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Investigation of Observed Seismicity
in the Horn River Basin
BC Oil and Gas Commission - August 2012
The BC Oil and Gas Commission is the single-window
regulatory agency with responsibilities for regulating
oil and gas activities in British Columbia, including
exploration, development, pipeline transportation and
reclamation.
The Commission’s core roles include reviewing and
assessing applications for industry activity, consulting
with First Nations, ensuring industry complies with
provincial legislation and cooperating with partner
agencies. The public interest is protected by ensuring
public safety, protecting the environment, conserving
petroleum resources and ensuring equitable participation
in production.
For general information about the Commission, please
visit www.bcogc.ca or phone 250-794-5200.
About the
BC Oil and Gas Commission
Fort St. John
Fort Nelson
Dawson Creek
Kelowna
Victoria
www.bcogc.ca
Terms Used in this Report
‘Seismicity’, ‘Seismic Events’ and
‘Events’ – used interchangeably
to describe seismograph recorded
earthquakes caused primarily by
fault movement.
‘Micro-Seismicity’ – very low
magnitude events created by
shear movement or tensile fracture
during hydraulic fracturing not
detectable by the Canadian National
Seismograph Network (CNSN).
‘Microseismic’ – describes both
the recording and processing of very
small magnitude events produced
by hydraulic fracturing.
‘Induced Seismicity’ – generally
defined as earthquakes resulting
from human activity.
‘Stage’ – refers to a hydraulically
fractured interval along a horizontal
wellbore, each stage is isolated and
perforated prior to the injection of
fluids to hydraulically fracture the
reservoir rock.
03 Executive Summary				
04 Event Summary			
06 Investigation Overview
08 Induced Seismicity in B.C.
12 Literature Review
14 Analysis
21 Controls on Seismicity
23 Davis and Frohlich Criteria
25 Findings
26 Recommendations
28 Conclusion
29 References
Table of Contents
This report provides the results of the BC Oil and
Gas Commission’s (Commission) investigation into
anomalous seismicity within geographically confined and
remote areas in the Horn River Basin between April 2009
and December 2011. The investigation was commenced
immediately after the Commission became aware of a
number of anomalous, low-level seismic events which
were recorded by Natural Resources Canada (NRCan)
near areas of oil and gas development. Only one of the
events under investigation had been reported by NRCan
as “felt” at the earth’s surface.
In undertaking the investigation, the Commission notes
that more than 8,000 high-volume hydraulic fracturing
completions have been performed in northeast British
Columbia with no associated anomalous seismicity.
None of the NRCan reported events caused any injury,
property damage or posed any risk to public safety or the
environment.
The investigation was completed by the Commission’s
geological and engineering staff within the Resource
Development department, and they benefited from
consultation with NRCan, the University of British
Columbia and the Alberta Geological Survey. Data
was obtained from numerous sources including open
source information as well as proprietary data acquired
by oil and gas companies working near the area of the
investigation.
Executive Summary
The Commission also acknowledges the professional,
open and honest exchanges of information and analyses
between the regulated industry and the investigation team.
The investigation has concluded that the events observed
within remote and isolated areas of the Horn River Basin
between 2009 and 2011 were caused by fluid injection
during hydraulic fracturing in proximity to pre-existing
faults.
Three sets of events are discussed in the report, the 38
events reported by NRCan, 216 events recorded by a
dense array deployed at Etsho and 18 events recorded
by a dense array deployed at Kiwigana. All these events
are interpreted to be the result of fault movement.
The Etsho dense array monitored the d-1-D/94-O-8 pad.
Events, recorded by this array, occurred on microseismic
plots along linear trends interpreted to be faults. In only
one instance did a linear seismic swarm overlay a fault
mapped with 2D or 3D seismic.
Fault maps interpreted from 2D and 3D seismic were
submitted for the investigation. These showed 12
mapped faults intersecting five of the 7 d-1-D pad
wellbores. No events could confidently be linked to 11 of
these faults, indicating that most of the faults intersected
either did not slip or did move without generating a
detectable event.
Disposal wells were ruled out as a source of the
seismicity during the investigation. Four disposal wells
were operating during the period of observed seismicity:
three at Etsho and one in the Tattoo area. These wells
were injecting recovered hydraulic fracturing fluids into
the Mississippian Debolt Formation, 1800 metres above
the Horn River Group. All event epicentres occurred
within the Devonian Horn River Group and no fault
movement was seen in the Debolt Formation.
The Commission makes seven recommendations based
on the investigation, which include the submission of
microseismic reports; establishment of a notification
and consultation procedure; studying the relationship
of hydraulic fracturing parameters on seismicity, and
upgrading and improving B.C.’s seismograph grid
and monitoring procedures. Improvements to the
seismographic grid network have already begun through
funding provided by Geoscience BC. The upgraded grid
will provide improved monitoring for induced seismicity
and will form the basis for the monitoring, detection,
notification and consultation procedure.
In addition, the Commission has initiated a broader study
with the University of British Columbia to examine factors
related to the extent, magnitude, impact and control of
induced seismicity in northeast B.C. The intent of this
research is to provide insights into predicting the location
and magnitude of seismic events based on hydraulic
fracturing parameters and geomechanics and to establish
protocols for prediction, detection, monitoring and
mitigation of these events.
3Investigation of Observed Seismicity in the Horn River Basin
Investigation of Observed Seismicity in the Horn River Basin4
Between April 2009 and July 2011, 31 seismic events
were recorded and located by NRCan in the Etsho area
of the Horn River Basin in northeast British Columbia
(Figure 1). Another seven events were recorded near
the Tattoo area between Dec. 8 and Dec. 13, 2011. The
observed events ranged in magnitude between 2.2 and
3.8 ML
on the Richter scale as recorded by NRCan
(Table 1).
Asearch of the areas in the National Earthquake Database
from 1985 to present shows no detected seismicity in the
Horn River Basin prior to 2009. Two events (1985/09/04,
3.1ML
and 1986/09/28, 2.9ML
) located approximately 160
km south and southwest of Fort Nelson were detected by
the Canadian National Seismograph Network (CNSN).
This suggests that similar events occurring in the Horn
River Basin could have been recorded. Two NRCan
seismograph stations, part of the CNSN, are currently
operational in northeast British Columbia. The Bull
Mountain station near Hudson’s Hope became operational
in January 1998 and the Fort Nelson station came online
in 1999. Magnitudes have been processed and reported
down to approximately 2.0 ML
in the Horn River Basin
since deployment of these two stations. Smaller events
may have occurred and gone undetected due to the
detection limitations of the CNSN. While the full extent
of historical seismicity is not known, the April 2009 to
December 2011 Etsho and Tattoo events are considered
anomalous events when considered in full context.
Event Summary
Figure 1: Location of Etsho,Tattoo and Kiwigana areas in the Horn River Basin. Red triangles
show NRCan reported epicentres, Bovie andTrout Lake Fault zones noted. Liard Basin to west of
Bovie Fault. Blue star indicates location of Kiwigana seismograph array.
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Northwest Territories
Fort
Nelson
094O11
094O16
094P13
094J15
094P04
094J16
094O06
094O14
094I13
094O02
094J14
094O10
094O09 094P12
094O01
094O03
094O07
094O08
094O15
094P05
HORN
RIVER
BASIN
LIARD
BASIN
BovieLakeFault
TroutLake
FaultZone
121°45'0"W
121°45'0"W
122°0'0"W
122°0'0"W
122°15'0"W
122°15'0"W
122°30'0"W
122°30'0"W
122°45'0"W
122°45'0"W
123°0'0"W
123°0'0"W
123°15'0"W
123°15'0"W
59°45'0"N
59°45'0"N
59°30'0"N
59°30'0"N
59°15'0"N
59°15'0"N
59°0'0"N
59°0'0"N
Tattoo Field
0 5 10 152.5 Kilometers
#* Earthquakes
! Major Cities
"
Well Surface Hole
(
Well Bottom Hole
Well Directional Survey
Earthquakes NEBC
2009 - 2012
1:500,000
!
!
!
!
Kelowna
Victoria
Fort Nelson
Fort St. John
Tattoo Area
Etsho Area
Kiwigana
^_
5Investigation of Observed Seismicity in the Horn River Basin
Table 1 provides a summary of the events recorded by NRCan in the Etsho and Tattoo areas that are plotted and shown on Figure 1.
The events in Table 1 were proximate to oil and gas activities employing hydraulic fracture operations when the events occurred.
Table 1 – Magnitude and
Location of NRCan Seismic Events,
with date and time.
Modified from NRCan report.
www.earthquakescanada.nrcan.gc.ca/
Event # Date	 Time (UT) Time (Pacific) Correct Date	 Lat	 Long Mag	 Approximate Location
38 2011/12/13 13:17:32 5:17:32 59.84 -122.66 3.1ML 114 km N of Fort Nelson
37 2011/12/12 23:34:12 15:34:12 59.81 -122.68 3.1ML 110 km N of Fort Nelson
36 2011/12/12 07:59:22 23:59:22 12/11/2011 59.82 -122.69 2.9ML 112 km N of Fort Nelson
35 2011/12/11 09:15:57 1:15:57 59.85 -122.69 2.4ML 114 km N of Fort Nelson
34 2011/12/11 02:37:53 18:37:53 12/10/2011 59.87 -122.67 2.9ML 116 km N of Fort Nelson
33 2011/12/10 02:52:34 18:52:34 12/9/2011 59.87 -122.69 2.9ML 117 km N of Fort Nelson
32 2011/12/08 15:28:37 7:28:37 59.81 -122.65 2.8ML 111 km N of Fort Nelson
31 2011/07/14 10:40:32 2:40:32 59.51 -122.20 2.5ML 82 km NE of Fort Nelson
30 2011/07/07 22:46:37 14:46:37 59.49 -122.40 3.1ML 76 km NNE of Fort Nelson
29 2011/07/01 09:32:46 1:32:46 59.54 -122.49 2.6ML 81 km NNE of Fort Nelson
28 2011/06/26 13:17:02 5:17:02 59.56 -122.37 2.7ML 84 km NNE of Fort Nelson
27 2011/06/18 23:02:03 15:02:03 59.82 -121.47 2.8ML 132 km NE of Fort Nelson
26 2011/05/29 08:09:47 0:09:47 59.54 -122.46 3.1ML 81 km NNE of Fort Nelson
25 2011/05/20 06:22:34 22:22:24 5/19/2011 59.51 -122.52 3.0ML 78 km NNE of Fort Nelson
24 2011/05/19 13:13:43 5:13:43 59.47 -122.47 3.3ML 74 km NNE of Fort Nelson
23 2011/05/19 13:05:15 5:05:15 59.49 -122.41 3.8ML 76 km NNE of Fort Nelson
22 2011/05/10 14:16:03 6:16:03 59.51 -122.37 3.5ML 79 km NNE of Fort Nelson
21 2011/05/03 12:56:29 4:56:29 59.51 -122.32 3.2ML 80 km NNE of Fort Nelson
20 2011/04/30 13:27:30 5:27:30 59.46 -122.59 3.1ML 72 km N of Fort Nelson
19 2011/04/28 22:34:51 14:34:51 59.47 -122.47 2.5ML 73 km NNE of Fort Nelson
18 2011/04/07 12:19:20 4:19:20 59.50 -122.51 3.2ML 76 km NNE of Fort Nelson
17 2011/03/04 03:09:05 19:09:05 3/3/2011 59.50 -122.34 3.3ML 78 km NNE of Fort Nelson
16 2010/10/12 21:01:11 13:01:11 59.55 -122.38 3.4ML 83 km NNE of Fort Nelson
15 2010/10/12 19:19:44 11:19:44 59.53 -122.31 3.0ML 83 km NNE of Fort Nelson
14 2010/10/12 17:09:40 9:09:40 59.59 -122.45 3.4ML 87 km NNE of Fort Nelson
13 2010/10/09 10:00:31 2:00:31 59.54 -122.42 3.1ML 82 km NNE of Fort Nelson
12 2010/10/05 22:01:14 14:01:14 59.60 -122.39 3.6ML 88 km NNE of Fort Nelson
11 2010/10/05 13:30:28 5:30:28 59.53 -122.27 3.1ML 83 km NNE of Fort Nelson
10 2010/10/04 11:09:34 3:09:34 59.59 -122.36 2.9ML 88 km NNE of Fort Nelson
9 2010/10/03 08:06:50 0:06:50 59.56 -122.27 3.5ML 86 km NNE of Fort Nelson
8 2010/09/30 12:33:36 4:33:36 59.58 -122.48 3.0ML 85 km NNE of Fort Nelson
7 2010/09/30 12:31:43 4:31:43 59.60 -122.39 2.9ML 89 km NNE of Fort Nelson
6 2010/08/22 09:30:20 1:30:20 59.53 -122.23 2.4ML 84 km NE of Fort Nelson
5 2010/08/03 20:15:35 12:15:35 59.51 -122.27 2.7ML 81 km NNE of Fort Nelson
4 2010/06/11 22:25:19 14:25:19 59.50 -122.30 3.4ML 79 km NNE of Fort Nelson
3 2009/04/09 16:34:00 8:34:00 59.48 -122.01 2.2ML 83 km NE of Fort Nelson
2 2009/04/08 21:30:23 13:30:23 59.43 -121.92 2.3ML 82 km NE of Fort Nelson
1 2009/04/08 21:27:37 13:27:37 59.46 -122.02 2.3ML 81 km NE of Fort Nelson
Investigation of Observed Seismicity in the Horn River Basin6
The Commission began a formal investigation in July
2011 into the anomalous events recorded by NRCan
in the Etsho area. The investigation was extended to
the Tattoo area when similar anomalous events were
detected there in December 2011. The purposes of the
investigation were to:
•	 Examine the available evidence to determine if there
may be a linkage between oil and gas activities and
the observed events.
•	 Review current research on induced seismicity and
apply those results to the investigation.
•	 Consider possible mitigation methodologies, where
appropriate, should a link be established between
the observed events and oil and gas activities.
The Commission began the investigation with a review of
hydraulic fracturing and well completion information on
wells situated near the area of observed seismicity in the
Etsho area. The dates and times of hydraulic fracturing
operations were compared to the dates and times of
recorded seismicity events.
To obtain additional information to assist in the
investigation, the Commission issued formal Information
Requests (IRs) to six operators within the study area.
The IRs provided the Commission access to data not
currently required to be submitted by the operators to the
Commission. Much of this operator information obtained
Investigation Overview
is proprietary and includes detailed completion statistics,
microseismic reports, groundwater analyses and seismic
mapping. In some cases, confidential data is used to
support findings or analyses but not reproduced within
the report.
Under British Columbia legislation and regulation,
specified oil and gas information is required to be
collected and submitted to the Commission. This
includes geophysical logs, sample reports and drilling
and completion information. Data is held confidential for
a time period as defined in the regulation, dependent on
well classification.
Through the course of the investigation, the Commission
consulted with experts from industry, NRCan, the
University of British Columbia and the Alberta Geological
Survey.
A literature search was done as part of the investigation,
focusing on science and analysis of induced seismicity
as well as the geology of the Horn River Basin. Included
in this search were a number of recent public reports on
induced seismicity incidents in Oklahoma, England and
Ohio.
Table 2: Richter Scale diagram showing range of magnitudes and effects. Based on US Geological Survey documents.
Event Frequencies courtesy of USGS (estimates).
Magnitude (ML
) Description Earthquake Effects Natural Seismicity OccurencesWorldwide
-3.0 – 0.5 Micro-Seismicity
Micro events created when
hydraulic fracturing breaks rock,
including micro shear movement
and tensile fracturing, not felt
Very frequent. Detection reliability extremely
varied. Frequency estimated at many millions of
events per year.
0.5- 2.0 Micro earthquake Very small earthquakes, not felt.
Very frequent. Detection reliability extremely
varied. Frequency estimated at many millions of
events per year.
2.0–2.9 Minor
Generally not felt, but recorded.
(Not felt in Horn River Basin)
1,300,000
3.0–3.9 Minor Often felt, but rarely cause damage. 130,000
4.0–4.9 Light
Noticeable shaking of indoor items,
rattling noises. Significant damage
unlikely.
13,000
Background Information
Measuring Earthquakes
Unless otherwise noted, earthquake
magnitudes reported in this
investigation are Richter scale
magnitudes (ML
) (Table 2) and occur
throughoutthisreportasbothpositive
and negative numbers. The Richter
magnitude scale was originally
calibrated to a seismograph in 1935.
At that time, zero on the scale was
set as an event that would cause
a one micrometre displacement
on a seismogram 100 kilometres
(km) from an epicentre. Instrument
sensitivity has improved with time
and modern seismographs are
capable of detecting earthquakes
that fall below the original zero value
set by Richter. Negative Richter
values account for this enhanced
sensitivity.
Duration magnitude (Md) used by
Holland (Holland, 2011) scales
earthquakes using surface wave
durations and is consistent with the
Richter scale.
7Investigation of Observed Seismicity in the Horn River Basin
Investigation of Observed Seismicity in the Horn River Basin8
The locations of earthquakes are generally referred to
using the terms “epicentre” and “hypocentre” or “focus”.
