This work argues that the emerging understanding of time in quantum information science can be articulated as a philosophical theory of change. Change and time are interrelated, and one can be used to interrogate the other, namely, a theory of change can be derived from a theory of time. What is new in quantum science is time being regarded as just another property to be engineered. At the quantum scale, time is reversible in certain ways, which is quite different from the everyday experience of time whose unidirectional arrow does not allow a dropped egg to reassemble. At the quantum scale of atoms, though, a particle retains the history of its trajectory, which may be retraced before collapsed in measurement.
Quantum scientists evolve systems backward and forward in time, controlling phase transitions with Floquet engineering. Quantum systems are entangled in time and space, with temporal correlations exhibiting greater multiplicity than spatial correlations. The chaotic time regimes of ballistic spread followed by saturation are implemented in quantum walks for faster search and heightened cryptosecurity. In quantum neuroscience, seizure may be explained by chaotic dynamics and normal resting state by Floquet-like periodic cycles. Time is revealed to have the same kinds of repeating structures as space (described by entanglement, symmetry, and topology), differently instantiated and controlled.
The quantum understanding of time can be propelled into a macroscale-theory of change through its connotation of a more flexible, malleable, probabilistic interface with reality. Change becomes less rigid. Probability is the lever of change, but notoriously difficult for humans to grasp, as we think better in storylines than statistics. The idea of manipulating quantum system properties in which time, space, dynamics (change), are all just parameters, is an empowering frame for the acceptance of change. The quantum mindset affords greater facility with probability-driven events (change).
ICT role in 21st century education and its challenges
The Quantum Mindset
1. The Quantum Mindset and the
Physics of Change
Acacia Group Los Angeles CA 19 Mar 2022
Slides: http://slideshare.net/LaBlogga
Melanie Swan, MBA, PhD
Quantum Technologies
Centre for Blockchain Technologies
University College London
2. 19 Mar 2022
Quantum Mindset
Change
Problem: lack of resources for thinking about change
Change: the act of becoming different (before-after temporality)
Method: obtain building blocks from various fields
Philosophy
Quantum physics
Clinical neuroscience
Financial markets
Result: distill a composite theory of change
Quantum Mindset: a two-cultures tool (arts and sciences) that
can be productively deployed to contemplate change
Nietzschean acceptance of uncertainty, quantum physics Floquet
engineering of time as any system parameter, Black Swan thinking
of outsized events occurring with frequency
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“Plus ça change, plus c’est la même chose”
– Karr, 1849, Les Guêpes (The Wasps)
“The more it changes, the more it’s the same thing”
3. 19 Mar 2022
Quantum Mindset
Philosophy
Badiou-Derrida: the event (different afterwards)
French revolution, bomb, 9/11, moon landing, DNA
Hegel: amalgamation of events is history (shapes of spirit)
Foucault: power-determined knowledge eras (epistemes)
Deleuze-Baudrillard (French philosophies of difference):
Distinguish between appearance and reality
Kant: time-space goggles are the synthetic a priori
transcendental condition of any experience
Bergson: doubled internal “deep time, deep change”
Nietzsche: embrace uncertainty; adopt an historical
philosophizing that is both in time and beyond our time
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4. 19 Mar 2022
Quantum Mindset
Quantum physics
Time reversibility
Trajectory history available before collapsed in measurement
Unlike macroscale of broken egg or milk poured into coffee
Out-of-time-order correlation functions (OTOCs)
Evolve a system to earlier or later time to apply an action
Floquet engineering
Direct a periodic system to avoid or enter phase transition
Time entanglement (greater multiplicity than spatial)
Chaos (time regimes of ballistic spread followed by saturation)
Quantum walks for faster search and heightened cryptosecurity
Quantum neuroscience: seizure has chaotic dynamics
Normal resting state: Floquet-like periodic cycles
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5. 19 Mar 2022
Quantum Mindset
Probability
A particle (or superpositioned data
modeled by quantum product
managers in today’s corporations)
Literally exists in all possible states
simultaneously before being collapsed
in a measurement
Einstein “God does not play dice”
However, probabilistic nature of
quantum reality proven
Double-slit experiment (light behaves
simultaneously as particle and wave)
Entangled particles
Superpositioned states
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Quantum System:
Exists in every possible
state of 0 and 1 until
collapsed in measurement
Classical System:
Always in a state of
either 0 or 1
Source: Piazza, L., Lummen, T.T.A, Quinonez, E. et al. (2015). Simultaneous observation of the quantization and the
interference pattern of a plasmonic near-field. Nature Communications. 6(6407):107.
