This document discusses MOS transistor theory and provides examples for calculating threshold voltage (VT).
[1] It describes the basic structure of an n-channel MOSFET and the energy band diagrams for different biasing conditions, including accumulation, depletion, and inversion.
[2] Threshold voltage depends on factors like gate material, oxide thickness, channel doping, and interface charges. An example calculates VT0 = 0.38V for an nMOS transistor with given parameters.
[3] Body effect is explained, where threshold voltage increases with reverse substrate bias. An example plots VT as a function of VSB, using the body effect coefficient γ = 0.85V1/2 calculated for the
1. 1
EE 560
MOS TRANSISTOR THEORY
PART 1
Kenneth R. Laker, University of Pennsylvania
2. 2
TWO TERMINAL MOS STRUCTURE
VG (GATE VOLTAGE)
GATE
OXIDE
SiO2
SUBSTRATE
tox
p-type doped Si
(NA = 1015 to 1016 cm-3)
VB (SUBSTRATE VOLTAGE)
EQUILIBRIUM: n p = ni2 (ni ≈ 1.45 x 1010 cm-3)
Let SUBSTRATE be uniformy doped @ NA
n i2
np 0 ≈ and pp0 = NA
Kenneth R. Laker, University of Pennsylvania
NA (BULK concentrations)
3. 3
ENERGY BAND DIAGRAM FOR p - TYPE SUBSTRATE
qΧ = electron affinity of Si
E F − Ei
φF = q
Work Function
q ΦS = q χ + (E c − E F )
kT n i (N >> n ) kT N D
φFp = ln A i
φF n = ln (ND >> ni)
q NA q ni
ni = 1.45 x 10-10 cm-3 @ room temp,
k = 1.38 x 10-23 J/oK,
=> kT/q = 26 mV @ room temp
q = 1.6 x 10 C-19
Kenneth R. Laker, University of Pennsylvania
4. 4
ENERGY BAND DIAGRAMS FOR
COMPONENTS OF MOS STRUCTURE
METAL (Al) OXIDE SEMICONDUCTOR (Si)
Eo qΦM = qχox= 0.95 eV
qχm = 4.1 eV Ec qΦS qχSi = 4.15 eV
EFm
Ec
band-gap: Eg = 1.1 eV
band-gap: Ei
Eg = 8 eV qφFp
EFp
Ev
Ev
ΦS > ΦM => p-type Si
ΦM > ΦS => n-type Si
Kenneth R. Laker, University of Pennsylvania
5. VG = 0 5
Equilibrium
Oxide
p-type Si Substrate
VB = 0
Flat-band voltage:
VFB = ΦM - ΦS volts Equilibrium
Built-in potential:
Ec
qΦM qΦS
Ei
qφs qφF
EFm EFp
φs = surface potential Ev
METAL (Al) OXIDE SEMICONDUCTOR (Si)
Kenneth R. Laker, University of Pennsylvania
6. MOS SYSTEM WITH EXTERNAL BIAS 7
Accumulation Region VG < 0
EOX EOX Oxide holes
ACCUMULATED
on the Si surface
p-type Si Substrate
VB = 0
VG = 0
Equilibrium
Oxide
p-type Si Substrate
VB = 0
Kenneth R. Laker, University of Pennsylvania
7. MOS SYSTEM WITH EXTERNAL BIAS 8
VG > 0 (small)
Depletion Region
EOX EOX Oxide
DEPLETION
Region
p-type Si Substrate
VB = 0
Ec
Ei
qVG EFp
EFm Ev
METAL (Al) OXIDE SEMICONDUCTOR (Si)
Kenneth R. Laker, University of Pennsylvania
8. MOS SYSTEM BIASED IN DEPLETION REGION 9
VG > 0 (small)
EOX EOX Oxide
0 x DEPLETION
xd d Region
x p-type Si Substrate
VB = 0
Mobile charge in thin layer
parallel to Si surface
Change in surface potential
to displace dQ
Depletion Region Charge
Kenneth R. Laker, University of Pennsylvania
9. MOS SYSTEM WITH EXTERNAL BIAS 10
VG > 0 (large)