The epicentre is the location on the earth’s surface located
directly above the “hypocentre” or “focus” where an event
actually occurs underground.
The CNSN is designed to monitor moderate to strong
magnitude earthquakes that pose a risk to public safety
and not to detect low magnitude induced seismicity.
Currently, the portion of the CNSN for northeast British
Columbia consists of two stations, the Bull Mountain
(Hudson’s Hope) and Fort Nelson seismograph stations.
The limited station coverage in the region results in an
uncertainty of 5 to 10km in the epicentral locations of
detected earthquakes. The uncertainty in earthquake
focal depths is even larger. Minimum magnitude detection
by CNSN for earthquakes in the northeast BC region is
estimated at 2.0 ML
but in the course of the investigation,
it was found that the current grid had failed to detect 15
events greater than 2.0 ML
. From June 23 to August 14,
2011, an operator deployed local seismograph array at
Etsho detected 19, 2.0 to 3.0 ML
events. Only four of these
events were reported by NRCan.
Station Coverage of the Canadian
National Seismograph Network (CNSN)
Induced seismicity may be caused by numerous factors
including slippage along fault planes, ground subsidence
from collapse of solution mines and stress release
from reservoir depletion. Fault movement can occur
when previously stable subsurface stress conditions
are altered. Human activities that can alter these stress
conditions include fluid injection for secondary recovery
in hydrocarbon reservoirs, injection of waste fluids into
deep rock formations, withdrawal of hydrocarbons from
reservoirs and geothermal energy operations involving
deep fluid injection.
Fluid injection may trigger induced seismicity. As fluid is
injected, it flows into the existing pore system of the rock
and into pre-existing fractures and faults. Across faults
injection can increase pore pressure, counter-acting
normal stress across the fault and may act to open an
existing fault plane. This overcomes friction along the fault
and can cause fault slippage.
In British Columbia, the only documented case of induced
seismicity, linked to oil and gas activity, occurred in the
Eagle Field area, approximately five km north of Fort St.
John. Twenty-nine Richter magnitude 2.2 to 4.3 events
were recorded from November 1984 to May 1994. Horner
(Horner, 1994) used the Davis and Frohlich criteria (Davis
and Frohlich, 1993) to conclude that the events were
induced. High pressure fluid injection for secondary oil
recovery was identified as a possible cause. High volume
hydraulic fracturing was not employed in the area at that
time.
In response to the Eagle Field incident, the regulator
ordered the injection pressure be lowered. Since that
time, reservoir waterflood and injection pressures within
British Columbia are required to be maintained below
levels capable of re-opening pre-existing fractures or faults.
This requirement ensures the integrity of confinement
boundaries and prevents fluid migration beyond the
targeted formations.
Induced Seismicity in British Columbia
The Horn River Basin in northeast British Columbia lies
between Fort Nelson and the Northwest Territories border
(Figure 2). Basinal shales of the Horn River Group fill the
Basin, bounded to the west by the Bovie fault and to the
east by laterally equivalent Keg River and Slave Point
Formations reef carbonates (Figure 3). The Muskwa, Otter
Park and Evie Formations of the Horn River Group are
highly siliceous, high organic content shale gas targets
(McPhail et al, 2008). Overlying the Horn River Group are
over 800 metres (m) of clay rich shales of the Fort Simpson
Formation (Figure 3). As mineralogy transitions from the
siliceous shales of the Muskwa Formation to the clay rich
shales of the overlying Fort Simpson, a natural barrier to
fracture propagation occurs and the growth of fractures
caused by hydraulic fracturing is contained to the targeted
Muskwa and Evie shales.
The Bovie Fault extends over 100 km from the northern
British Columbia border south and then southwest into the
foothills. This fault separates the Horn River Basin from
the Liard Basin (Figure 1). Trending northeast from about
30 km south of Maxhamish Lake toward the Celibeta High
is the Trout Lake Fault zone with a strike-slip component.
(MacLean, Morrow, 2004).
Figure 2: Provincial map of British Columbia showing locations and
outlines of Horn River and Liard Basins and Cordova Embayment
Geology of the Horn River Basin
9Investigation of Observed Seismicity in the Horn River Basin
Investigation of Observed Seismicity in the Horn River Basin10
Figure 3: Cross-section of Horn River Basin showing Muskwa, Otter Park and Evie formation shale gas targets. Horizontal wellbores target the Muskwa, Otter Park
and Evie zones. Diagram modified from Geoscience BC Horn River Basin Subsurface Aquifer Characterization Project schematic cross-section.
Otter Park
metres
100 km
0
1000
West East
HORN RIVER BASINLIARD BASIN
Debolt/Rundle
Shallow Freshwater Aquifers
Dunvegan
Sikanni
Buckinghorse
Scatter
Chinkeh
Triassic
Mattson
Surface
Figure 1. Schematic stratigraphic cross-section, Horn River Basin and adjacent Liard Basin, modified from Petrel Robertson.
Ft. Simpson Shale
BovieFault
Debolt/Rundle
Slave Point /
Keg River
Debolt/Rundle Saline Aquifer
Cretaceous (Buckinghorse) Shale
Muskwa
Evie
11Investigation of Observed Seismicity in the Horn River Basin
In the Etsho study area, horizontal wells targeting the Horn
River shales were hydraulically fractured using multiple
stages of slickwater and sand. The horizontal leg of each
well was cemented with casing and a “perf and plug”
technique was used to initiate the fractures, starting at the
toe of the well and proceeding to the heel. Each hydraulic
fracture stage was isolated with bridge plugs and received
multiple perforations prior to pumping the stage. Once all
the stages were complete, the bridge plugs were drilled out
and the hydraulic fracture fluid was flowed back to surface.
Analysis of microseismic data shows that fracture growth
within the study area is confined to the target Horn River
shales. It appears that the overlying Ft. Simpson shale
acts as a highly effective fracture barrier during hydraulic
fracturing.
Hydraulic fracturing operations in the Etsho area have
been ongoing from February 2007 to late July 2011.
During this period, 14 different drilling pads were used to
drill over 90 wells with more than 1,600 hydraulic fracturing
stage completion operations (Table 3).
Hydraulic Fracturing in the Horn River Basin Table 3: Pad Hydraulic Fracturing Statistics for Etsho (non-confidential pads). Minimum, maximum and
average numbers are calculated from all pad data reviewed. Only non-confidential pads are listed in the table.
Well Pad Wells/Pad Stages/
Well
HZ Completed
(m)
Fluid/Well
(m3
)
Sand/Well
(Tonnes)
Avg Pump
Rate (m3
/
minute)
Fracs/Pad # of Seismic
Events
b-100-G 5 5 1,176 11,505 710 12 26 0
c-1-J 9 16 1,837 52,429 3,072 14 147 0
b-76-K 13 15 1,752 58,386 2,454 15 180 1
d-70-J 7 14 1,391 53,800 2,692 15 74 3
d-1-D 7 27 2,727 138,005 5,484 15 176 6
c-34-L 9 18 2,200 63,000 3,200 15 162 7
b-63-K 14 23 2,452 107,738 4,505 14 347 13
Average 8 17 1,846 61,612 3,107 13 149 3
Min. 4 5 1,176 11,505 710 8 26 0
Max. 16 27 2,727 138,005 5,484 15 347 13
Investigation of Observed Seismicity in the Horn River Basin12
Recently, two international cases of induced seismicity
have been documented linking hydraulic fracturing to
seismic events. In the first case, Dr. C.J. de Pater and Dr.
S. Baisch (de Pater and Baisch, 2011) directly tie hydraulic
fracturing in the Bowland Shale near Blackpool, England
to local seismicity. In the second case, Holland (Holland,
2011) suggests a relationship between hydraulic fracturing
in Garvin County, Oklahoma and local seismicity.
Other studies considered during the investigation include
Shale Gas Extraction in the UK: A Review of Hydraulic
Fracturing published by the Royal Academy of Engineering
in June 2012 and Induced Seismicity Potential in Energy
Technologies (Pre-Publication) by the US National
Research Council.
Literature Review
Near Blackpool, England, the Preese Hall–1, spudded Aug.
16, 2010, targeted gas in the Bowland shale. The Bowland
shale was encountered at 1,993.3 m (metres) (6,540 feet)
MD (Measured Depth) and was drilled to 2,744.4 m (9,004
feet) MD. Hydraulic fracturing ran from 2,337.8-2,727.6
m (7,670 – 8,949 feet). From March 28 to May 27, 2011
five hydraulic fracturing (slickwater) stages were run.
Stage volumes ranged from 596.2–1,669.4 cubic metres
(m3
) (5,000-14,000 bbls) water and 52-117 metric tonnes
proppant. Bottom-hole pressures reached a gradient of
21.4 KPa/m (0.95 psi/ft).
Fifty events, magnitude -2 to 2.3 ML
, (generally considered
to be below the threshold for detection as a “felt” event
at the surface) were recorded from March 28 to May 28,
2011. Seismicity is focused around stages 2, 4 and 5.
Events began early in stage operations and the strongest
event occurred 10 hours after shut-in. The occurrence of
events some time after hydraulic fracturing operations is
interpreted to be the effect of a pressure front spreading
out from the hydraulic fracturing injection point. De Pater
and Baisch (de Pater and Baisch, 2011) conclude that
seismicity magnitude can be mitigated by “rapid fluid flow
back after the treatments and reducing the treatment
volume”.
Sufficient movement occurred to deform well casing
within the target formations on the horizontal leg. The
casing deformation was attributed to “distributed, small
magnitudes of bedding plane slip”.
In Garvin County, Oklahoma, hydraulic fracturing
operations began at the Picket Unit B Well 4-18 on Jan 17,
2011. This is a vertical well located in the Eola field at the
northern edge of the Ardmore basin. The geology of the
area consists of numerous, major, parallel faults running
west-northwest to east-southeast. Several northwest to
southeast trending faults intersect the major faults. The
Eola field is block faulted and fault dips are near vertical.
Fifty events, magnitude 1-2.8 Md (Duration Magnitude),
occurred on Jan. 17-18, 2011. The events began seven
hours after hydraulic fracture operations started.
Thirty-nine of the events occurred within 16 hours after
hydraulic fracturing operations began. Although this
Blackpool, UK Garvin County, USA
area of Oklahoma has considerable natural seismicity,
seismological evidence indicates a unique origin different
from naturally occurring earthquakes.
Holland used the seven question Davis and Frohlich
criteria (Davis and Frohlich, 1993) to help determine if the
events were induced. The following summarizes Holland’s
answers:
1. Are these events the first known earthquakes of this
character in the region? (UNKNOWN) It was difficult
to determine if the events were uniquely different from
previously recorded earthquakes in the area.
2. Is there a clear correlation between injection and
seismicity? (YES) There was a clear correlation between
hydraulic fracturing and earthquake times.
3. Are the epicenters near wells (within 5 km)? (YES) The
epicentres are within five kilometres of the Picket well.
4. Do some earthquakes occur at or near injection depths?
(YES) Most earthquakes occurred near injection depths.
Depth uncertainty on seismic recording is about 630 m.
5. If not, are there known geologic structures, that may
channel flow to sites of earthquakes? (YES) Faults exist
that could channel injection fluid to epicentre locations.
6. Are changes in fluid pressure at well bottoms sufficient
to encourage seismicity? (YES) Hydraulic fracturing
pressures are sufficient to encourage seismicity.
7. Are changes in fluid pressure at hypocentral locations
sufficient to encourage seismicity? (UNKNOWN) Pressure
diffusion could not be adequately modeled within the Eola
Field.
Holland concluded that timing and location of the events
suggested a possible connection to hydraulic fracturing.
13Investigation of Observed Seismicity in the Horn River Basin
Etsho
A 20-seismograph dense array was deployed
in the Etsho area to record, locate and study the
seismicity in greater detail than possible with
NRCan data. This array, surrounding the d-1-
D/94-O-8 pad, was operated from June 16 to Aug.
15, 2011.
Kiwigana
A second dense array was deployed at Kiwigana,
40 kilometres to the southwest of the Etsho area
(Figure 1). This 151-station seismograph array was
located over the ECA HZ KIWIGANA c-15-D/94-O-7
multi-well pad and operated from Oct. 25, 2011 to
Jan. 27, 2012 (Figure 4).
Operator Dense Array Deployments Figure 4: Map of Kiwigana dense array, surrounding c-15-D/94-O-7 pad, showing horizontal wellbores (black lines) and seismograph
locations (red dots).
Investigation of Observed Seismicity in the Horn River Basin14
Induced Seismicity
Hydraulic fracturing is the process of creating cracks
(fractures), in buried geological formations to create
pathways along which hydrocarbons trapped within the
formation can flow into the wellbore at higher rates than
otherwise possible. The hydrocarbons then flow to the
surface under controlled conditions through the wellhead
and are collected for processing and distribution.
During the hydraulic fracturing process, a mixture of water,
sand and other chemical additives designed to protect the
integrity of the wellbore and enhance production is pumped
under high pressure into the formation to create fractures.
The fractures are kept open by sand or “proppant”, which
provides pathways to allow the natural gas to flow into the
wellbore.
As hydraulic fracturing fluids are injected into intact gas
bearing shales, thousands of micro-seismicity events
(approx -3.0 to 0.5 ML
) are created as the rock is fractured.
These events are caused by micro shear movement and
tensile fractures and by the re-opening of existing fractures
and faults. The micro-seismicity created by fracture
development is often monitored during hydraulic fracturing
by a borehole or surface seismograph array to assess the
effectiveness of the fracture program. Special equipment
Analysis
is used as these events are far below the detection
threshold of the seismographic monitoring networks in
place for earthquake detection. For the purposes of this
report, the focus is on seismicity that would not normally
occur when performing hydraulic fracture completions
(such as seismicity resulting from fault movement). Larger
magnitude events may occur when fluid injected during
hydraulic fracturing triggers movement along pre-existing
stressed faults.
Only one event studied within this investigation was
reported felt at surface. NRCan’s report on the May 19,
2011, 3.8 ML
event indicates that the event was “felt by
workers in (the) bush”. No injuries or damage to surface
structures were reported for this or any of the events
studied within this investigation.
Twenty-seven of the recorded Etsho events lie within a
10 km radius circle (Figure 5). Within this same circle are
seven multi-lateral drilling pads. Five of these pads were
conducting hydraulic fracturing operations when events
occurred.
Figure 5: NRCan event locations, event sequence and drilling pad locations, shown within 10km radius red shaded circle.
#*
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Horn River
Basin
094P04
094O02
094O10
094O09
094P12
094O01
094O07
094O08
094P05
4/8/2009
4/9/2009
6/11/2010
8/3/2010
8/22/2010
9/30/2010
9/30/2010
10/3/2010
10/4/2010
10/5/2010
10/5/2010
10/9/2010
10/12/2010
10/12/2010
10/12/2010
3/4/20114/7/2011
4/28/20114/30/2011
5/3/2011
5/10/2011
5/19/2011
5/19/2011
5/20/2011
5/29/2011
6/26/2011
7/1/2011
7/7/2011
7/14/2011
C- 024-I
B- 025-H
D- 063-H
C- 039-J
B-B077-H
A- 097-J
A-A080-L
A- 069-L
D-N070-K
A- 076-F
A- 016-K
C- 100-G
A-A020-J
C- 089-G
C- 015-G
C-D055-B
D- 071-G
D- 068-H
A- 077-I
A- 027-I
D-A054-A
D- 052-H
A- 012-H
A- 036-A
B- 012-G
B- 045-I
A- 041-A
A- 051-J
D-A052-L
A-A076-F
A- 100-B
D-C087-G
D-A087-G
C- 055-B
C-A055-B
B- 086-A
B- 031-A
A- 089-D
B- 060-L
A- 050-C
A-C009-K
B- 008-K
A- 006-C
A- 006-J
D- 099-I
A- 027-I
C- 056-E
B-C063-K
D-A090-G
A- 026-G
C-B055-B
C-C055-B
C-C001-J
B- 066-I
A- 077-L
C- 062-H
B- 002-H
B-C008-K
A- 051-A
D- 051-A
B- 098-F
C- 067-K
D- 066-F
A-A100-B
B- 090-J
B-D100-G
D-B087-G
B- 016-IC-A016-I
C- 071-A
B- 060-D
C- 035-D
A-A051-A
A- 059-D
D- 069-L
D-I052-L
D-H001-D
C-B063-K
D- 090-G
D- 077-J
D-E087-G
C-E055-B
D- 056-J
D- 085-G
B- 085-A
A- 035-E
B- 048-A
B- 086-K
B- 072-K
A-A097-J
B- 063-B
D-K052-L
D-E052-L
C- 099-K
B-A076-K
C-D063-K
D-J070-J
A- 020-J
D-B077-J
A- 045-G
B-H018-I
B- 077-H
A-E016-I
D- 094-A
C- 093-A
D- 068-D
C- 007-D
D-A063-H
A-A050-C
B-B008-K
C- 094-I
B- 052-I
C-A034-L C-D034-L
C-I034-L
D-C052-L
D-G001-D
D-K070-K
D-H070-K B- 076-K
B-E063-K
B-A063-K B- 061-K
D-E070-J
D-D070-J
A-F020-J
A-D020-J
A- 029-B
C- 018-B
D- 087-G
C-D001-J
B-D018-I
B-C018-I
B-K077-H
B-G077-H
C- 026-A
D-O037-H
D- 054-A
D-A094-A
B- 093-A
D- 039-E
D- 079-D
B- 091-B
C- 002-H
A-A009-K
C- 057-D
C-B034-L
C-G034-L
A- 083- D
D-O001-D D-K001-D
D-E001-D
D-M070-K
D-D070-K
A- 008-C
A-B077-K
D- 046-K
B-A090-J
D-F070-J
B- 100-G
A-H020-J
B- 018-B
D-G087-G
B- 084-B
C- 001-J
C-A001-J
C-E001-J
B- 018-I
B-E077-H
B-N077-H
B-H077-H
D-F037-H
D-G037-H
D-J037-H
D-K037-H
D- 025-H
C- 016-I
A-C016-I
A- 031-H
C- 021-A
D- 020-D
D- 028-E
A- 027-E
C-A007-D
D- 037-D
122°0'0"W
122°0'0"W
122°15'0"W
122°15'0"W
122°30'0"W
122°30'0"W
59°30'0"N
59°30'0"N
59°15'0"N
59°15'0"N
0 2 4 61 Kilometers
Etsho Activity 20 km Buffer
#* Earthquakes
! Major Cities
"
Well Surface Hole
(
Well Bottom Hole
Well Directional Survey
Earthquakes NEBC
2009 - 2012
1:200,000
!
