# Measurement of back-action from electron spins in a gate defined GaAs   double quantum dot coupled to a mesoscopic nuclear spin bath

**Authors:** Patrick Bethke, Robert P. G. McNeil, Julian Ritzmann, Tim Botzem, Arne, Ludwig, Andreas D. Wieck, Hendrik Bluhm

arXiv: 1906.11264 · 2020-07-28

## TL;DR

This paper provides direct experimental evidence of back-action from an electron spin qubit on a mesoscopic nuclear spin environment in a GaAs quantum dot, revealing quantum interactions in a large, complex system.

## Contribution

It demonstrates the first direct measurement of back-action from a single electron spin qubit on a large nuclear spin bath using correlation techniques.

## Key findings

- Detected back-action in a system of about 10^6 nuclear spins.
- Correlations depend on the intermediate qubit state, indicating quantum back-action.
- Measured back-action effects within the qubit's coherence time.

## Abstract

Decoherence of a quantum system arising from its interaction with an environment is a key concept for understanding the transition between the quantum and classical world as well as performance limitations in quantum technology applications. The effects of large, weakly coupled environments are often described as a classical, fluctuating field whose dynamics is unaffected by the qubit, whereas a fully quantum description still implies some back-action from the qubit on the environment. Here we show direct experimental evidence for such a back-action for an electron-spin-qubit in a GaAs quantum dot coupled to a mesoscopic environment of order $10^6$ nuclear spins. By means of a correlation measurement technique, we detect the back-action of a single qubit-environment interaction whose duration is comparable to the qubit's coherence time, even in such a large system. We repeatedly let the qubit interact with the spin bath and measure its state. Between such cycles, the qubit is reinitialized to different states. The correlations of the measurement outcomes are strongly affected by the intermediate qubit state, which reveals the action of a single electron spin on the nuclear spins.

## Full text

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## Figures

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## References

36 references — full list in the complete paper: https://tomesphere.com/paper/1906.11264/full.md

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Source: https://tomesphere.com/paper/1906.11264