Inversion Region
EOX EOX Oxide
xdm Electrons
attracted to Si
p-type Si Substrate surface
Inversion Condition VB = 0
φs = -φF
2ε Si | 2φF |
x dm = x d φs = − φF = Ec
qN A
Ei
EFp
EFm qVG φs = -φF Ev
METAL (Al) OXIDE SEMICONDUCTOR (Si)
Kenneth R. Laker, University of Pennsylvania
10. G G
11
G G G G
D S D S S DS D S D S
B B B B
B B
n-channel enhancement p-channel enhancement
I DS I DS
IDS IDS
-VTp
-V Tp
V
VGS
0 GS
V
VGS
0 GS
+VTn
+V
Tn
n-channel depletion I DS
G
IDS
I p-channel depletion
I
DS +VTp
+VTp
DS VGS
V
GS
D S 0
B
V
VGS
-VTn
-V 0 GS
Tn Kenneth R. Laker, University of Pennsylvania
11. B S G D 12
W
L
oxide
n+ n+
conducting
channel
substrate depletion layer
or bulk B
p
N-CHANNEL ENHANCEMENT-TYPE MOSFET
nMOS Layout
polysilicon gate
active area
metal
contact area
W
L Kenneth R. Laker, University of Pennsylvania
12. B S G D D G S B 13
p+ p+ n+ n+
n-well
p -substrate
VGS < VTn CUT-OFF REGION
DEPLETION REGION
0 < VGS < VTn VGS VDS
G oxide
B (G2) S D
C
CGC
GC
n+
n+ CBC n+
n+
CBC
depletion region
depletion region
substrate
substrate
p
or or bulk B
bulk B
p
Kenneth R. Laker, University of Pennsylvania
13. VGS > VTn INVERSION REGION 14
VGS VDS
G oxide
B (G2 ) S D
CGC
C GC
n+
n+ CBC n+
n+
CBC
conducting
channel
substrate
substrate depletion region
or
or
or bulk B
or bulk B inversion region
inversion region
p
p
Underneath Gate Ec
VG = VTn
Ei
φF
2φF EFp
EFm qVTn -φF
Ev
METAL (Al) OXIDE SEMICONDUCTOR (Si)
Kenneth R. Laker, University of Pennsylvania
14. MOS Capacitance C = WLC , C = ε ox 15
[tox -> TOX in SPICE]
GC ox ox
t ox
[Cox -> COX in SPICE]
tox = 50 nm, εox = 0.34 pF/cm => Cox = 6.8 x 10-8 F/cm2
W x L = 50 µm x 50 µm => CGC = 170 fF
Depletion Capacitance C BC = WLC j , C j = εSi
xd
[NSUB -> NSUB in SPICE]
NSUB (p - substrate)
kT n i
ln φFp =
q NA
NA = 3 x 1017 cm-3, ni = 1.45 x 1010 cm-3 => φF = -0.438 V
(recall that at room temp or 27oC kT/q = 26 mV)
VSB = 0 V, εSi = 1.06 pF/cm, q = 1.6 x 10-19 C, NA, φF => xd = 6.22 µm
εSi, xd => Cj = 0.17 x 10-8 F/cm2
W x L = 50 µm x 50 µm => CBC = 42.5 fF
Kenneth R. Laker, University of Pennsylvania
15. 16
Threshold Voltage for MOS Transistors
n-channel enhancement
For VSB = 0, the threshold voltage is denoted as VT0 or VT0n,p T0 -> VT0 in SPICE]
[V
QB 0 Q ox
VT 0 = ΦGC − 2φF − −
C ox C ox
Threshold Voltage factors: (+ for nMOS and - for pMOS)
[2φ F = PHI in SPICE]
-> Gate conductor material;
-> Gate oxide material & [N A = NSUB in SPICE]
thickness;
-> Channel doping;
-> Impurities in Si-oxide
interface;
ΦGC = φF(substrate) -φM metal gate
ΦGC = φF(substrate) -φF (gate) polysilicon gate
-> Source-bulk voltage Vsb;
-> Temperature. [Qox = qNSS in SPICE]
Kenneth R. Laker, University of Pennsylvania
16. 17
Threshold Voltage for MOS Transistors
n-channel enhancement
For : the threshold voltage is denoted as VT or VTn,p
QB Q ox
