# Optimizing NMR quantum information processing via generalized   transitionless quantum driving

**Authors:** Alan C. Santos, Amanda Nicotina, Alexandre M. de Souza, Roberto S., Sarthour, Ivan S. Oliveira, Marcelo S. Sarandy

arXiv: 1906.08065 · 2020-03-16

## TL;DR

This paper experimentally investigates a generalized transitionless quantum driving method in NMR, demonstrating its robustness and resource efficiency for fast, high-fidelity quantum control even under resonance conditions.

## Contribution

It introduces a generalized TQD approach for NMR that is robust against resonance and requires less energy, improving quantum control efficiency.

## Key findings

- Generalized TQD mimics adiabatic behavior at resonance.
- Requires less magnetic field strength than standard TQD.
- Provides feasible, optimized single-qubit gates with robustness against decoherence.

## Abstract

High performance quantum information processing requires efficient control of undesired decohering effects, which are present in realistic quantum dynamics. To deal with this issue, a powerful strategy is to employ transitionless quantum driving (TQD), where additional fields are added to speed up the evolution of the quantum system, achieving a desired state in a short time in comparison with the natural decoherence time scales. In this paper, we provide an experimental investigation of the performance of a generalized approach for TQD to implement shortcuts to adiabaticity in nuclear magnetic resonance (NMR). As a first discussion, we consider a single nuclear spin-$\frac{1}{2}$ system in a time-dependent rotating magnetic field. While the adiabatic dynamics is violated at a resonance situation, the TQD Hamiltonian is shown to be robust against resonance, allowing us to mimic the adiabatic behavior in a fast evolution even under the resonant configurations of the original (adiabatic) Hamiltonian. Moreover, we show that the generalized TQD theory requires less energy resources, with the strength of the magnetic field less than that required by standard TQD. As a second discussion, we analyze the experimental implementation of shortcuts to single-qubit adiabatic gates. By adopting generalized TQD, we can provide feasible time-independent driving Hamiltonians, which are optimized in terms of the number of pulses used to implement the quantum dynamics. The robustness of adiabatic and generalized TQD evolutions against typical decoherence processes in NMR is also analyzed.

## Full text

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## Figures

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## References

38 references — full list in the complete paper: https://tomesphere.com/paper/1906.08065/full.md

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Source: https://tomesphere.com/paper/1906.08065