!
!
!
Kelowna
Victoria
Fort Nelson
Fort St. John
Etsho Area
At Tattoo all seven of the recorded events can be
encompassed within a 10 km radius circle that
encloses two multi-well shale gas drilling pads.
One pad at Tattoo had ongoing hydraulic fracturing
operations when the seismicity occurred (Figure 6).
15Investigation of Observed Seismicity in the Horn River Basin
Investigation of Observed Seismicity in the Horn River Basin16
Figure 6:Tattoo area NRCan event epicentres and Multi-well Pads, shown within“20km buffer”,
10km radius red circle.
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Northwest
Territories
094O11
094O16
094O14
094O10
094O09
094O15
9/30/2010
9/30/2010
10/4/2010
10/5/2010
10/9/2010
10/12/2010
10/12/201010/12/20105/29/2011
6/26/2011
7/1/2011
12/8/2011
12/10/2011
12/11/2011
12/11/2011
12/12/2011
12/12/2011
12/13/2011
A- 078-L
B- 095-E
D-A028-F
B-A018-G
B-A055-B
D- 063-H
D- 030-D
C- 092-E A-G098-F
A- 086-BA-A086-B
D- 061-A
A- 076-F
B- 025-L
D- 073-L
D- 077-K
B- 055-B
A- 041-A
B- 066-D
D- 012-L
A-B098-F
C-D068-B
A-B086-B
B- 091-G
B- 058-H
C- 060-D
A-A076-F
B- 018-G
C- 007-J
D- 097-B
C- 015-L
C-B092-E
A- 040-K
A-A098-F
A- 098-F
C- 060-G
B-E070-B
B- 077-B
A-C086-B
C- 075-F
D- 058-L
C- 077-L
C- 066-E
A- 025-L
A- 045-E
D-H050-A
D-D050-A
D-B050-A
C- 062-H
B- 002-H
B-D070-B
C-A068-B
C-E068-B
C- 081-G
D- 013-L
D- 066-F
C- 054-D
C- 053-C
C- 067-L
B- 047-L
A- 035-L
A- 054-L
C- 057-C
B- 057-C
D- 028-F
C-A007-J
A- 069-D
B-A022-L
C- 001-L
A-C001-L
A-C098-F
D-B071-A
D-H071-A D-I071-A
D- 070-F
B- 096-E
C-A057-C
D- 069-C
D-B028-F
B- 048-A
B- 022-L
A-B001-L
C- 030-K
C- 020-K
C- 049-E
B- 059-E
C- 099-D
A- 027-L
C- 035-E
A- 002-D
B- 066-B
D-A063-H
C- 012-L
B- 021-L
A- 001-L
C- 081-D
A- 056-F
B- 070-B
A- 033-L
A- 028-D
C- 066-L
D- 076-E
B- 044-L
C- 063-L
C- 042-C
D-C050-A
D-I050-A
B- 091-B
D-J050-A
C- 002-H
C- 029-D
B- 057-L
C- 083-L
C-A092-E
A- 021-L
A-A001-L
A-D001-L
D- 028-J
C- 027-J
C-C068-B C-B068-B
D-A068-B
B- 063-B C- 056-A
D- 071-A D-A071-A
D-D071-A
C- 057-D
A- 083-D
BovieLakeFault
TroutLake
FaultZone
122°15'0"W
122°30'0"W
122°30'0"W
122°45'0"W
122°45'0"W
123°0'0"W
60°0'0"N
59°45'0"N
59°45'0"N
Tattoo Field
0 2 4 61 Kilometers
Tattoo Activity 20 km Buffer
#* Earthquakes
! Major Cities
"
Well Surface Hole
(
Well Bottom Hole
Well Directional Survey
Earthquakes NEBC
2009 - 2012
1:200,000
!
!
!
!
Kelowna
Victoria
Fort Nelson
Fort St. John
Tattoo Area
Horn River
Basin
SeismicityEventLocationsandDepth–ProximitytoHydraulic
Fracturing
A number of events, ranging from magnitude -0.8 to
3.0 ML
, were recorded by the Etsho dense array during
hydraulic fracturing. Of these, 216 are interpreted to be
related to fault movement (197 events, magnitude 1.0 –
2.0ML
and 19 events magnitude 2.0-3.0 ML
). Operator
provided b-value analysis indicated that magnitudes from
0.5ML
to 1.0ML
indicate the transition from fracture driven
seismicity to seismicity driven by fault movement. For the
dense array’s operational date range, June 23 to August
14, the two northeast B.C. stations in the CNSN recorded
four events (mag. 2.5 to 3.1 ML
).
Figure 7 shows the horizontal wellbores for the d-1-D
drilling pad, volumes injected at each hydraulic fracturing
stage and the magnitude >1.0ML
events occurring from
June 23 to August 14, 2011.
17Investigation of Observed Seismicity in the Horn River Basin
Figure 7: Diagram showing d-1-D wellbores and events >1.0.Wellbores are black
lines and stages with relative injection volumes are thickened blue sections.
The horizontal and vertical locations of
several events at Etsho detected by NRCan
were relocated by the operator using data
obtained from the dense array. The results
of this work placed event hypocentres within
200 m, vertically and horizontally, of hydraulic
fracturing stages. In cases where events
could be confidently linked to hydraulic
fracturing stages, events occurred during the
event stage or prior to the following stage
beginning. Associated faults, identified on
microseismic plots as linear swarms, could
be seen intersecting stage locations. True
vertical depths (TVD) of hydraulic fracturing
completions at the Etsho d-1-D pad range
from approximately 2,650 to 2,889 metres
TVD. Of the 69 magnitude 1.5 to 3.0 ML
seismic events recorded by the dense array
and linked to this pad, all fall within the
targeted formations. Sixty-six of these events
occur between 2,800 and 2,870 metres.
At Kiwigana, numerous micro-seismicity
events, ranging from -1.7 to 0.5 ML
, were
detected between Oct. 25, 2011 and Jan. 27,
2012 by the operator deployed dense array.
These micro-seismicity events resulted from
tensile failure and shear movement during
the normal process of hydraulic fracturing to
develop the reservoir. An additional 18 events
ranging from 1.0 to 1.86 ML
were detected
and are interpreted to be the result of injection
fluids triggering movement along pre-existing
faults.
Figure 8 is a cumulative microseismic plot
showing a vertical profile of the Kiwigana
wellbores at the c-15-D pad. Coloured dots
indicating micro-seismicity show that hydraulic
fracturing operations are successfully
contained to the Horn River shale target
horizons and that the overlying Ft. Simpson
shale provides an effective barrier to vertical
fracture growth. A fault is suggested near
the centre of the wellbores by the downward
trending collection of microseismic points.
Investigation of Observed Seismicity in the Horn River Basin18
Figure 8: Cumulative microseismic plot for Kiwigana, coloured dots indicate contained micro-seismicity events caused by tensile and shear failure of intact
shale.Trail of coloured dots suggest reopening or movement of pre-existing fault. Generalized stratigraphic column to right.
19Investigation of Observed Seismicity in the Horn River Basin
HydraulicFracturingTimingvs.SeismicityEventTiming
Hydraulic fracturing dates and times were compared to seismicity event times (Figure 9). At Etsho and Tattoo, all 38 NRCan reported events occurred either during a hydraulic fracturing
stage or sometime after one stage ended and another began. No events were recorded before hydraulic fracturing operations began or after the last hydraulic fracturing operations ended.
Figure 9:Timing of NRCan reported Events (black dots) vs. Magnitude.Timing of hydraulic fracturing operations (coloured columns).
c-68-B/94-O-15
c-34-L/94-O-8
b-76-K/94-O-8
c-1-J/94-O-8
c-55-B/94-O-9
d-87-G/94-O-8
4
3
2
1
1.5
0.5
2.5
3.5
2008 2009 2010 2011
Jan
Ootla 70-J 76-K
NRCan-ReportedEarthquakeEvents(RichterScale)
Jan Jan JanFeb Feb Feb FebMar Mar Mar MarApr Apr Apr AprMay May May MaySep Sep Sep SepJun Jun Jun JunJul Jul Jul JulOct Oct Oct OctAug Aug Aug AugNov Nov Nov NovDec Dec Dec Dec
d-70-J/94-O-8
Seismic Event
Correlations of Event Times to Horn River Pad Operations
d-70-K/94-O-8
d-52-L/94-O-8
b-18-I/94-O-8
b-63-K/94-O-8
d-1-D/94-O-9
Investigation of Observed Seismicity in the Horn River Basin20
Hydraulic fracturing and NRCan event timing were compared at 15 Etsho and Tattoo drilling pad sites. Nine pads had ongoing hydraulic fracturing operations when the NRCan
events occurred (Figure 9). The other multi-well drilling pads in the Etsho area could not be linked to the NRCan events by location or timing.
Eighteen magnitude 1.9 to 3.0 ML
events were selected from dense array microseismic plots. These events were selected because they were located adjacent to hydraulic fracturing
stages and could be connected to a single stage fluid injection with some confidence. Evidence strongly suggests that all events were triggered by fluid injection at adjacent stages.
Figure 10 shows the time lapse from the beginning of the selected stage to the seismicity event time. One stage was linked to 3 events, four stages to 2 events each and 7 stages
had one event. On average, stage start time to stop time was 5 ½ hours. Eight events occurred during stage operations. Seventeen events occurred within 17 ½ hours and all
events had occurred within 24 hours of assigned stage start times.
All stages along the d-G1-D (southwestern most) wellbore had 10,000 m3
total hydraulic fracturing fluid placed. For these stages, two injections of 5,000 m3
were placed at the same
stage interval separated by about one hour. Eight of the events connected to the 11 stages graphed with 10,000 m3
total fluid placed, occurred prior to the second injection of
5,000 m3
.
Figure 10: Timing of seismicity events, resulting from fluid injection at selected hydraulic fracturing stages. Green dots designate events linked to stages with 10,000 m3
total‘Fracturing Fluid Placed’
(two injections of 5000 m3
separated by one hour). Red dots are events linked to stages with 5,000 m3
total‘Fracturing Fluid Placed’.
Horn River Pad Operations d-1-D Pad
Time Lapse from Start of Hydraulic Fracturing to Associated Seismic Event
0 60 240 420 600 780 960 1140 1320120 300 480 660 840 1020 1200 1380180 360 540 720 900 1080 1260 1440
1.0
1.5
0.5
2.5
3.5
2.0
3.0
4.0
Richter
Scale
Magnitude
Minutes (12 hrs) (24 hrs)
Start of Hydraulic Fracturing Operation
330 Mins (5.5 hrs): Average Duration of Hydraulic Fracturing Stage
Minutes to Seismic Events
Mag 2.14 145 mins
Mag 2.01 9 mins
Mag 2.66 146 mins
Mag 2.55 49 mins
Mag 2.70 108 mins
Mag 1.97 110 mins
Mag 2.29 179 mins
Mag 2.50 333 mins
Mag 2.09 273 mins
Mag 2.54 660 mins
Mag 2.17 681 mins
Mag 2.02 409 mins
Mag 3.04 962 mins
Mag 1.94 1043 mins
Mag 2.42 751 mins
Mag 2.02 877 mins
Mag 1.91 707 mins
Mag 2.60 1408 mins
10,000 m3
5,000 m3
Frac Fluid Placed
21Investigation of Observed Seismicity in the Horn River Basin
Proximity to pre-existing faults, injection volumes,
breakdown pressures and hydraulic fracture pump rates
were examined as possible controls on seismicity.
Dense array data was used by an operator to compare
pumping rates and fault proximity to seismicity frequency
and magnitude at the d-1-D pad. The operator study
concluded that seismicity was greatest near pre-existing
faults and subsided away from the mapped fault fairway.
As hydraulic fracturing proceeded from toe to heel along
horizontal wellbores, seismicity magnitude increased
as wellbore stages encountered micro-seismically
visible faults. Higher magnitude events, caused by fault
movement, declined or fell off completely as completion
stages moved away from faulting. According to the
operator study, as hydraulic fracturing stages continued
along the horizontal legs and pump power was reduced,
events became less frequent. This indicates either
no faults were being intersected or additional faults
encountered were not critically stressed or injection was
insufficient to trigger fault movement. The operator analysis
concluded that proximity to faulting appeared to have a
greater effect on seismicity than pump rates.
Faulting was identified on microseismic plots and 3-D
seismic supported fault mapping provided by operators.
In only one case did a linear seismicity swarm clearly
Controls on Seismicity
coincide with a 3-D seismic mapped fault. A much larger
linear swarm of events mapped at d-1-D, interpreted
to be occurring along a single reactivated fault, had no
supporting 3-D mapped faulting. Microseismic plots were
not available for the May 19, 2011 3.8 ML
event. The
maximum event verified by dense array and visible on
microseismic plot was the July 7, 2011, 3.1 ML
(NRCan)
event located within the large linear swarm at d-1-D
(figure 7).
At Etsho, an operator analysis showed a slight correlation
between hydraulic fracture pumping rates and event
magnitude and frequency. Pump rates were reduced
from16 m3
/min to 13 m3
/min on July 19, 2011. In this
operator analysis, after the July 19 pump rate reduction,
the frequency of higher magnitude events decreased.
Figure 11 shows the results of a Commission analysis.
Event magnitudes, collected from the dense array,
from June 23 to July 31 are compared to pump rates,
breakdown pressures and injection volumes for the
corresponding period. Magnitudes are averages of all
events occurring on the date. Pump rates, pressures and
volumes were averaged by date for all the wells on the
d-1-D/94-O-8 pad. The magnitude drop around July 9
(Figure 11) indicates a decline in magnitude as hydraulic
fracturing stages moved away from pre-existing faults
that became active as a result of fluid injection. Although
pump rates were below average from July 15–20, no
corresponding decline in magnitudes is seen in this
analysis. Some periods of direct relationship can be seen
between breakdown pressures and magnitudes. As
stated previously, magnitudes decline around July 9 as
completions move away from the active faulted interval.
Magnitudes after July 9 suggest few events past that date
are related to fault movement.
Within the active faulted zone (June 23 to July 9)
magnitudes show some correlation to breakdown
pressures.
Investigation of Observed Seismicity in the Horn River Basin22
Figure 11: Change in average magnitude with changes in daily fracture
volume, pump rate and breakdown pressure over time. Frac fluid placed,
pump rates and breakdown pressures are daily averages taken from
d-1-D pad completions report. Magnitudes are also daily averages.
Hydraulic fracturing pump rates at Kiwigana were maintained
at slightly below 13 m3
/min. Micro-seismicity frequency and
magnitude were fairly consistent during the Oct. 2011 to Jan. 2012
hydraulic fracturing operations, with magnitudes ranging from -1.7
to 1.9 ML
.
Eighteen events were above 1.0 ML
for a period from Nov. 6-10,
2011 suggesting minor fault movement. A review of microseismic
plots for this time period shows that as the initial hydraulic
fracturing stages were completed in the c-A15-D wellbore, a
trailing swarm of microseismic points, indicating fault slippage,
extended below and to the southwest of the completion interval
and stage location. Here again, fluid injection at a fracturing
stage while proximal to a critically-stressed fault appears to trigger
seismicity.
At Kiwigana, a consistent, relatively low pump rate may have been
effective in mitigating seismicity magnitude and frequency. Only 18
events were interpreted to be the result of fault movement. None
of these very low magnitude events were detected by NRCan or
felt at surface.
