# Quantum Simulations with Unitary & Nonunitary Controls: NMR   implementations

**Authors:** Swathi S Hegde

arXiv: 1701.03443 · 2017-01-13

## TL;DR

This paper explores quantum simulation techniques using NMR, demonstrating control over unitary and nonunitary processes, including quantum many-body freezing, phase decoherence, and its suppression.

## Contribution

It presents experimental methods for simulating quantum phenomena with both unitary and nonunitary controls, including a protocol for decomposing arbitrary unitaries and techniques for decoherence suppression.

## Key findings

- Successful simulation of quantum many-body freezing
- Development of a protocol for unitary decomposition
- Effective suppression of phase decoherence

## Abstract

Feynman, in 1982, proposed the idea of using a quantum simulator to perform quantum simulations. A quantum simulator is basically a controllable quantum system that can mimic the dynamics of other quantum systems we wish to study. In this thesis we investigate some aspects of quantum simulation using both unitary and nonunitary controls. In the unitary part, we experimentally simulated the phenomenon of quantum many-body freezing, and also developed a general protocol to decompose an arbitrary unitary operator. In the nonunitary part, we studied phase decoherence by artificially inducing it. We characterized it by noise spectroscopy and quantum process tomography, and also suppressed it by using standard dynamical decoupling techniques. While we use nuclear spin systems in an NMR setup as our quantum testbed, most of the concepts are general and are applicable elsewhere.

## Full text

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## Figures

47 figures with captions in the complete paper: https://tomesphere.com/paper/1701.03443/full.md

## References

127 references — full list in the complete paper: https://tomesphere.com/paper/1701.03443/full.md

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Source: https://tomesphere.com/paper/1701.03443