6. 19 Mar 2022
Quantum Mindset
Probability
Probability: predict the possibility of
change happening, the likelihood of
uncertain future events occurring
Medical diagnosis and treatment
Crop failure
Speculation
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Normal (Gaussian) Distribution Fat-tailed (Black Swan) Distribution Drug-dosing Based on S-Curves
Source: Taleb, N.N. (2001). Fooled by Randomness: The Hidden Role of Chance in Life and in the Markets. (2007). The Black
Swan: The Impact of the Highly Improbable. New York: Random House.
7. 19 Mar 2022
Quantum Mindset
Neuroscience and Markets
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Sources: Breakspear, M. (2017). Dynamic models of large-scale brain activity. Nat Neurosci. 20:340-52. Taleb, N.N. (2001). Fooled
by Randomness. (2007). The Black Swan: The Impact of the Highly Improbable. New York: Random House.
Black-Scholes Model
Neuroscience
Seizure: chaotic dynamics
Resting state: Floquet-like periodicity
Markets
Critique of Black Scholes option pricing
with normal distribution assumptions
8. 19 Mar 2022
Quantum Mindset
The Quantum Mindset
The Quantum Mindset: thinking in terms of quantum
properties to solve problems
Superposition: literally co-existing realities before collapsed
Superpositioned data modeling (all possible system states tested
simultaneously); quantum product manager (Gartner)
Quantum machine learning (unsupervised learning using Born
machine not Boltzmann machine)
Develop standardized quantum circuits (e.g. neural signaling)
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Classical System
(0/1 bits)
Quantum System
(complex-valued qubits
on a Bloch sphere)
Domain Properties Definition
Quantum
Matter
Symmetry Looking the same from different points of view (e.g. a face, cube, laws of physics);
symmetry breaking is phase transition
Topology Geometric structure preserved under deformation (bending, stretching, twisting, and
crumpling, but not cutting or gluing); doughnut and coffee cup both have a hole
Quantum
Information
Superposition An unobserved particle exists in all possible states simultaneously, but once measured,
collapses to just one state (superpositioned data modeling of all possible states)
Entanglement Particles connected such that their states are related, even when separated by distance
(a “tails-up/tails-down” relationship; one particle in one state, other in the other)
Interference Waves reinforcing or canceling each other out (cohering or decohering)
9. 19 Mar 2022
Quantum Mindset
The Quantum Mindset Theory of Change
A multidisciplinary theory of change
Nietzschean acceptance of uncertainty
Quantum Floquet engineering of time as any system feature
Black Swan higher-frequency outsized events
Flexible performative attitude towards non-intuitive
concepts, informed by the quantum domain
Macroscale-theory of change: a more flexible, malleable,
probabilistic interface with reality, change becomes less rigid
The idea of manipulating quantum system properties in
which time, space, and dynamics (change) are all just
parameters provides an empowering frame for the
acceptance of change
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10. The Quantum Mindset and the
Physics of Change
Acacia Group Los Angeles CA 19 Mar 2022
Slides: http://slideshare.net/LaBlogga
Melanie Swan, MBA, PhD
Quantum Technologies
Centre for Blockchain Technologies
University College London
Thank you!
Questions?
11. 19 Mar 2022
Quantum Mindset
The Quantum Mindset in everyday use
Heisenberg uncertainty principle
A particle’s speed or location can be known, but not both
Police officer: “Sir, do you know how fast you were going?”
Heisenberg: “No, but I know where I am”
Schrödinger’s cat states and superposition
Multiple states literally coexist before collapsed in measurement
Police officer: (inspecting trunk): “Sir, did you know there is a dead cat?”
Schrödinger: “Well, now I do” (Gartner: corporate hiring of physicists)
Einstein: E=mc2 and no “spooky action at a distance”
Energy is equal to mass x the speed of light squared, no FTL
True, faster-than-light travel does not allow one particle to influence
another, but entanglement is the proven explanation
Heads-tails relationships between particles, used in the quantum
teleportation of cryptographic keys for secure login
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