# Resonant shortcuts for adiabatic rapid passage with only $z$-field   control

**Authors:** Dionisis Stefanatos, Emmanuel Paspalakis

arXiv: 1906.11493 · 2019-07-24

## TL;DR

This paper introduces novel ultrafast shortcuts for adiabatic rapid passage in qubits using only $z$-field control, enabling high-fidelity quantum gates with minimal control complexity.

## Contribution

The work develops a new method for achieving perfect adiabatic rapid passage with only $z$-field control through resonant shortcuts and pulse sequences, expanding control options in quantum computing.

## Key findings

- Constant pulses achieve perfect passage at specific times.
- Pulse sequences can ensure perfect fidelity for durations above a limit.
- Method exploits composite pulses with continuous $z$-field variation.

## Abstract

In this work we derive novel ultrafast shortcuts for adiabatic rapid passage for a qubit where the only control variable is the longitudinal $z$-field, while the transverse $x$-field remains constant. This restrictive framework is pertinent to some important tasks in quantum computing, for example the design of a high fidelity controlled-phase gate can be mapped to the adiabatic quantum control of such a qubit. We study this problem in the adiabatic reference frame and with appropriately rescaled time, using as control input the derivative of the total field polar angle (with respect to rescaled time). We first show that a constant pulse can achieve perfect adiabatic rapid passage at only specific times, corresponding to resonant shortcuts to adiabaticity. We next show that, by using "on-off-on-...-on-off-on" pulse-sequences with appropriate characteristics (amplitude, timing, and number of pulses), a perfect fidelity can be obtained for every duration larger than the limit $\pi/\Omega$, where $\Omega$ is the constant transverse $x$-field. We provide equations from which these characteristics can be calculated. The proposed methodology for generalized resonant shortcuts exploits the advantages of composite pulses in the rescaled time, while the corresponding control $z$-field varies continuously and monotonically in the original time. Of course, as the total duration approaches the lower limit, the changes in the control signal become more abrupt. These results are not restricted only to quantum information processing applications, but is also expected to impact other areas, where adiabatic rapid passage is used.

## Full text

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## Figures

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## References

45 references — full list in the complete paper: https://tomesphere.com/paper/1906.11493/full.md

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Source: https://tomesphere.com/paper/1906.11493