2011 Horn River Pad Operations d-1-D Pad
Breakdown Pressure versus Average Magnitude
June July
32
48
46
42
44
50
40
36
38
34
23 5 17 2924 6 18 3025 7 19 3126 8 2027 9 211 13 2528 10 2229 11 232 14 2630 12 243 15 274 16 28
Breakdown
Pressure
(MPa)
Average
Magnitude
(ML)
0.8
-0.4
-0.2
0.0
0.2
-0.6
0.4
1.0
0.6
Pump Rate versus Average Magnitude
June July
0
16
14
10
12
18
8
4
6
2
23 5 17 2924 6 18 3025 7 19 3126 8 2027 9 211 13 2528 10 2229 11 232 14 2630 12 243 15 274 16 28
Pump Rate
(m3
/min)
Average
Magnitude
(ML)
0.8
-0.4
-0.2
0.0
0.2
-0.6
0.4
1.0
0.6
Frac Fluid Placed versus Average Magnitude
June July
3250
5250
5000
4500
4750
5500
4250
3750
4000
3500
23 5 17 2924 6 18 3025 7 19 3126 8 2027 9 211 13 2528 10 2229 11 232 14 2630 12 243 15 274 16 28
Frac Fluid
Placed
(m3
)
Average
Magnitude
(ML)
0.8
-0.4
-0.2
0.0
0.2
-0.6
0.4
1.0
0.6
23Investigation of Observed Seismicity in the Horn River Basin
The Davis and Frohlich induced seismicity criteria (Davis
and Frohlich 1993) is a generally accepted methodology
for the identification of induced seismicity. These criteria
strongly suggest the Horn River Basin seismicity was
induced by hydraulic fracturing.
Davis and Frohlich Criteria – related to Horn River Basin
1. Timing
a. Are these events the first known earthquakes of this
character in the region? Probably, only some mag >2.5ML
events would have been detected in the Horn River Basin
back to 1999. Prior to 1999, magnitude 4.0ML
events
would have been detected as far back as the 1960’s. No
events were recorded by NRCan in the Horn River Basin
prior to April 2009
b. Did the events only begin after hydraulic fracturing
had commenced? Yes, all the Horn River Basin events,
recorded by both NRCan and the operator deployed dense
array, began after hydraulic fracturing commenced.
c. Is there a clear correlation between hydraulic fracturing
and seismicity? Yes, all the seismic events in Horn River
Basin occurred during or between hydraulic fracturing
stages.
Davis and Frohlich Criteria
2. Location
a. Are epicenters within five kilometres of wells? Yes, all
epicentres occurred within five kilometres of hydraulic
fracturing operations.
b. Do some earthquakes occur at or near hydraulic
fracturing depths? Yes, the dense array report shows
seismicity occurring within 300 metres of hydraulic
fracturing stages.
c. Do epicenters appear spatially related to the production
region? Yes, all the NRCan reported events were located
within five kilometres of hydraulic fracturing operations in
the Horn River Basin. Dense array hypocentres locate the
events within 1 km.
3. Fluid pressures, etc.
a. Did hydraulic fracturing cause a significant change in
fluid pressures? Yes, hydraulic fracturing must increase
localized pressures to breakdown pressure in order to
fracture the reservoir rock. This pressure is greater than
original formation pore pressure.
b. Did seismicity begin only after the fluid pressures had
increased significantly? Yes, the events occurred after
hydraulic fracturing commenced and fluid pressures had
increased significantly.
c. Is the observed seismicity explainable in terms of current
models relating hydraulic fracturing to fault activity? Yes,
current induced seismicity models relate increased pore
pressure from fluid injection to overcoming friction along a
fault resulting in fault slippage.
Horizontal portions of wellbores at Etsho are roughly 2500
to 3000 metres long. Five of the six operators covered
by the Information Request reported no wellbore integrity
issues in 91 of the 93 wellbores at Etsho. Two instances
of wellbore deformation along horizontal sections were
reported by one operator. These occurred over a short
interval beginning at 3,011 m KB (Kelly Bushing) in the
d-A1-D/94-O-9 well. In this instance, casing deformation
was minor and did not hinder completion operations. At
d-1-D/94-O-9, the deformation was encountered at 4,245
m KB and the casing distortion blocked completion efforts
at 4,288 m KB. Neither incident posed any risk with respect
to safety, containment or fluid migration.
The operator reported that the deformation occurred in the
horizontal section of the wellbores only and no wellbore
issues were reported in the vertical sections of any wells.
This deformation was detected in July 2011. Hydraulic
fracturing stages for the two affected wellbore measured
depths were completed from June 16 to July 3, 2011.
All geophysical logs, containing wellbore caliper and
image data, were run in Sept. and Oct. 2010, prior to the
deformation occurring.
The bit (117.5mm) used to drill out the stage packers is
very close to the inside diameter of the casing (121.0mm)
and would have detected any vertical wellbore casing
distortion. As a result of not encountering any further
distortion, no subsequent casing or cement evaluation
tools were run.
Wellbore Integrity
Investigation of Observed Seismicity in the Horn River Basin24
All Etsho operators conducted two and three dimensional
seismic surveys and interpreted faulting before conducting
hydraulic fracturing operations.
Fault mapping at Etsho shows abundant faulting. Interpretations
vary but it appears most of this faulting (including the larger,
regional faults in this grouping) is deep seated and concentrated
in a north-south trending fault fairway centered at Etsho. Minor,
secondary faulting is evident, generally trending northwest to
southeast, at approximately 45 degrees.
From the data reviewed, faulting appears to be confined below
the lower Fort Simpson shale extending into the basement
(Precambrian) or within the shallower Debolt Formation.
No faulting was seen to extend through the Fort Simpson
Formation and no evidence was found that Middle Devonian
aged faulting, in this area, could provide a conduit for fluids to
zones above the Fort Simpson shale.
Faults were also interpreted from available microseismic plots.
In the case of the dense array at Etsho, daily microseismic
plots (June 16 – July 31, 2011) that showed high magnitude
events were submitted for the investigation. Along with higher
magnitude seismicity, dates and the stages hydraulically
fractured for that date were highlighted. Event dates could
be compared to the plots and fault mapping. In all cases
examined, faulting could be seen on the plots as linear swarms
or a smaller bundle of events with a large signature event
represented by a large dot. Faults can also be seen as long,
trailing legs of dots on microseismic vertical profiles (Figure
12). In this case, hydraulic fracturing fluids or a pressure
front appear to have migrated along the fault creating micro-
seismicity events that reach the underlying Keg River formation.
Pre-Existing Faults
Figure 12: Micro-seismicity events (coloured circles) and hydraulic fracture stages (green ellipses) along horizontal wellbore legs.
1.	 The seismicity observed and reported by NRCan
in the Horn River Basin between April 2009 and
December 2011 was induced by fault movement
resulting from injection of fluids during hydraulic
fracturing.
2.	 No injuries or property damage were reported as a
result of the induced seismicity. Only one event was
reported by NRCan to have been felt at the ground
surface.
3.	 The fractures developed during the hydraulic
fracturing operations studied within the investigation
were effectively confined to the target Horn River
shales by the overlying Ft. Simpson shales. No
effects on shallow aquifers or the environment were
identified.
4.	 The magnitude and frequency of the induced
seismicity investigated by the Commission may be
influenced by numerous factors including pump rate,
breakdown pressure and proximity to pre-existing
faults.
Findings
5.	 No casing deformation was reported in the vertical
portion of wellbores and no reservoir containment
issues were identified. Minor casing deformation
within the horizontal well portion of target shale
formations occurred in 2 instances. The cause of the
casing deformation could not be conclusively linked to
the seismicity.
6.	 Fault mapping provided by operators shows abundant
sub parallel north-south trending faulting through the
Etsho and Tattoo areas. These faults are generally
deep seated and do not show displacement above
the Ft. Simpson shale. The Ft. Simpson shale is
considered to be a ductile fracture barrier. Fault
reactivation in this structural setting is not considered
a threat to shallow overlying aquifers.
7.	 Seismograph station additions are needed to the
CNSN to improve monitoring for induced seismicity in
northeast British Columbia.
25Investigation of Observed Seismicity in the Horn River Basin
Investigation of Observed Seismicity in the Horn River Basin26
1.ImprovetheaccuracyoftheCanadianNationalSeismograph
NetworkinnortheastB.C.
During the investigation it became evident that the existing
coverage of the CNSN, operated by NRCan for northeast
B.C. is adequate for large conventional earthquake
detection but could not reliably provide the spatial accuracy
necessary to positively identify smaller seismic events
associated with induced seismicity. The current grid did
not detect 15 magnitude 2.0 to 3.0 ML
events which were
detected by the more accurate dense array temporarily
installed at Etsho.
The Commission has been working with NRCan and
the Alberta Geological Survey to determine what
enhancements to the existing detection grid are needed
to provide accurate and timely identification of induced
seismicity.
Action: Geoscience BC has organized funding for a
five year project to install and operate six additional
seismograph stations for the CNSN. NRCan has
completed site surveys and installation is scheduled for
late 2012. The enhanced grid will reliably identify induced
seismicity, providing detection sensitivities below 2.0 ML
and surface location accuracy to within one kilometre.
Recommendations
2.Performgeologicalandseismicassessmentstoidentifypre-
existingfaulting.
While several faults were believed to have been
intersected by wellbores at Etsho, only a few of these
faults slipped resulting in seismicity. In one case a mapped
fault coincided with a microseismic plot event swarm. In
other areas, seismicity occurred where faults had not
been mapped. It currently cannot be determined which
intersected fault will move or what injection pressure
or volume will trigger the event. Operators do identify
as many pre-existing faults as practical and can tailor
their hydraulic fracture programs to include enhanced
monitoring for seismicity when completing near these faults
Action: Operators should review geological and seismic
data to identify pre-existing faulting. If induced seismicity
is detected, the active fault could be located and avoided
in subsequent wellbores. Additional mitigation procedures,
such as bypassing stages adjacent to a known active fault
might also be considered. Monitoring for events will be
done by the Commission under Recommendation 3.
3.Establishinducedseismicitymonitoringandreporting
ProceduresandRequirements.
A notification and consultation procedure provides a means
for the Commission to respond to induced seismicity in
northeast B.C. If seismicity is detected on the CNSN or
an operator deployed dense array, the Commission would
contact the operator to investigate the occurrences and
determine appropriate mitigation options when required.
Action: Each case will require a unique response.
Incidents will be evaluated on the basis of event frequency,
magnitude, ground motion, depth and proximity to
populated areas. In the case of the Horn River Basin area,
the Commission will commence consultations regarding
additional monitoring requirements or mitigation as soon as
induced seismicity is detected.
Specific to the Horn River Basin, with the additions to the
CNSN, induced events should be reliably and consistently
detected and reported at magnitude 2.0 ML
. Mitigation
discussions with the operator will begin immediately.
Mitigation steps taken will vary dependent on the risk
posed by the events and may include enhanced data
recovery for research purposes.
An order to suspend hydraulic fracturing specific to the
well under completion could be issued dependent on
an evaluation of the previously stated criteria of event
frequency, magnitude, ground motion, depth and proximity
to populated areas. Operators will immediately suspend
hydraulic fracturing operations for a well upon detection of
a 4.0 ML
or greater event.
4.StationgroundmotionsensorsnearselectedNEBC
communitiestoquantifyriskfromgroundmotion.
Along with location and depth, it is important to know how
much the ground actually moved at a given location during
a seismic event. Ground motion sensors record ground
acceleration and enable a correlation between magnitude
27Investigation of Observed Seismicity in the Horn River Basin
and ground acceleration. This has implications for human
safety and infrastructure integrity.
Action: NRCan experts will be consulted to determine
equipment selection, location, installation and operation of
ground motion sensor stations.
5.TheCommissionwillstudythedeploymentofaportable
denseseismographarraytoselectedlocationswhereinduced
seismicityisanticipatedorhasoccurred.
A dense array, separate from the regional grid, is
necessary to determine event depth, a key to diagnosing
induced seismicity. Depth is required to fully understand
the range of fault movement and risk to shallow aquifers.
Focal mechanism determination, improved location
resolution and lower magnitude detection are also possible
benefits of a dense array. They can be designed to be
quickly deployable, placed on the ground, and may require
as few as five seismographs.
Action: Two operators have deployed three dense arrays
in the Horn River Basin and an additional research dense
array is being considered by NRCan for the Basin. The
Commission will seek funding for a portable dense array
to be deployed as needed for induced seismicity research
and data collection.
6.Requirethesubmissionofmicro-seismicreportstomonitor
hydraulicfracturingforcontainmentofmicrofracturingandto
identifyexistingfaults.
Microseismic data can identify geological features such
as faults where there may be increased risk of inducing
seismicity beyond magnitude 2.0 ML
. In addition,
microseismic plots can verify that hydraulic fracturing is
confined to the target zone by outlining both the vertical
and lateral extent of the fracturing.
Action: The Commission will develop requirements for
submission of information gathered from microseismic
monitoring during hydraulic fracturing. Data gathered will
be limited to that which is necessary to show fracture
containment and faulting. The format shall be determined
in consultation with stakeholders including other regulators
outside of British Columbia. Consideration of the
proprietary nature of microseismic data must be included in
the development of submission requirements.
7.Studytherelationshipbetweenhydraulicfracturing
parametersandseismicity.
At Etsho and Kiwigana magnitudes may have declined as
pump rates were reduced or held low. This investigation
found weak correlations between pump rates and
magnitude and breakdown pressure and magnitude. The
historical response to induced seismicity from fluid injection
has been to either stop operations or reduce injection
rates. Seismicity frequency at the Rangely oilfield in
Colorado (Gibbs et al, 1972) directly corresponded to the
amount of water injected per year.
Action: The Commission is continuing its analysis of
hydraulic fracturing data to attempt to find correlations
between hydraulic fracturing parameters and event
magnitude. Reducing pump rates or injection volumes will
be considered if induced seismicity is detected beyond the
criteria set out under recommendation three.
Investigation of Observed Seismicity in the Horn River Basin28
Horn River Basin seismicity events, from 2009 to late 2011,
were caused by fluid injection during hydraulic fracturing.
All events occurred during or between hydraulic fracturing
stage operations. Dense array data accurately placed the
depth and location of events at or near hydraulic fracturing
stages. Only one event was reported as “felt” and no
events were felt beyond 10 km of the epicentres.
Faulting transecting horizontal wellbores can be identified
on microseismic plots. Some events greater than 2.0 ML
were located at the intersection of faults and wellbores
when adjacent hydraulic fracturing stages were being
completed. In other circumstances, faults intersected
wellbores yet no anomalous events were detected. Fault
movement is dependent on numerous factors such as in-
situ stress and there is no reliable method to identify which
faults will slip or under what conditions. Further research
is needed to determine if induced seismicity from hydraulic
fracturing can be controlled by either altering hydraulic
fracturing parameters or by fault characterization and
avoidance.
The current coverage of the CNSN was designed as part
of a national large earthquake preparedness system and is
inadequate for the reliable detection of induced seismicity.
Only four of the 19 (2.0 to 3.0 ML
) events detected by the
dense array at Etsho between June 23 and Aug. 15, 2011
were detected by the current regional grid. Recommended
Conclusion
improvements to the CNSN will improve location resolution
to within one km and magnitude detection to <2.0 ML
.
Site surveys for the additional seismograph stations being
added to the CNSN have been completed. Installation
of the new stations is tentatively scheduled for late 2012.
Dense arrays will be deployed where appropriate to
determine event depth and precise location.
None of the events under investigation resulted in any
injury or property damage and only 1 event was recorded
by NRCan as having been “felt” at the surface. The
recommended ground motion sensors will accurately
record any ground acceleration from future events. This
enables a correlation between magnitude and any ground
motion and eliminates the need to rely on ‘felt’ reports to
gauge possible effects at surface.
Recommended improvements to the CNSN and
implementation of a notification and consultation procedure
will provide the necessary early detection and mitigation
action as well as for additional research on mitigation
methods. It is essential to take pre-emptive steps to
ensure future events are detected and the regulatory
framework adequately provides for the monitoring,
reporting and mitigation of all seismicity related to hydraulic
fracturing thereby ensuring the continued safe and
environmentally responsible development of shale gas
within British Columbia.
Davis, S.D. and Frohlich, C., 1993. Did (or will) fluid
injection cause earthquakes? – Criteria for a Rational
Assessment, Seismol. Res. Lett. 64(3-4), 207-224
De Pater, C.J. and Baisch, S., 2011 Geomechanical
Study of Bowland Shale Seismicity, Synthesis Report
commissioned by Cuadrilla Resources Ltd.
Gibbs, J., Healy, J., Raleigh, C., Coakley, J. 1972
Earthquakes in the Oil Field at Rangely, Colorado, U.S.
Geological Survey, Open File Report 72-130
Holland, Austin, 2011, “Examination of Possibly Induced
Seismicity from Hydraulic Fracturing in the Eola Field,
Garvin County, Oklahoma”, Oklahoma Geological Survey
Open File Report OF1, 2011.
Horner, R.B., Barclay, J.E. and MacRae, J.M. ,1994,
Earthquakes and Hydrocarbon Production in the Fort St.
