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Complexity of simulating quantum systems on classical computers Barbara Terhal IBM Research
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Computational Quantum Physics Computational quantum physicists (in condensed-matter physics, quantum chemistry etc.) have been in the business of showing how to simulate and understand properties of many-body quantum systems using a classical computer. Heuristic and ad-hoc methods dominate, but the claim has been that these methods often work well in practice. Quantum information science has and will contribute to computational quantum physics in several ways: Come up with better simulation algorithms Make rigorous what is done heuristically/approximately in computational physics. Delineate the boundary between what is possible and what is not. That is: show that certain problems are hard for classical (or even quantum) computers in a complexity sense.
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Physically-Relevant Quantum States local interactions are between O(1) degrees of freedom (e.g. qubits)
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Efficient Classical Descriptions
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Matrix Product States
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1 st Generalization: Tree Tensor Product States
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2 nd Generalization: Tensor Product States or PEPS
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Properties of MPS and Tree-TPS
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Properties of tensor product states PEPS and TPS perhaps too general for classical simulation purposes
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Quantum Circuit Point of View Past Light Cone Max width
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Quantum Circuit Point of View
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Area Law
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Classical Simulations of Dynamics
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Lieb-Robinson Bounds Bulk Past Light Cone B A Lieb-Robinson Bound: Commutator of operator A with backwards propagated B decays exponentially with distance between A and B, when A is outside B’s effective past light-cone.
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Stoquastic Hamiltonians
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Examples of Stoquastic Hamiltonians Particles in a potential; Hamiltonian is a sum of a diagonal potential term in position |x> and off-diagonal negative kinetic terms (-d 2 /dx 2 ). All of classical and quantum mechanics. Quantum transverse Ising model Ferromagnetic Heisenberg models (modeling interacting spins on lattices) Jaynes-Cummings Hamiltonian (describing atom-laser interaction), spin-boson model, bosonic Hubbard models, Bose-Einstein condensates etc. D-Wave’s Orion quantum computer… Non-stoquastic are typically fermionic systems, charged particles in a magnetic field. Stoquastic Hamiltonians are ubiquitous in nature. Note that we only consider ground-state properties of these Hamiltonians.
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Stoquastic Hamiltonians
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Frustration-Free Stoquastic Hamiltonians
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Conclusion
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