VT = ΦGC − 2φF − −
C ox C ox
Q B 0 Q ox Q B − Q B0
= ΦGC − 2φF − − −
C ox C ox C ox
where VT0
(γ = Body-effect coefficient) [γ = GAMMA in SPICE]
+
Kenneth R. Laker, University of Pennsylvania
17. 18
Threshold Voltage for MOS Transistors
n-channel -> p-channel
****BE CAREFULL*** WITH SIGNS
• φF is negative in nMOS, positive in pMOS
• QB0, QB are negtive in nMOS, positive in pMOS
• γ is positive in nMOS, negative in pMOS
• VSB is negative in nMOS, positive in pMOS
C BC
NOTE: γ ∝
C GC
Kenneth R. Laker, University of Pennsylvania
18. 19
Threshold Voltage for MOS Transistors
VT0
3V nMOS NBULK = NA
14 16 NBULK
NA
10 10
pMOS
NBULK = ND
-3V
VT
16
3V (nMOS 10 /cm 3 )
14
(nMOS 3 x10 /cm 3 )
0
VBS
V SB
3 6
16
(pMOS 10 /cm3 )
-3V
Kenneth R. Laker, University of Pennsylvania
19. 20
EXAMPLE 3.2 Calculate the threshold voltage VT0 at VBS = 0, for
a polysilicon gate n-channel MOS transistor with the following
parameters:
substrate doping density NA = 1016 cm-3,
polysilicon doping density ND = 2 x 1020 cm-3,
gate oxide thickness tox = 500 Angstroms,
oxide-interface fixed charge density Nox = 4 x 1010 cm-2.
QB 0 Q ox
VT 0 = ΦGC − 2φF(sub) − −
C ox C ox
φF(sub), ΦGC: ΦGC = φF(sub) − φF(gate)
kT n i 1.45x10
10
φF(sub) = ln = 0.026Vln = −0.35V
q NA 10 16
kT N D 2 x10 20
φF( gate) = ln = 0.026 Vln 10 = 0.60 V
q ni 1.45x10
ΦGC = φF(sub) − φF(gate) = -0.35 V - 0.60 V = -0.95 V
Kenneth R. Laker, University of Pennsylvania
20. QB 0 Q ox 21
EXAMPLE 3-2 CONT. VT 0 = ΦGC − 2φF(sub) − −
C ox C ox
QB0:
= − 2(1.6x10 −19 C)(1016 cm −3 )(1.06 x10 −12 Fcm −1 ) | 2 x 0.35V|
F = C/V
-8 2
= - 4.87 x 10 C/cm
Cox:
ε ox 0.34 x10 −12 Fcm −1 −8
C ox = = = 6.8x10 F/cm 2
t ox 500 x10 −8 cm
Qox:
Q ox = qNox = (1.6x10 −19 C)(4 x1010 cm −2 ) = 6.4 x10 −9 C/cm 2
Q B 0 −4.87x10 C/cm −8 2 Q ox 6.4 x10 −9 C/cm 2
= = −0.716 V = −8 2 = 0.094 V
−8 2 Cox 6.8x10 F/cm
C ox 6.8x10 F/cm
VT 0 = −0.95V− (−0.70 V) − (−0.72 V) − (0.09V) = 0.38V
Kenneth R. Laker, University of Pennsylvania
21. EXAMPLE 3.3 Consider the n-channel MOS transistor with the 22
following process parameters:
substrate doping density NA = 1016 cm-3,
polysilicon doping density ND = 2 x 1020 cm-3,
gate oxide thickness tox = 500 Angstroms,
oxide-interface fixed charge density Nox = 4 x 1010 cm-2.
In digital circuit design, the condition VSB = 0 can not always be
quaranteed for all transistors. Plot the threshold voltage VT as a
function of VSB.
γ - Body-effect coefficient: F = C/V
2 qN A e Si 2(1.6 x10 −19 C)(1016 cm −3 )(1.06 x10 −12 Fcm −1 )
γ= = −8
C ox 6.8x10 F/cm 2
5.824 x10 −8 C/V −1/ 2 cm 2
= −8 = 0.85V1/ 2
6.8x10 C/Vcm 2
Kenneth R. Laker, University of Pennsylvania
22. 23
EXAMPLE 3-3 CONT.
where
VT 0 = 0.38V (from EX 3-2)
γ = 0.85V1 /2
VT(Volts)
1.60
1.40
1.20
1.00
0.80
0.60
0.40
0.20 VSB(Volts)
-1 0 1 2 3 4 5 6
Kenneth R. Laker, University of Pennsylvania