John Area of Northeastern British Columbia, Canadian
Journal of Exploration Geophysics, Vol. 30, No. 1, (June
1994), P. 38-50
References
MacLean, B.C., Morrow, D.W., 2004, Bulletin of Canadian
Petroleum Geology, Vol. 52, No. 4 (December 2004, P.
302-324
McPhail, S., Walsh, W., Lee, C., Monahan, P.A., 2008,
British Columbia Energy and Mines, Open File, Report #
2008-1
Nicholson, C. and R.L. Wesson, 1990, Earthquake Hazard
Associated With Deep Well Injection – A Report to the U.S.
Environmental Protection Agency, U.S. Geol. Surv. Bull,
1951.
Hayes, B.J., 2010, HORN RIVER BASIN Subsurface
Aquifer Characterication Project, Presentation to
Unconventional Gas Technical Forum, Geoscience BC
project
29Investigation of Observed Seismicity in the Horn River Basin

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Investigation of Observed Seismicity in the Horn River Basin (38 characters

  • 1. Investigation of Observed Seismicity in the Horn River Basin BC Oil and Gas Commission - August 2012
  • 2. The BC Oil and Gas Commission is the single-window regulatory agency with responsibilities for regulating oil and gas activities in British Columbia, including exploration, development, pipeline transportation and reclamation. The Commission’s core roles include reviewing and assessing applications for industry activity, consulting with First Nations, ensuring industry complies with provincial legislation and cooperating with partner agencies. The public interest is protected by ensuring public safety, protecting the environment, conserving petroleum resources and ensuring equitable participation in production. For general information about the Commission, please visit www.bcogc.ca or phone 250-794-5200. About the BC Oil and Gas Commission Fort St. John Fort Nelson Dawson Creek Kelowna Victoria www.bcogc.ca Terms Used in this Report ‘Seismicity’, ‘Seismic Events’ and ‘Events’ – used interchangeably to describe seismograph recorded earthquakes caused primarily by fault movement. ‘Micro-Seismicity’ – very low magnitude events created by shear movement or tensile fracture during hydraulic fracturing not detectable by the Canadian National Seismograph Network (CNSN). ‘Microseismic’ – describes both the recording and processing of very small magnitude events produced by hydraulic fracturing. ‘Induced Seismicity’ – generally defined as earthquakes resulting from human activity. ‘Stage’ – refers to a hydraulically fractured interval along a horizontal wellbore, each stage is isolated and perforated prior to the injection of fluids to hydraulically fracture the reservoir rock. 03 Executive Summary 04 Event Summary 06 Investigation Overview 08 Induced Seismicity in B.C. 12 Literature Review 14 Analysis 21 Controls on Seismicity 23 Davis and Frohlich Criteria 25 Findings 26 Recommendations 28 Conclusion 29 References Table of Contents
  • 3. This report provides the results of the BC Oil and Gas Commission’s (Commission) investigation into anomalous seismicity within geographically confined and remote areas in the Horn River Basin between April 2009 and December 2011. The investigation was commenced immediately after the Commission became aware of a number of anomalous, low-level seismic events which were recorded by Natural Resources Canada (NRCan) near areas of oil and gas development. Only one of the events under investigation had been reported by NRCan as “felt” at the earth’s surface. In undertaking the investigation, the Commission notes that more than 8,000 high-volume hydraulic fracturing completions have been performed in northeast British Columbia with no associated anomalous seismicity. None of the NRCan reported events caused any injury, property damage or posed any risk to public safety or the environment. The investigation was completed by the Commission’s geological and engineering staff within the Resource Development department, and they benefited from consultation with NRCan, the University of British Columbia and the Alberta Geological Survey. Data was obtained from numerous sources including open source information as well as proprietary data acquired by oil and gas companies working near the area of the investigation. Executive Summary The Commission also acknowledges the professional, open and honest exchanges of information and analyses between the regulated industry and the investigation team. The investigation has concluded that the events observed within remote and isolated areas of the Horn River Basin between 2009 and 2011 were caused by fluid injection during hydraulic fracturing in proximity to pre-existing faults. Three sets of events are discussed in the report, the 38 events reported by NRCan, 216 events recorded by a dense array deployed at Etsho and 18 events recorded by a dense array deployed at Kiwigana. All these events are interpreted to be the result of fault movement. The Etsho dense array monitored the d-1-D/94-O-8 pad. Events, recorded by this array, occurred on microseismic plots along linear trends interpreted to be faults. In only one instance did a linear seismic swarm overlay a fault mapped with 2D or 3D seismic. Fault maps interpreted from 2D and 3D seismic were submitted for the investigation. These showed 12 mapped faults intersecting five of the 7 d-1-D pad wellbores. No events could confidently be linked to 11 of these faults, indicating that most of the faults intersected either did not slip or did move without generating a detectable event. Disposal wells were ruled out as a source of the seismicity during the investigation. Four disposal wells were operating during the period of observed seismicity: three at Etsho and one in the Tattoo area. These wells were injecting recovered hydraulic fracturing fluids into the Mississippian Debolt Formation, 1800 metres above the Horn River Group. All event epicentres occurred within the Devonian Horn River Group and no fault movement was seen in the Debolt Formation. The Commission makes seven recommendations based on the investigation, which include the submission of microseismic reports; establishment of a notification and consultation procedure; studying the relationship of hydraulic fracturing parameters on seismicity, and upgrading and improving B.C.’s seismograph grid and monitoring procedures. Improvements to the seismographic grid network have already begun through funding provided by Geoscience BC. The upgraded grid will provide improved monitoring for induced seismicity and will form the basis for the monitoring, detection, notification and consultation procedure. In addition, the Commission has initiated a broader study with the University of British Columbia to examine factors related to the extent, magnitude, impact and control of induced seismicity in northeast B.C. The intent of this research is to provide insights into predicting the location and magnitude of seismic events based on hydraulic fracturing parameters and geomechanics and to establish protocols for prediction, detection, monitoring and mitigation of these events. 3Investigation of Observed Seismicity in the Horn River Basin
  • 4. Investigation of Observed Seismicity in the Horn River Basin4 Between April 2009 and July 2011, 31 seismic events were recorded and located by NRCan in the Etsho area of the Horn River Basin in northeast British Columbia (Figure 1). Another seven events were recorded near the Tattoo area between Dec. 8 and Dec. 13, 2011. The observed events ranged in magnitude between 2.2 and 3.8 ML on the Richter scale as recorded by NRCan (Table 1). Asearch of the areas in the National Earthquake Database from 1985 to present shows no detected seismicity in the Horn River Basin prior to 2009. Two events (1985/09/04, 3.1ML and 1986/09/28, 2.9ML ) located approximately 160 km south and southwest of Fort Nelson were detected by the Canadian National Seismograph Network (CNSN). This suggests that similar events occurring in the Horn River Basin could have been recorded. Two NRCan seismograph stations, part of the CNSN, are currently operational in northeast British Columbia. The Bull Mountain station near Hudson’s Hope became operational in January 1998 and the Fort Nelson station came online in 1999. Magnitudes have been processed and reported down to approximately 2.0 ML in the Horn River Basin since deployment of these two stations. Smaller events may have occurred and gone undetected due to the detection limitations of the CNSN. While the full extent of historical seismicity is not known, the April 2009 to December 2011 Etsho and Tattoo events are considered anomalous events when considered in full context. Event Summary Figure 1: Location of Etsho,Tattoo and Kiwigana areas in the Horn River Basin. Red triangles show NRCan reported epicentres, Bovie andTrout Lake Fault zones noted. Liard Basin to west of Bovie Fault. Blue star indicates location of Kiwigana seismograph array. #* #* #*#*#* #* #* #* #* #* #* #* #* #* #* #* #*#* #*#* #*#* #* #* #* #* #* #* #* #* #* #* #*#* #* #*#* #* ## # ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ((( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ((( ( ( ( ( ( ( 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""""""""""""""""""" """"""" " " Northwest Territories Fort Nelson 094O11 094O16 094P13 094J15 094P04 094J16 094O06 094O14 094I13 094O02 094J14 094O10 094O09 094P12 094O01 094O03 094O07 094O08 094O15 094P05 HORN RIVER BASIN LIARD BASIN BovieLakeFault TroutLake FaultZone 121°45'0"W 121°45'0"W 122°0'0"W 122°0'0"W 122°15'0"W 122°15'0"W 122°30'0"W 122°30'0"W 122°45'0"W 122°45'0"W 123°0'0"W 123°0'0"W 123°15'0"W 123°15'0"W 59°45'0"N 59°45'0"N 59°30'0"N 59°30'0"N 59°15'0"N 59°15'0"N 59°0'0"N 59°0'0"N Tattoo Field 0 5 10 152.5 Kilometers #* Earthquakes ! Major Cities " Well Surface Hole ( Well Bottom Hole Well Directional Survey Earthquakes NEBC 2009 - 2012 1:500,000 ! ! ! ! Kelowna Victoria Fort Nelson Fort St. John Tattoo Area Etsho Area Kiwigana ^_
  • 5. 5Investigation of Observed Seismicity in the Horn River Basin Table 1 provides a summary of the events recorded by NRCan in the Etsho and Tattoo areas that are plotted and shown on Figure 1. The events in Table 1 were proximate to oil and gas activities employing hydraulic fracture operations when the events occurred. Table 1 – Magnitude and Location of NRCan Seismic Events, with date and time. Modified from NRCan report. www.earthquakescanada.nrcan.gc.ca/ Event # Date Time (UT) Time (Pacific) Correct Date Lat Long Mag Approximate Location 38 2011/12/13 13:17:32 5:17:32 59.84 -122.66 3.1ML 114 km N of Fort Nelson 37 2011/12/12 23:34:12 15:34:12 59.81 -122.68 3.1ML 110 km N of Fort Nelson 36 2011/12/12 07:59:22 23:59:22 12/11/2011 59.82 -122.69 2.9ML 112 km N of Fort Nelson 35 2011/12/11 09:15:57 1:15:57 59.85 -122.69 2.4ML 114 km N of Fort Nelson 34 2011/12/11 02:37:53 18:37:53 12/10/2011 59.87 -122.67 2.9ML 116 km N of Fort Nelson 33 2011/12/10 02:52:34 18:52:34 12/9/2011 59.87 -122.69 2.9ML 117 km N of Fort Nelson 32 2011/12/08 15:28:37 7:28:37 59.81 -122.65 2.8ML 111 km N of Fort Nelson 31 2011/07/14 10:40:32 2:40:32 59.51 -122.20 2.5ML 82 km NE of Fort Nelson 30 2011/07/07 22:46:37 14:46:37 59.49 -122.40 3.1ML 76 km NNE of Fort Nelson 29 2011/07/01 09:32:46 1:32:46 59.54 -122.49 2.6ML 81 km NNE of Fort Nelson 28 2011/06/26 13:17:02 5:17:02 59.56 -122.37 2.7ML 84 km NNE of Fort Nelson 27 2011/06/18 23:02:03 15:02:03 59.82 -121.47 2.8ML 132 km NE of Fort Nelson 26 2011/05/29 08:09:47 0:09:47 59.54 -122.46 3.1ML 81 km NNE of Fort Nelson 25 2011/05/20 06:22:34 22:22:24 5/19/2011 59.51 -122.52 3.0ML 78 km NNE of Fort Nelson 24 2011/05/19 13:13:43 5:13:43 59.47 -122.47 3.3ML 74 km NNE of Fort Nelson 23 2011/05/19 13:05:15 5:05:15 59.49 -122.41 3.8ML 76 km NNE of Fort Nelson 22 2011/05/10 14:16:03 6:16:03 59.51 -122.37 3.5ML 79 km NNE of Fort Nelson 21 2011/05/03 12:56:29 4:56:29 59.51 -122.32 3.2ML 80 km NNE of Fort Nelson 20 2011/04/30 13:27:30 5:27:30 59.46 -122.59 3.1ML 72 km N of Fort Nelson 19 2011/04/28 22:34:51 14:34:51 59.47 -122.47 2.5ML 73 km NNE of Fort Nelson 18 2011/04/07 12:19:20 4:19:20 59.50 -122.51 3.2ML 76 km NNE of Fort Nelson 17 2011/03/04 03:09:05 19:09:05 3/3/2011 59.50 -122.34 3.3ML 78 km NNE of Fort Nelson 16 2010/10/12 21:01:11 13:01:11 59.55 -122.38 3.4ML 83 km NNE of Fort Nelson 15 2010/10/12 19:19:44 11:19:44 59.53 -122.31 3.0ML 83 km NNE of Fort Nelson 14 2010/10/12 17:09:40 9:09:40 59.59 -122.45 3.4ML 87 km NNE of Fort Nelson 13 2010/10/09 10:00:31 2:00:31 59.54 -122.42 3.1ML 82 km NNE of Fort Nelson 12 2010/10/05 22:01:14 14:01:14 59.60 -122.39 3.6ML 88 km NNE of Fort Nelson 11 2010/10/05 13:30:28 5:30:28 59.53 -122.27 3.1ML 83 km NNE of Fort Nelson 10 2010/10/04 11:09:34 3:09:34 59.59 -122.36 2.9ML 88 km NNE of Fort Nelson 9 2010/10/03 08:06:50 0:06:50 59.56 -122.27 3.5ML 86 km NNE of Fort Nelson 8 2010/09/30 12:33:36 4:33:36 59.58 -122.48 3.0ML 85 km NNE of Fort Nelson 7 2010/09/30 12:31:43 4:31:43 59.60 -122.39 2.9ML 89 km NNE of Fort Nelson 6 2010/08/22 09:30:20 1:30:20 59.53 -122.23 2.4ML 84 km NE of Fort Nelson 5 2010/08/03 20:15:35 12:15:35 59.51 -122.27 2.7ML 81 km NNE of Fort Nelson 4 2010/06/11 22:25:19 14:25:19 59.50 -122.30 3.4ML 79 km NNE of Fort Nelson 3 2009/04/09 16:34:00 8:34:00 59.48 -122.01 2.2ML 83 km NE of Fort Nelson 2 2009/04/08 21:30:23 13:30:23 59.43 -121.92 2.3ML 82 km NE of Fort Nelson 1 2009/04/08 21:27:37 13:27:37 59.46 -122.02 2.3ML 81 km NE of Fort Nelson
  • 6. Investigation of Observed Seismicity in the Horn River Basin6 The Commission began a formal investigation in July 2011 into the anomalous events recorded by NRCan in the Etsho area. The investigation was extended to the Tattoo area when similar anomalous events were detected there in December 2011. The purposes of the investigation were to: • Examine the available evidence to determine if there may be a linkage between oil and gas activities and the observed events. • Review current research on induced seismicity and apply those results to the investigation. • Consider possible mitigation methodologies, where appropriate, should a link be established between the observed events and oil and gas activities. The Commission began the investigation with a review of hydraulic fracturing and well completion information on wells situated near the area of observed seismicity in the Etsho area. The dates and times of hydraulic fracturing operations were compared to the dates and times of recorded seismicity events. To obtain additional information to assist in the investigation, the Commission issued formal Information Requests (IRs) to six operators within the study area. The IRs provided the Commission access to data not currently required to be submitted by the operators to the Commission. Much of this operator information obtained Investigation Overview is proprietary and includes detailed completion statistics, microseismic reports, groundwater analyses and seismic mapping. In some cases, confidential data is used to support findings or analyses but not reproduced within the report. Under British Columbia legislation and regulation, specified oil and gas information is required to be collected and submitted to the Commission. This includes geophysical logs, sample reports and drilling and completion information. Data is held confidential for a time period as defined in the regulation, dependent on well classification. Through the course of the investigation, the Commission consulted with experts from industry, NRCan, the University of British Columbia and the Alberta Geological Survey. A literature search was done as part of the investigation, focusing on science and analysis of induced seismicity as well as the geology of the Horn River Basin. Included in this search were a number of recent public reports on induced seismicity incidents in Oklahoma, England and Ohio.
