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An Introduction to Quantum Mechanics through Random Walks

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Presentation on theme: "An Introduction to Quantum Mechanics through Random Walks"— Presentation transcript:

1 An Introduction to Quantum Mechanics through Random Walks
Duncan Wright University of South Carolina Department of Mathematics

2 Quantum Mechanics Dun Wright
Duncan Wright University of South Carolina Department of Mathematics

3 Overview Classical vs. Quantum Physics Statistical Mechanics
Classical Random Walk Formalisms of Quantum Mechanics Quantum Random Walk Entropy and More

4 Statistical Mechanics
Classical vs. Quantum Macroscopic vs. Microscopic Complete Knowledge vs. Course Graining Commutative vs. Non-Commutative Statistical Mechanics Probability Measures vs. Trace-Class Operators

5 Performing Experiments
Step 1: Set up the experiment Choose the system we wish to analyze Set the initial state of the system Step 2: Begin the experiment Allow an external force to change the system The initial state of the system changes Step 3: Measure or observe the outcome of the experiment Determine how the system has changed Find the final state of the system

6 Stern-Gerlach Experiment

7 Classical Random Walk 2-Dimensional- Drunk Man’s Walk
1-Dimensional Random Walk Source: Wikipedia- Random Walk

8 Classical Random Walk Initial State: -3 -2 -1 0 1 2 3
Transition Matrix: Initial State: n= t x n= n= n= Final State: Transition Probability:

9 Classical Random Walk Central Limit Theorem
Source: Renato Portugal (2013): Quantum Walks and Search Algorithms

10 Formalisms of Quantum Mechanics
Def: Complete, Inner Product Space Hilbert Space Ex: Cauchy sequences converge Sesquilinear Map 1. 2. 3.

11 Formalisms of Quantum Mechanics
Hilbert Space Ex: Linear Functionals Def: “Bra” “Ket” = =

12 Formalisms of Quantum Mechanics
Hilbert Space Ex: Linear Functionals Def: Pure State

13 From Classical to Quantum
Space: State: Probability Distribution Pure State = Positive, Trace-Preserving Operators Evolution: Transition Matrix

14 Evolution of a Quantum System
In particular,

15 Quantum Random Walk Evolution: Initial State: Final State: Transition
n= n= n= n= Final State: Transition Probability:

16 Quantum Random Walk 𝐻 𝐶 = 𝐻 𝑃 = 𝐻= Internal Degrees of Freedom:
with basis 𝐻 𝑃 = Position Space: 𝐻= Where the Magic happens: with basis elements and

17 Quantum Random Walk Coin Space:
Gives equal probability to be in spin up or spin down.

18 Quantum Random Walk Shift Operator:
If particle is in spin up, S will shift it right. If particle is in spin down, S will shift it left.

19 Quantum Random Walk Unitary Operator:
Now we have options for our initial state even after restricting it to be at the origin. or

20 Quantum Random Walk Initial State: Evolution:

21 Quantum Random Walk Initial State:
Source: Renato Portugal (2013): Quantum Walks and Search Algorithms

22 Quantum Random Walk Initial State:
Source: Renato Portugal (2013): Quantum Walks and Search Algorithms

23 Quantum Random Walk Initial State:
Source: Renato Portugal (2013): Quantum Walks and Search Algorithms

24 Entropy We have a classical system whose macrostate is described by the probability measure 𝑃= 𝑝 1 , 𝑝 2 , …, 𝑝 𝑛 . After measuring the system 𝑁 times, we expect to see: 1st microstate: 𝑝 1 𝑁 times 2nd microstate: 𝑝 2 𝑁 times 𝑛th microstate: 𝑝 𝑛 𝑁 times 1 𝑁 ln 𝑁 →∞

25 More to Come Komogorov-Sinai Entropy Quantum Dynamical Entropy
Open Quantum Random Walks

26 Thank you!

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