Simulating many-body physics with quantum phase-space methods

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Simulations✄ soliton jitter, soliton squeezing, supercontinuum generationfb3 ; 1000 paths0123abc42Relative noise (dB)0−2−4−6−8−10Electronic onlyRaman T=300KRaman T = 1E−6K0 2 4 6 8 10 12x/x 0Simulating many-body physics with quantum phase-space methods 33
Application II: atoms in a lattice|1>|2>|1>FermionsBosonsĤ = −∑ t i j ĉ † i,σĉ j,σ +U ∑ĉ †i j,σjj,↑ĉ† j,↓ĉ j,↓ĉ j,↑✄ simplest model of an interacting Fermi gas on a lattice➜ weak-coupling limit → BCS transitions➜ solid-state models; relevance to High-T c superconductorsSimulating many-body physics with quantum phase-space methods 34
Page 1: Simulating many-body physics with q
Page 4 and 5: Theoretical Methods✄ deterministi
Page 6 and 7: Overview✄introduction to phase-sp
Page 8: Probability distributions✄ many w
Page 11 and 12: Simulating many-body physics with q
Page 13 and 14: Density operators for quantum evolu
Page 15 and 16: Stochastic Gauges✄ Mapping from H
Page 17 and 18: Overview✄ introduction to phase-s
Page 19 and 20: General Gaussian operatorsa general
Page 22 and 23: Gaussian Basis II: Thermal operator
Page 24 and 25: Extended phase space−→ λ = (Ω
Page 26 and 27: Application I: photons in a fibreĤ
Page 28 and 29: Quantum Langevin Equations✄ Raman
Page 30 and 31: Wigner Equations✄ get stochastic,
Page 32 and 33: +P Equations✄ get two stochastic
Page 36 and 37: Solving the Hubbard Model✄ only t
Page 38 and 39: Applying the Gaussian representatio
Page 40 and 41: Stratonovich Equations✄ Itô stoc
Page 42 and 43: Branching✄ averages are weighted,
Page 44 and 45: Application III: Molecules in a wel
Page 46: Summary✄ Generalised phase-space

Simulating many-body physics with quantum phase-space methods

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