  • 7. Table 2: Richter Scale diagram showing range of magnitudes and effects. Based on US Geological Survey documents. Event Frequencies courtesy of USGS (estimates). Magnitude (ML ) Description Earthquake Effects Natural Seismicity OccurencesWorldwide -3.0 – 0.5 Micro-Seismicity Micro events created when hydraulic fracturing breaks rock, including micro shear movement and tensile fracturing, not felt Very frequent. Detection reliability extremely varied. Frequency estimated at many millions of events per year. 0.5- 2.0 Micro earthquake Very small earthquakes, not felt. Very frequent. Detection reliability extremely varied. Frequency estimated at many millions of events per year. 2.0–2.9 Minor Generally not felt, but recorded. (Not felt in Horn River Basin) 1,300,000 3.0–3.9 Minor Often felt, but rarely cause damage. 130,000 4.0–4.9 Light Noticeable shaking of indoor items, rattling noises. Significant damage unlikely. 13,000 Background Information Measuring Earthquakes Unless otherwise noted, earthquake magnitudes reported in this investigation are Richter scale magnitudes (ML ) (Table 2) and occur throughoutthisreportasbothpositive and negative numbers. The Richter magnitude scale was originally calibrated to a seismograph in 1935. At that time, zero on the scale was set as an event that would cause a one micrometre displacement on a seismogram 100 kilometres (km) from an epicentre. Instrument sensitivity has improved with time and modern seismographs are capable of detecting earthquakes that fall below the original zero value set by Richter. Negative Richter values account for this enhanced sensitivity. Duration magnitude (Md) used by Holland (Holland, 2011) scales earthquakes using surface wave durations and is consistent with the Richter scale. 7Investigation of Observed Seismicity in the Horn River Basin
  • 8. Investigation of Observed Seismicity in the Horn River Basin8 The locations of earthquakes are generally referred to using the terms “epicentre” and “hypocentre” or “focus”. The epicentre is the location on the earth’s surface located directly above the “hypocentre” or “focus” where an event actually occurs underground. The CNSN is designed to monitor moderate to strong magnitude earthquakes that pose a risk to public safety and not to detect low magnitude induced seismicity. Currently, the portion of the CNSN for northeast British Columbia consists of two stations, the Bull Mountain (Hudson’s Hope) and Fort Nelson seismograph stations. The limited station coverage in the region results in an uncertainty of 5 to 10km in the epicentral locations of detected earthquakes. The uncertainty in earthquake focal depths is even larger. Minimum magnitude detection by CNSN for earthquakes in the northeast BC region is estimated at 2.0 ML but in the course of the investigation, it was found that the current grid had failed to detect 15 events greater than 2.0 ML . From June 23 to August 14, 2011, an operator deployed local seismograph array at Etsho detected 19, 2.0 to 3.0 ML events. Only four of these events were reported by NRCan. Station Coverage of the Canadian National Seismograph Network (CNSN) Induced seismicity may be caused by numerous factors including slippage along fault planes, ground subsidence from collapse of solution mines and stress release from reservoir depletion. Fault movement can occur when previously stable subsurface stress conditions are altered. Human activities that can alter these stress conditions include fluid injection for secondary recovery in hydrocarbon reservoirs, injection of waste fluids into deep rock formations, withdrawal of hydrocarbons from reservoirs and geothermal energy operations involving deep fluid injection. Fluid injection may trigger induced seismicity. As fluid is injected, it flows into the existing pore system of the rock and into pre-existing fractures and faults. Across faults injection can increase pore pressure, counter-acting normal stress across the fault and may act to open an existing fault plane. This overcomes friction along the fault and can cause fault slippage. In British Columbia, the only documented case of induced seismicity, linked to oil and gas activity, occurred in the Eagle Field area, approximately five km north of Fort St. John. Twenty-nine Richter magnitude 2.2 to 4.3 events were recorded from November 1984 to May 1994. Horner (Horner, 1994) used the Davis and Frohlich criteria (Davis and Frohlich, 1993) to conclude that the events were induced. High pressure fluid injection for secondary oil recovery was identified as a possible cause. High volume hydraulic fracturing was not employed in the area at that time. In response to the Eagle Field incident, the regulator ordered the injection pressure be lowered. Since that time, reservoir waterflood and injection pressures within British Columbia are required to be maintained below levels capable of re-opening pre-existing fractures or faults. This requirement ensures the integrity of confinement boundaries and prevents fluid migration beyond the targeted formations. Induced Seismicity in British Columbia
  • 9. The Horn River Basin in northeast British Columbia lies between Fort Nelson and the Northwest Territories border (Figure 2). Basinal shales of the Horn River Group fill the Basin, bounded to the west by the Bovie fault and to the east by laterally equivalent Keg River and Slave Point Formations reef carbonates (Figure 3). The Muskwa, Otter Park and Evie Formations of the Horn River Group are highly siliceous, high organic content shale gas targets (McPhail et al, 2008). Overlying the Horn River Group are over 800 metres (m) of clay rich shales of the Fort Simpson Formation (Figure 3). As mineralogy transitions from the siliceous shales of the Muskwa Formation to the clay rich shales of the overlying Fort Simpson, a natural barrier to fracture propagation occurs and the growth of fractures caused by hydraulic fracturing is contained to the targeted Muskwa and Evie shales. The Bovie Fault extends over 100 km from the northern British Columbia border south and then southwest into the foothills. This fault separates the Horn River Basin from the Liard Basin (Figure 1). Trending northeast from about 30 km south of Maxhamish Lake toward the Celibeta High is the Trout Lake Fault zone with a strike-slip component. (MacLean, Morrow, 2004). Figure 2: Provincial map of British Columbia showing locations and outlines of Horn River and Liard Basins and Cordova Embayment Geology of the Horn River Basin 9Investigation of Observed Seismicity in the Horn River Basin
  • 10. Investigation of Observed Seismicity in the Horn River Basin10 Figure 3: Cross-section of Horn River Basin showing Muskwa, Otter Park and Evie formation shale gas targets. Horizontal wellbores target the Muskwa, Otter Park and Evie zones. Diagram modified from Geoscience BC Horn River Basin Subsurface Aquifer Characterization Project schematic cross-section. Otter Park metres 100 km 0 1000 West East HORN RIVER BASINLIARD BASIN Debolt/Rundle Shallow Freshwater Aquifers Dunvegan Sikanni Buckinghorse Scatter Chinkeh Triassic Mattson Surface Figure 1. Schematic stratigraphic cross-section, Horn River Basin and adjacent Liard Basin, modified from Petrel Robertson. Ft. Simpson Shale BovieFault Debolt/Rundle Slave Point / Keg River Debolt/Rundle Saline Aquifer Cretaceous (Buckinghorse) Shale Muskwa Evie
  • 11. 11Investigation of Observed Seismicity in the Horn River Basin In the Etsho study area, horizontal wells targeting the Horn River shales were hydraulically fractured using multiple stages of slickwater and sand. The horizontal leg of each well was cemented with casing and a “perf and plug” technique was used to initiate the fractures, starting at the toe of the well and proceeding to the heel. Each hydraulic fracture stage was isolated with bridge plugs and received multiple perforations prior to pumping the stage. Once all the stages were complete, the bridge plugs were drilled out and the hydraulic fracture fluid was flowed back to surface. Analysis of microseismic data shows that fracture growth within the study area is confined to the target Horn River shales. It appears that the overlying Ft. Simpson shale acts as a highly effective fracture barrier during hydraulic fracturing. Hydraulic fracturing operations in the Etsho area have been ongoing from February 2007 to late July 2011. During this period, 14 different drilling pads were used to drill over 90 wells with more than 1,600 hydraulic fracturing stage completion operations (Table 3). Hydraulic Fracturing in the Horn River Basin Table 3: Pad Hydraulic Fracturing Statistics for Etsho (non-confidential pads). Minimum, maximum and average numbers are calculated from all pad data reviewed. Only non-confidential pads are listed in the table. Well Pad Wells/Pad Stages/ Well HZ Completed (m) Fluid/Well (m3 ) Sand/Well (Tonnes) Avg Pump Rate (m3 / minute) Fracs/Pad # of Seismic Events b-100-G 5 5 1,176 11,505 710 12 26 0 c-1-J 9 16 1,837 52,429 3,072 14 147 0 b-76-K 13 15 1,752 58,386 2,454 15 180 1 d-70-J 7 14 1,391 53,800 2,692 15 74 3 d-1-D 7 27 2,727 138,005 5,484 15 176 6 c-34-L 9 18 2,200 63,000 3,200 15 162 7 b-63-K 14 23 2,452 107,738 4,505 14 347 13 Average 8 17 1,846 61,612 3,107 13 149 3 Min. 4 5 1,176 11,505 710 8 26 0 Max. 16 27 2,727 138,005 5,484 15 347 13
  • 12. Investigation of Observed Seismicity in the Horn River Basin12 Recently, two international cases of induced seismicity have been documented linking hydraulic fracturing to seismic events. In the first case, Dr. C.J. de Pater and Dr. S. Baisch (de Pater and Baisch, 2011) directly tie hydraulic fracturing in the Bowland Shale near Blackpool, England to local seismicity. In the second case, Holland (Holland, 2011) suggests a relationship between hydraulic fracturing in Garvin County, Oklahoma and local seismicity. Other studies considered during the investigation include Shale Gas Extraction in the UK: A Review of Hydraulic Fracturing published by the Royal Academy of Engineering in June 2012 and Induced Seismicity Potential in Energy Technologies (Pre-Publication) by the US National Research Council. Literature Review Near Blackpool, England, the Preese Hall–1, spudded Aug. 16, 2010, targeted gas in the Bowland shale. The Bowland shale was encountered at 1,993.3 m (metres) (6,540 feet) MD (Measured Depth) and was drilled to 2,744.4 m (9,004 feet) MD. Hydraulic fracturing ran from 2,337.8-2,727.6 m (7,670 – 8,949 feet). From March 28 to May 27, 2011 five hydraulic fracturing (slickwater) stages were run. Stage volumes ranged from 596.2–1,669.4 cubic metres (m3 ) (5,000-14,000 bbls) water and 52-117 metric tonnes proppant. Bottom-hole pressures reached a gradient of 21.4 KPa/m (0.95 psi/ft). Fifty events, magnitude -2 to 2.3 ML , (generally considered to be below the threshold for detection as a “felt” event at the surface) were recorded from March 28 to May 28, 2011. Seismicity is focused around stages 2, 4 and 5. Events began early in stage operations and the strongest event occurred 10 hours after shut-in. The occurrence of events some time after hydraulic fracturing operations is interpreted to be the effect of a pressure front spreading out from the hydraulic fracturing injection point. De Pater and Baisch (de Pater and Baisch, 2011) conclude that seismicity magnitude can be mitigated by “rapid fluid flow back after the treatments and reducing the treatment volume”. Sufficient movement occurred to deform well casing within the target formations on the horizontal leg. The casing deformation was attributed to “distributed, small magnitudes of bedding plane slip”. In Garvin County, Oklahoma, hydraulic fracturing operations began at the Picket Unit B Well 4-18 on Jan 17, 2011. This is a vertical well located in the Eola field at the northern edge of the Ardmore basin. The geology of the area consists of numerous, major, parallel faults running west-northwest to east-southeast. Several northwest to southeast trending faults intersect the major faults. The Eola field is block faulted and fault dips are near vertical. Fifty events, magnitude 1-2.8 Md (Duration Magnitude), occurred on Jan. 17-18, 2011. The events began seven hours after hydraulic fracture operations started. Thirty-nine of the events occurred within 16 hours after hydraulic fracturing operations began. Although this Blackpool, UK Garvin County, USA area of Oklahoma has considerable natural seismicity, seismological evidence indicates a unique origin different from naturally occurring earthquakes. Holland used the seven question Davis and Frohlich criteria (Davis and Frohlich, 1993) to help determine if the events were induced. The following summarizes Holland’s answers: 1. Are these events the first known earthquakes of this character in the region? (UNKNOWN) It was difficult to determine if the events were uniquely different from previously recorded earthquakes in the area. 2. Is there a clear correlation between injection and seismicity? (YES) There was a clear correlation between hydraulic fracturing and earthquake times. 3. Are the epicenters near wells (within 5 km)? (YES) The epicentres are within five kilometres of the Picket well. 4. Do some earthquakes occur at or near injection depths? (YES) Most earthquakes occurred near injection depths. Depth uncertainty on seismic recording is about 630 m. 5. If not, are there known geologic structures, that may channel flow to sites of earthquakes? (YES) Faults exist that could channel injection fluid to epicentre locations. 6. Are changes in fluid pressure at well bottoms sufficient to encourage seismicity? (YES) Hydraulic fracturing pressures are sufficient to encourage seismicity. 7. Are changes in fluid pressure at hypocentral locations sufficient to encourage seismicity? (UNKNOWN) Pressure diffusion could not be adequately modeled within the Eola Field. Holland concluded that timing and location of the events suggested a possible connection to hydraulic fracturing.
  • 13. 13Investigation of Observed Seismicity in the Horn River Basin Etsho A 20-seismograph dense array was deployed in the Etsho area to record, locate and study the seismicity in greater detail than possible with NRCan data. This array, surrounding the d-1- D/94-O-8 pad, was operated from June 16 to Aug. 15, 2011. Kiwigana A second dense array was deployed at Kiwigana, 40 kilometres to the southwest of the Etsho area (Figure 1). This 151-station seismograph array was located over the ECA HZ KIWIGANA c-15-D/94-O-7 multi-well pad and operated from Oct. 25, 2011 to Jan. 27, 2012 (Figure 4). Operator Dense Array Deployments Figure 4: Map of Kiwigana dense array, surrounding c-15-D/94-O-7 pad, showing horizontal wellbores (black lines) and seismograph locations (red dots).
  • 14. Investigation of Observed Seismicity in the Horn River Basin14 Induced Seismicity Hydraulic fracturing is the process of creating cracks (fractures), in buried geological formations to create pathways along which hydrocarbons trapped within the formation can flow into the wellbore at higher rates than otherwise possible. The hydrocarbons then flow to the surface under controlled conditions through the wellhead and are collected for processing and distribution. During the hydraulic fracturing process, a mixture of water, sand and other chemical additives designed to protect the integrity of the wellbore and enhance production is pumped under high pressure into the formation to create fractures. The fractures are kept open by sand or “proppant”, which provides pathways to allow the natural gas to flow into the wellbore. As hydraulic fracturing fluids are injected into intact gas bearing shales, thousands of micro-seismicity events (approx -3.0 to 0.5 ML ) are created as the rock is fractured. These events are caused by micro shear movement and tensile fractures and by the re-opening of existing fractures and faults. The micro-seismicity created by fracture development is often monitored during hydraulic fracturing by a borehole or surface seismograph array to assess the effectiveness of the fracture program. Special equipment Analysis is used as these events are far below the detection threshold of the seismographic monitoring networks in place for earthquake detection. For the purposes of this report, the focus is on seismicity that would not normally occur when performing hydraulic fracture completions (such as seismicity resulting from fault movement). Larger magnitude events may occur when fluid injected during hydraulic fracturing triggers movement along pre-existing stressed faults. Only one event studied within this investigation was reported felt at surface. NRCan’s report on the May 19, 2011, 3.8 ML event indicates that the event was “felt by workers in (the) bush”. No injuries or damage to surface structures were reported for this or any of the events studied within this investigation. Twenty-seven of the recorded Etsho events lie within a 10 km radius circle (Figure 5). Within this same circle are seven multi-lateral drilling pads. Five of these pads were conducting hydraulic fracturing operations when events occurred.
