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Quantum Simulation
Multi-scale quantum simulation of quantum field theory using wavelets
arXiv
Authors: Gavin K. Brennen, Peter Rohde, Barry C. Sanders, Sukhwinder Singh
Year
2014
Paper ID
46138
Status
Preprint
Abstract Read
~2 min
Abstract Words
130
Citations
N/A
Abstract
A successful approach to understand field theories is to resolve the physics into different length or energy scales using the renormalization group framework. We propose a quantum simulation of quantum field theory which encodes field degrees of freedom in a wavelet basis---a multi-scale description of the theory. Since wavelets are compact wavefunctions, this encoding allows for quantum simulations to create particle excitations with compact support and provides a natural way to associate observables in the theory to finite resolution detectors. We show that the wavelet basis is well suited to compute subsystem entanglement entropy by dividing the field into contributions from short-range wavelet degrees of freedom and long-range scale degrees of freedom, of which the latter act as renormalized modes which capture the essential physics at a renormalization fixed point.
Why This Paper Matters
- This paper contributes to the Quantum Simulation research area in the Quantum Articles archive.
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- A successful approach to understand field theories is to resolve the physics into different length or energy scales using the renormalization group framework.
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