  • 15. Figure 5: NRCan event locations, event sequence and drilling pad locations, shown within 10km radius red shaded circle. #* #* #* #* #* #* #* #* #* #* #* #* #* #* #* #* #*#* #* #* #*#* #* #* #* #* #* #* #* #* ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " " "" " """" """ " " " " " " " " " " " """ " "" """ " " " """"""" " " " " "" " """"""""""""""" """""""""""""" " " """""" "" " """"""" """ " " " " """""" " " " " " " " """""""" " " " """"""""" "" "" " " """"" """""""" """""""" """ " """"" " " " " " " " " " " " "" """""""" " " "" " " " """"""""""""""" " " " " " " " " " " " " " " " " " " " """"""""""""""""""" Horn River Basin 094P04 094O02 094O10 094O09 094P12 094O01 094O07 094O08 094P05 4/8/2009 4/9/2009 6/11/2010 8/3/2010 8/22/2010 9/30/2010 9/30/2010 10/3/2010 10/4/2010 10/5/2010 10/5/2010 10/9/2010 10/12/2010 10/12/2010 10/12/2010 3/4/20114/7/2011 4/28/20114/30/2011 5/3/2011 5/10/2011 5/19/2011 5/19/2011 5/20/2011 5/29/2011 6/26/2011 7/1/2011 7/7/2011 7/14/2011 C- 024-I B- 025-H D- 063-H C- 039-J B-B077-H A- 097-J A-A080-L A- 069-L D-N070-K A- 076-F A- 016-K C- 100-G A-A020-J C- 089-G C- 015-G C-D055-B D- 071-G D- 068-H A- 077-I A- 027-I D-A054-A D- 052-H A- 012-H A- 036-A B- 012-G B- 045-I A- 041-A A- 051-J D-A052-L A-A076-F A- 100-B D-C087-G D-A087-G C- 055-B C-A055-B B- 086-A B- 031-A A- 089-D B- 060-L A- 050-C A-C009-K B- 008-K A- 006-C A- 006-J D- 099-I A- 027-I C- 056-E B-C063-K D-A090-G A- 026-G C-B055-B C-C055-B C-C001-J B- 066-I A- 077-L C- 062-H B- 002-H B-C008-K A- 051-A D- 051-A B- 098-F C- 067-K D- 066-F A-A100-B B- 090-J B-D100-G D-B087-G B- 016-IC-A016-I C- 071-A B- 060-D C- 035-D A-A051-A A- 059-D D- 069-L D-I052-L D-H001-D C-B063-K D- 090-G D- 077-J D-E087-G C-E055-B D- 056-J D- 085-G B- 085-A A- 035-E B- 048-A B- 086-K B- 072-K A-A097-J B- 063-B D-K052-L D-E052-L C- 099-K B-A076-K C-D063-K D-J070-J A- 020-J D-B077-J A- 045-G B-H018-I B- 077-H A-E016-I D- 094-A C- 093-A D- 068-D C- 007-D D-A063-H A-A050-C B-B008-K C- 094-I B- 052-I C-A034-L C-D034-L C-I034-L D-C052-L D-G001-D D-K070-K D-H070-K B- 076-K B-E063-K B-A063-K B- 061-K D-E070-J D-D070-J A-F020-J A-D020-J A- 029-B C- 018-B D- 087-G C-D001-J B-D018-I B-C018-I B-K077-H B-G077-H C- 026-A D-O037-H D- 054-A D-A094-A B- 093-A D- 039-E D- 079-D B- 091-B C- 002-H A-A009-K C- 057-D C-B034-L C-G034-L A- 083- D D-O001-D D-K001-D D-E001-D D-M070-K D-D070-K A- 008-C A-B077-K D- 046-K B-A090-J D-F070-J B- 100-G A-H020-J B- 018-B D-G087-G B- 084-B C- 001-J C-A001-J C-E001-J B- 018-I B-E077-H B-N077-H B-H077-H D-F037-H D-G037-H D-J037-H D-K037-H D- 025-H C- 016-I A-C016-I A- 031-H C- 021-A D- 020-D D- 028-E A- 027-E C-A007-D D- 037-D 122°0'0"W 122°0'0"W 122°15'0"W 122°15'0"W 122°30'0"W 122°30'0"W 59°30'0"N 59°30'0"N 59°15'0"N 59°15'0"N 0 2 4 61 Kilometers Etsho Activity 20 km Buffer #* Earthquakes ! Major Cities " Well Surface Hole ( Well Bottom Hole Well Directional Survey Earthquakes NEBC 2009 - 2012 1:200,000 ! ! ! ! Kelowna Victoria Fort Nelson Fort St. John Etsho Area At Tattoo all seven of the recorded events can be encompassed within a 10 km radius circle that encloses two multi-well shale gas drilling pads. One pad at Tattoo had ongoing hydraulic fracturing operations when the seismicity occurred (Figure 6). 15Investigation of Observed Seismicity in the Horn River Basin
  • 16. Investigation of Observed Seismicity in the Horn River Basin16 Figure 6:Tattoo area NRCan event epicentres and Multi-well Pads, shown within“20km buffer”, 10km radius red circle. #* #* #* #* #* #* #* #* #* #* #* #* #* #* #* #*#* #* #* #* #* # ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( " " " " " " " " " " " " " " " " " " " " " " "" " " " " " " " " " " " " " " " " " " " "" " " " " " " " " " " " " " " " " " " " " " " " " "" "" " " " "" "" " " " " " """ " " " " "" " " " " " " " " " " " " " "" " " " " """" " " " "" " " "" " " " " " " " " " """"""""" " " " " Northwest Territories 094O11 094O16 094O14 094O10 094O09 094O15 9/30/2010 9/30/2010 10/4/2010 10/5/2010 10/9/2010 10/12/2010 10/12/201010/12/20105/29/2011 6/26/2011 7/1/2011 12/8/2011 12/10/2011 12/11/2011 12/11/2011 12/12/2011 12/12/2011 12/13/2011 A- 078-L B- 095-E D-A028-F B-A018-G B-A055-B D- 063-H D- 030-D C- 092-E A-G098-F A- 086-BA-A086-B D- 061-A A- 076-F B- 025-L D- 073-L D- 077-K B- 055-B A- 041-A B- 066-D D- 012-L A-B098-F C-D068-B A-B086-B B- 091-G B- 058-H C- 060-D A-A076-F B- 018-G C- 007-J D- 097-B C- 015-L C-B092-E A- 040-K A-A098-F A- 098-F C- 060-G B-E070-B B- 077-B A-C086-B C- 075-F D- 058-L C- 077-L C- 066-E A- 025-L A- 045-E D-H050-A D-D050-A D-B050-A C- 062-H B- 002-H B-D070-B C-A068-B C-E068-B C- 081-G D- 013-L D- 066-F C- 054-D C- 053-C C- 067-L B- 047-L A- 035-L A- 054-L C- 057-C B- 057-C D- 028-F C-A007-J A- 069-D B-A022-L C- 001-L A-C001-L A-C098-F D-B071-A D-H071-A D-I071-A D- 070-F B- 096-E C-A057-C D- 069-C D-B028-F B- 048-A B- 022-L A-B001-L C- 030-K C- 020-K C- 049-E B- 059-E C- 099-D A- 027-L C- 035-E A- 002-D B- 066-B D-A063-H C- 012-L B- 021-L A- 001-L C- 081-D A- 056-F B- 070-B A- 033-L A- 028-D C- 066-L D- 076-E B- 044-L C- 063-L C- 042-C D-C050-A D-I050-A B- 091-B D-J050-A C- 002-H C- 029-D B- 057-L C- 083-L C-A092-E A- 021-L A-A001-L A-D001-L D- 028-J C- 027-J C-C068-B C-B068-B D-A068-B B- 063-B C- 056-A D- 071-A D-A071-A D-D071-A C- 057-D A- 083-D BovieLakeFault TroutLake FaultZone 122°15'0"W 122°30'0"W 122°30'0"W 122°45'0"W 122°45'0"W 123°0'0"W 60°0'0"N 59°45'0"N 59°45'0"N Tattoo Field 0 2 4 61 Kilometers Tattoo Activity 20 km Buffer #* Earthquakes ! Major Cities " Well Surface Hole ( Well Bottom Hole Well Directional Survey Earthquakes NEBC 2009 - 2012 1:200,000 ! ! ! ! Kelowna Victoria Fort Nelson Fort St. John Tattoo Area Horn River Basin SeismicityEventLocationsandDepth–ProximitytoHydraulic Fracturing A number of events, ranging from magnitude -0.8 to 3.0 ML , were recorded by the Etsho dense array during hydraulic fracturing. Of these, 216 are interpreted to be related to fault movement (197 events, magnitude 1.0 – 2.0ML and 19 events magnitude 2.0-3.0 ML ). Operator provided b-value analysis indicated that magnitudes from 0.5ML to 1.0ML indicate the transition from fracture driven seismicity to seismicity driven by fault movement. For the dense array’s operational date range, June 23 to August 14, the two northeast B.C. stations in the CNSN recorded four events (mag. 2.5 to 3.1 ML ). Figure 7 shows the horizontal wellbores for the d-1-D drilling pad, volumes injected at each hydraulic fracturing stage and the magnitude >1.0ML events occurring from June 23 to August 14, 2011.
  • 17. 17Investigation of Observed Seismicity in the Horn River Basin Figure 7: Diagram showing d-1-D wellbores and events >1.0.Wellbores are black lines and stages with relative injection volumes are thickened blue sections. The horizontal and vertical locations of several events at Etsho detected by NRCan were relocated by the operator using data obtained from the dense array. The results of this work placed event hypocentres within 200 m, vertically and horizontally, of hydraulic fracturing stages. In cases where events could be confidently linked to hydraulic fracturing stages, events occurred during the event stage or prior to the following stage beginning. Associated faults, identified on microseismic plots as linear swarms, could be seen intersecting stage locations. True vertical depths (TVD) of hydraulic fracturing completions at the Etsho d-1-D pad range from approximately 2,650 to 2,889 metres TVD. Of the 69 magnitude 1.5 to 3.0 ML seismic events recorded by the dense array and linked to this pad, all fall within the targeted formations. Sixty-six of these events occur between 2,800 and 2,870 metres. At Kiwigana, numerous micro-seismicity events, ranging from -1.7 to 0.5 ML , were detected between Oct. 25, 2011 and Jan. 27, 2012 by the operator deployed dense array. These micro-seismicity events resulted from tensile failure and shear movement during the normal process of hydraulic fracturing to develop the reservoir. An additional 18 events ranging from 1.0 to 1.86 ML were detected and are interpreted to be the result of injection fluids triggering movement along pre-existing faults. Figure 8 is a cumulative microseismic plot showing a vertical profile of the Kiwigana wellbores at the c-15-D pad. Coloured dots indicating micro-seismicity show that hydraulic fracturing operations are successfully contained to the Horn River shale target horizons and that the overlying Ft. Simpson shale provides an effective barrier to vertical fracture growth. A fault is suggested near the centre of the wellbores by the downward trending collection of microseismic points.
  • 18. Investigation of Observed Seismicity in the Horn River Basin18 Figure 8: Cumulative microseismic plot for Kiwigana, coloured dots indicate contained micro-seismicity events caused by tensile and shear failure of intact shale.Trail of coloured dots suggest reopening or movement of pre-existing fault. Generalized stratigraphic column to right.
  • 19. 19Investigation of Observed Seismicity in the Horn River Basin HydraulicFracturingTimingvs.SeismicityEventTiming Hydraulic fracturing dates and times were compared to seismicity event times (Figure 9). At Etsho and Tattoo, all 38 NRCan reported events occurred either during a hydraulic fracturing stage or sometime after one stage ended and another began. No events were recorded before hydraulic fracturing operations began or after the last hydraulic fracturing operations ended. Figure 9:Timing of NRCan reported Events (black dots) vs. Magnitude.Timing of hydraulic fracturing operations (coloured columns). c-68-B/94-O-15 c-34-L/94-O-8 b-76-K/94-O-8 c-1-J/94-O-8 c-55-B/94-O-9 d-87-G/94-O-8 4 3 2 1 1.5 0.5 2.5 3.5 2008 2009 2010 2011 Jan Ootla 70-J 76-K NRCan-ReportedEarthquakeEvents(RichterScale) Jan Jan JanFeb Feb Feb FebMar Mar Mar MarApr Apr Apr AprMay May May MaySep Sep Sep SepJun Jun Jun JunJul Jul Jul JulOct Oct Oct OctAug Aug Aug AugNov Nov Nov NovDec Dec Dec Dec d-70-J/94-O-8 Seismic Event Correlations of Event Times to Horn River Pad Operations d-70-K/94-O-8 d-52-L/94-O-8 b-18-I/94-O-8 b-63-K/94-O-8 d-1-D/94-O-9
  • 20. Investigation of Observed Seismicity in the Horn River Basin20 Hydraulic fracturing and NRCan event timing were compared at 15 Etsho and Tattoo drilling pad sites. Nine pads had ongoing hydraulic fracturing operations when the NRCan events occurred (Figure 9). The other multi-well drilling pads in the Etsho area could not be linked to the NRCan events by location or timing. Eighteen magnitude 1.9 to 3.0 ML events were selected from dense array microseismic plots. These events were selected because they were located adjacent to hydraulic fracturing stages and could be connected to a single stage fluid injection with some confidence. Evidence strongly suggests that all events were triggered by fluid injection at adjacent stages. Figure 10 shows the time lapse from the beginning of the selected stage to the seismicity event time. One stage was linked to 3 events, four stages to 2 events each and 7 stages had one event. On average, stage start time to stop time was 5 ½ hours. Eight events occurred during stage operations. Seventeen events occurred within 17 ½ hours and all events had occurred within 24 hours of assigned stage start times. All stages along the d-G1-D (southwestern most) wellbore had 10,000 m3 total hydraulic fracturing fluid placed. For these stages, two injections of 5,000 m3 were placed at the same stage interval separated by about one hour. Eight of the events connected to the 11 stages graphed with 10,000 m3 total fluid placed, occurred prior to the second injection of 5,000 m3 . Figure 10: Timing of seismicity events, resulting from fluid injection at selected hydraulic fracturing stages. Green dots designate events linked to stages with 10,000 m3 total‘Fracturing Fluid Placed’ (two injections of 5000 m3 separated by one hour). Red dots are events linked to stages with 5,000 m3 total‘Fracturing Fluid Placed’. Horn River Pad Operations d-1-D Pad Time Lapse from Start of Hydraulic Fracturing to Associated Seismic Event 0 60 240 420 600 780 960 1140 1320120 300 480 660 840 1020 1200 1380180 360 540 720 900 1080 1260 1440 1.0 1.5 0.5 2.5 3.5 2.0 3.0 4.0 Richter Scale Magnitude Minutes (12 hrs) (24 hrs) Start of Hydraulic Fracturing Operation 330 Mins (5.5 hrs): Average Duration of Hydraulic Fracturing Stage Minutes to Seismic Events Mag 2.14 145 mins Mag 2.01 9 mins Mag 2.66 146 mins Mag 2.55 49 mins Mag 2.70 108 mins Mag 1.97 110 mins Mag 2.29 179 mins Mag 2.50 333 mins Mag 2.09 273 mins Mag 2.54 660 mins Mag 2.17 681 mins Mag 2.02 409 mins Mag 3.04 962 mins Mag 1.94 1043 mins Mag 2.42 751 mins Mag 2.02 877 mins Mag 1.91 707 mins Mag 2.60 1408 mins 10,000 m3 5,000 m3 Frac Fluid Placed
  • 21. 21Investigation of Observed Seismicity in the Horn River Basin Proximity to pre-existing faults, injection volumes, breakdown pressures and hydraulic fracture pump rates were examined as possible controls on seismicity. Dense array data was used by an operator to compare pumping rates and fault proximity to seismicity frequency and magnitude at the d-1-D pad. The operator study concluded that seismicity was greatest near pre-existing faults and subsided away from the mapped fault fairway. As hydraulic fracturing proceeded from toe to heel along horizontal wellbores, seismicity magnitude increased as wellbore stages encountered micro-seismically visible faults. Higher magnitude events, caused by fault movement, declined or fell off completely as completion stages moved away from faulting. According to the operator study, as hydraulic fracturing stages continued along the horizontal legs and pump power was reduced, events became less frequent. This indicates either no faults were being intersected or additional faults encountered were not critically stressed or injection was insufficient to trigger fault movement. The operator analysis concluded that proximity to faulting appeared to have a greater effect on seismicity than pump rates. Faulting was identified on microseismic plots and 3-D seismic supported fault mapping provided by operators. In only one case did a linear seismicity swarm clearly Controls on Seismicity coincide with a 3-D seismic mapped fault. A much larger linear swarm of events mapped at d-1-D, interpreted to be occurring along a single reactivated fault, had no supporting 3-D mapped faulting. Microseismic plots were not available for the May 19, 2011 3.8 ML event. The maximum event verified by dense array and visible on microseismic plot was the July 7, 2011, 3.1 ML (NRCan) event located within the large linear swarm at d-1-D (figure 7). At Etsho, an operator analysis showed a slight correlation between hydraulic fracture pumping rates and event magnitude and frequency. Pump rates were reduced from16 m3 /min to 13 m3 /min on July 19, 2011. In this operator analysis, after the July 19 pump rate reduction, the frequency of higher magnitude events decreased. Figure 11 shows the results of a Commission analysis. Event magnitudes, collected from the dense array, from June 23 to July 31 are compared to pump rates, breakdown pressures and injection volumes for the corresponding period. Magnitudes are averages of all events occurring on the date. Pump rates, pressures and volumes were averaged by date for all the wells on the d-1-D/94-O-8 pad. The magnitude drop around July 9 (Figure 11) indicates a decline in magnitude as hydraulic fracturing stages moved away from pre-existing faults that became active as a result of fluid injection. Although pump rates were below average from July 15–20, no corresponding decline in magnitudes is seen in this analysis. Some periods of direct relationship can be seen between breakdown pressures and magnitudes. As stated previously, magnitudes decline around July 9 as completions move away from the active faulted interval. Magnitudes after July 9 suggest few events past that date are related to fault movement. Within the active faulted zone (June 23 to July 9) magnitudes show some correlation to breakdown pressures.
  • 22. Investigation of Observed Seismicity in the Horn River Basin22 Figure 11: Change in average magnitude with changes in daily fracture volume, pump rate and breakdown pressure over time. Frac fluid placed, pump rates and breakdown pressures are daily averages taken from d-1-D pad completions report. Magnitudes are also daily averages. Hydraulic fracturing pump rates at Kiwigana were maintained at slightly below 13 m3 /min. Micro-seismicity frequency and magnitude were fairly consistent during the Oct. 2011 to Jan. 2012 hydraulic fracturing operations, with magnitudes ranging from -1.7 to 1.9 ML . Eighteen events were above 1.0 ML for a period from Nov. 6-10, 2011 suggesting minor fault movement. A review of microseismic plots for this time period shows that as the initial hydraulic fracturing stages were completed in the c-A15-D wellbore, a trailing swarm of microseismic points, indicating fault slippage, extended below and to the southwest of the completion interval and stage location. Here again, fluid injection at a fracturing stage while proximal to a critically-stressed fault appears to trigger seismicity. At Kiwigana, a consistent, relatively low pump rate may have been effective in mitigating seismicity magnitude and frequency. Only 18 events were interpreted to be the result of fault movement. None of these very low magnitude events were detected by NRCan or felt at surface. 2011 Horn River Pad Operations d-1-D Pad Breakdown Pressure versus Average Magnitude June July 32 48 46 42 44 50 40 36 38 34 23 5 17 2924 6 18 3025 7 19 3126 8 2027 9 211 13 2528 10 2229 11 232 14 2630 12 243 15 274 16 28 Breakdown Pressure (MPa) Average Magnitude (ML) 0.8 -0.4 -0.2 0.0 0.2 -0.6 0.4 1.0 0.6 Pump Rate versus Average Magnitude June July 0 16 14 10 12 18 8 4 6 2 23 5 17 2924 6 18 3025 7 19 3126 8 2027 9 211 13 2528 10 2229 11 232 14 2630 12 243 15 274 16 28 Pump Rate (m3 /min) Average Magnitude (ML) 0.8 -0.4 -0.2 0.0 0.2 -0.6 0.4 1.0 0.6 Frac Fluid Placed versus Average Magnitude June July 3250 5250 5000 4500 4750 5500 4250 3750 4000 3500 23 5 17 2924 6 18 3025 7 19 3126 8 2027 9 211 13 2528 10 2229 11 232 14 2630 12 243 15 274 16 28 Frac Fluid Placed (m3 ) Average Magnitude (ML) 0.8 -0.4 -0.2 0.0 0.2 -0.6 0.4 1.0 0.6
  • 23. 23Investigation of Observed Seismicity in the Horn River Basin The Davis and Frohlich induced seismicity criteria (Davis and Frohlich 1993) is a generally accepted methodology for the identification of induced seismicity. These criteria strongly suggest the Horn River Basin seismicity was induced by hydraulic fracturing. Davis and Frohlich Criteria – related to Horn River Basin 1. Timing a. Are these events the first known earthquakes of this character in the region? Probably, only some mag >2.5ML events would have been detected in the Horn River Basin back to 1999. Prior to 1999, magnitude 4.0ML events would have been detected as far back as the 1960’s. No events were recorded by NRCan in the Horn River Basin prior to April 2009 b. Did the events only begin after hydraulic fracturing had commenced? Yes, all the Horn River Basin events, recorded by both NRCan and the operator deployed dense array, began after hydraulic fracturing commenced. c. Is there a clear correlation between hydraulic fracturing and seismicity? Yes, all the seismic events in Horn River Basin occurred during or between hydraulic fracturing stages. Davis and Frohlich Criteria 2. Location a. Are epicenters within five kilometres of wells? Yes, all epicentres occurred within five kilometres of hydraulic fracturing operations. b. Do some earthquakes occur at or near hydraulic fracturing depths? Yes, the dense array report shows seismicity occurring within 300 metres of hydraulic fracturing stages. c. Do epicenters appear spatially related to the production region? Yes, all the NRCan reported events were located within five kilometres of hydraulic fracturing operations in the Horn River Basin. Dense array hypocentres locate the events within 1 km. 3. Fluid pressures, etc. a. Did hydraulic fracturing cause a significant change in fluid pressures? Yes, hydraulic fracturing must increase localized pressures to breakdown pressure in order to fracture the reservoir rock. This pressure is greater than original formation pore pressure. b. Did seismicity begin only after the fluid pressures had increased significantly? Yes, the events occurred after hydraulic fracturing commenced and fluid pressures had increased significantly. c. Is the observed seismicity explainable in terms of current models relating hydraulic fracturing to fault activity? Yes, current induced seismicity models relate increased pore pressure from fluid injection to overcoming friction along a fault resulting in fault slippage. Horizontal portions of wellbores at Etsho are roughly 2500 to 3000 metres long. Five of the six operators covered by the Information Request reported no wellbore integrity issues in 91 of the 93 wellbores at Etsho. Two instances of wellbore deformation along horizontal sections were reported by one operator. These occurred over a short interval beginning at 3,011 m KB (Kelly Bushing) in the d-A1-D/94-O-9 well. In this instance, casing deformation was minor and did not hinder completion operations. At d-1-D/94-O-9, the deformation was encountered at 4,245 m KB and the casing distortion blocked completion efforts at 4,288 m KB. Neither incident posed any risk with respect to safety, containment or fluid migration. The operator reported that the deformation occurred in the horizontal section of the wellbores only and no wellbore issues were reported in the vertical sections of any wells. This deformation was detected in July 2011. Hydraulic fracturing stages for the two affected wellbore measured depths were completed from June 16 to July 3, 2011. All geophysical logs, containing wellbore caliper and image data, were run in Sept. and Oct. 2010, prior to the deformation occurring. The bit (117.5mm) used to drill out the stage packers is very close to the inside diameter of the casing (121.0mm) and would have detected any vertical wellbore casing distortion. As a result of not encountering any further distortion, no subsequent casing or cement evaluation tools were run. Wellbore Integrity
  • 24. Investigation of Observed Seismicity in the Horn River Basin24 All Etsho operators conducted two and three dimensional seismic surveys and interpreted faulting before conducting hydraulic fracturing operations. Fault mapping at Etsho shows abundant faulting. Interpretations vary but it appears most of this faulting (including the larger, regional faults in this grouping) is deep seated and concentrated in a north-south trending fault fairway centered at Etsho. Minor, secondary faulting is evident, generally trending northwest to southeast, at approximately 45 degrees. From the data reviewed, faulting appears to be confined below the lower Fort Simpson shale extending into the basement (Precambrian) or within the shallower Debolt Formation. No faulting was seen to extend through the Fort Simpson Formation and no evidence was found that Middle Devonian aged faulting, in this area, could provide a conduit for fluids to zones above the Fort Simpson shale. Faults were also interpreted from available microseismic plots. In the case of the dense array at Etsho, daily microseismic plots (June 16 – July 31, 2011) that showed high magnitude events were submitted for the investigation. Along with higher magnitude seismicity, dates and the stages hydraulically fractured for that date were highlighted. Event dates could be compared to the plots and fault mapping. In all cases examined, faulting could be seen on the plots as linear swarms or a smaller bundle of events with a large signature event represented by a large dot. Faults can also be seen as long, trailing legs of dots on microseismic vertical profiles (Figure 12). In this case, hydraulic fracturing fluids or a pressure front appear to have migrated along the fault creating micro- seismicity events that reach the underlying Keg River formation. Pre-Existing Faults Figure 12: Micro-seismicity events (coloured circles) and hydraulic fracture stages (green ellipses) along horizontal wellbore legs.
  • 25. 1. The seismicity observed and reported by NRCan in the Horn River Basin between April 2009 and December 2011 was induced by fault movement resulting from injection of fluids during hydraulic fracturing. 2. No injuries or property damage were reported as a result of the induced seismicity. Only one event was reported by NRCan to have been felt at the ground surface. 3. The fractures developed during the hydraulic fracturing operations studied within the investigation were effectively confined to the target Horn River shales by the overlying Ft. Simpson shales. No effects on shallow aquifers or the environment were identified. 4. The magnitude and frequency of the induced seismicity investigated by the Commission may be influenced by numerous factors including pump rate, breakdown pressure and proximity to pre-existing faults. Findings 5. No casing deformation was reported in the vertical portion of wellbores and no reservoir containment issues were identified. Minor casing deformation within the horizontal well portion of target shale formations occurred in 2 instances. The cause of the casing deformation could not be conclusively linked to the seismicity. 6. Fault mapping provided by operators shows abundant sub parallel north-south trending faulting through the Etsho and Tattoo areas. These faults are generally deep seated and do not show displacement above the Ft. Simpson shale. The Ft. Simpson shale is considered to be a ductile fracture barrier. Fault reactivation in this structural setting is not considered a threat to shallow overlying aquifers. 7. Seismograph station additions are needed to the CNSN to improve monitoring for induced seismicity in northeast British Columbia. 25Investigation of Observed Seismicity in the Horn River Basin
  • 26. Investigation of Observed Seismicity in the Horn River Basin26 1.ImprovetheaccuracyoftheCanadianNationalSeismograph NetworkinnortheastB.C. During the investigation it became evident that the existing coverage of the CNSN, operated by NRCan for northeast B.C. is adequate for large conventional earthquake detection but could not reliably provide the spatial accuracy necessary to positively identify smaller seismic events associated with induced seismicity. The current grid did not detect 15 magnitude 2.0 to 3.0 ML events which were detected by the more accurate dense array temporarily installed at Etsho. The Commission has been working with NRCan and the Alberta Geological Survey to determine what enhancements to the existing detection grid are needed to provide accurate and timely identification of induced seismicity. Action: Geoscience BC has organized funding for a five year project to install and operate six additional seismograph stations for the CNSN. NRCan has completed site surveys and installation is scheduled for late 2012. The enhanced grid will reliably identify induced seismicity, providing detection sensitivities below 2.0 ML and surface location accuracy to within one kilometre. Recommendations 2.Performgeologicalandseismicassessmentstoidentifypre- existingfaulting. While several faults were believed to have been intersected by wellbores at Etsho, only a few of these faults slipped resulting in seismicity. In one case a mapped fault coincided with a microseismic plot event swarm. In other areas, seismicity occurred where faults had not been mapped. It currently cannot be determined which intersected fault will move or what injection pressure or volume will trigger the event. Operators do identify as many pre-existing faults as practical and can tailor their hydraulic fracture programs to include enhanced monitoring for seismicity when completing near these faults Action: Operators should review geological and seismic data to identify pre-existing faulting. If induced seismicity is detected, the active fault could be located and avoided in subsequent wellbores. Additional mitigation procedures, such as bypassing stages adjacent to a known active fault might also be considered. Monitoring for events will be done by the Commission under Recommendation 3. 3.Establishinducedseismicitymonitoringandreporting ProceduresandRequirements. A notification and consultation procedure provides a means for the Commission to respond to induced seismicity in northeast B.C. If seismicity is detected on the CNSN or an operator deployed dense array, the Commission would contact the operator to investigate the occurrences and determine appropriate mitigation options when required. Action: Each case will require a unique response. Incidents will be evaluated on the basis of event frequency, magnitude, ground motion, depth and proximity to populated areas. In the case of the Horn River Basin area, the Commission will commence consultations regarding additional monitoring requirements or mitigation as soon as induced seismicity is detected. Specific to the Horn River Basin, with the additions to the CNSN, induced events should be reliably and consistently detected and reported at magnitude 2.0 ML . Mitigation discussions with the operator will begin immediately. Mitigation steps taken will vary dependent on the risk posed by the events and may include enhanced data recovery for research purposes. An order to suspend hydraulic fracturing specific to the well under completion could be issued dependent on an evaluation of the previously stated criteria of event frequency, magnitude, ground motion, depth and proximity to populated areas. Operators will immediately suspend hydraulic fracturing operations for a well upon detection of a 4.0 ML or greater event. 4.StationgroundmotionsensorsnearselectedNEBC communitiestoquantifyriskfromgroundmotion. Along with location and depth, it is important to know how much the ground actually moved at a given location during a seismic event. Ground motion sensors record ground acceleration and enable a correlation between magnitude
  • 27. 27Investigation of Observed Seismicity in the Horn River Basin and ground acceleration. This has implications for human safety and infrastructure integrity. Action: NRCan experts will be consulted to determine equipment selection, location, installation and operation of ground motion sensor stations. 5.TheCommissionwillstudythedeploymentofaportable denseseismographarraytoselectedlocationswhereinduced seismicityisanticipatedorhasoccurred. A dense array, separate from the regional grid, is necessary to determine event depth, a key to diagnosing induced seismicity. Depth is required to fully understand the range of fault movement and risk to shallow aquifers. Focal mechanism determination, improved location resolution and lower magnitude detection are also possible benefits of a dense array. They can be designed to be quickly deployable, placed on the ground, and may require as few as five seismographs. Action: Two operators have deployed three dense arrays in the Horn River Basin and an additional research dense array is being considered by NRCan for the Basin. The Commission will seek funding for a portable dense array to be deployed as needed for induced seismicity research and data collection. 6.Requirethesubmissionofmicro-seismicreportstomonitor hydraulicfracturingforcontainmentofmicrofracturingandto identifyexistingfaults. Microseismic data can identify geological features such as faults where there may be increased risk of inducing seismicity beyond magnitude 2.0 ML . In addition, microseismic plots can verify that hydraulic fracturing is confined to the target zone by outlining both the vertical and lateral extent of the fracturing. Action: The Commission will develop requirements for submission of information gathered from microseismic monitoring during hydraulic fracturing. Data gathered will be limited to that which is necessary to show fracture containment and faulting. The format shall be determined in consultation with stakeholders including other regulators outside of British Columbia. Consideration of the proprietary nature of microseismic data must be included in the development of submission requirements. 7.Studytherelationshipbetweenhydraulicfracturing parametersandseismicity. At Etsho and Kiwigana magnitudes may have declined as pump rates were reduced or held low. This investigation found weak correlations between pump rates and magnitude and breakdown pressure and magnitude. The historical response to induced seismicity from fluid injection has been to either stop operations or reduce injection rates. Seismicity frequency at the Rangely oilfield in Colorado (Gibbs et al, 1972) directly corresponded to the amount of water injected per year. Action: The Commission is continuing its analysis of hydraulic fracturing data to attempt to find correlations between hydraulic fracturing parameters and event magnitude. Reducing pump rates or injection volumes will be considered if induced seismicity is detected beyond the criteria set out under recommendation three.
  • 28. Investigation of Observed Seismicity in the Horn River Basin28 Horn River Basin seismicity events, from 2009 to late 2011, were caused by fluid injection during hydraulic fracturing. All events occurred during or between hydraulic fracturing stage operations. Dense array data accurately placed the depth and location of events at or near hydraulic fracturing stages. Only one event was reported as “felt” and no events were felt beyond 10 km of the epicentres. Faulting transecting horizontal wellbores can be identified on microseismic plots. Some events greater than 2.0 ML were located at the intersection of faults and wellbores when adjacent hydraulic fracturing stages were being completed. In other circumstances, faults intersected wellbores yet no anomalous events were detected. Fault movement is dependent on numerous factors such as in- situ stress and there is no reliable method to identify which faults will slip or under what conditions. Further research is needed to determine if induced seismicity from hydraulic fracturing can be controlled by either altering hydraulic fracturing parameters or by fault characterization and avoidance. The current coverage of the CNSN was designed as part of a national large earthquake preparedness system and is inadequate for the reliable detection of induced seismicity. Only four of the 19 (2.0 to 3.0 ML ) events detected by the dense array at Etsho between June 23 and Aug. 15, 2011 were detected by the current regional grid. Recommended Conclusion improvements to the CNSN will improve location resolution to within one km and magnitude detection to <2.0 ML . Site surveys for the additional seismograph stations being added to the CNSN have been completed. Installation of the new stations is tentatively scheduled for late 2012. Dense arrays will be deployed where appropriate to determine event depth and precise location. None of the events under investigation resulted in any injury or property damage and only 1 event was recorded by NRCan as having been “felt” at the surface. The recommended ground motion sensors will accurately record any ground acceleration from future events. This enables a correlation between magnitude and any ground motion and eliminates the need to rely on ‘felt’ reports to gauge possible effects at surface. Recommended improvements to the CNSN and implementation of a notification and consultation procedure will provide the necessary early detection and mitigation action as well as for additional research on mitigation methods. It is essential to take pre-emptive steps to ensure future events are detected and the regulatory framework adequately provides for the monitoring, reporting and mitigation of all seismicity related to hydraulic fracturing thereby ensuring the continued safe and environmentally responsible development of shale gas within British Columbia.
  • 29. Davis, S.D. and Frohlich, C., 1993. Did (or will) fluid injection cause earthquakes? – Criteria for a Rational Assessment, Seismol. Res. Lett. 64(3-4), 207-224 De Pater, C.J. and Baisch, S., 2011 Geomechanical Study of Bowland Shale Seismicity, Synthesis Report commissioned by Cuadrilla Resources Ltd. Gibbs, J., Healy, J., Raleigh, C., Coakley, J. 1972 Earthquakes in the Oil Field at Rangely, Colorado, U.S. Geological Survey, Open File Report 72-130 Holland, Austin, 2011, “Examination of Possibly Induced Seismicity from Hydraulic Fracturing in the Eola Field, Garvin County, Oklahoma”, Oklahoma Geological Survey Open File Report OF1, 2011. Horner, R.B., Barclay, J.E. and MacRae, J.M. ,1994, Earthquakes and Hydrocarbon Production in the Fort St. John Area of Northeastern British Columbia, Canadian Journal of Exploration Geophysics, Vol. 30, No. 1, (June 1994), P. 38-50 References MacLean, B.C., Morrow, D.W., 2004, Bulletin of Canadian Petroleum Geology, Vol. 52, No. 4 (December 2004, P. 302-324 McPhail, S., Walsh, W., Lee, C., Monahan, P.A., 2008, British Columbia Energy and Mines, Open File, Report # 2008-1 Nicholson, C. and R.L. Wesson, 1990, Earthquake Hazard Associated With Deep Well Injection – A Report to the U.S. Environmental Protection Agency, U.S. Geol. Surv. Bull, 1951. Hayes, B.J., 2010, HORN RIVER BASIN Subsurface Aquifer Characterication Project, Presentation to Unconventional Gas Technical Forum, Geoscience BC project 29Investigation of Observed Seismicity in the Horn River Basin