Gating classical information flow through spin chains by quantum phase transitions

TL;DR

This paper demonstrates that quantum fluctuations in spin chains can be harnessed to control classical information flow, with external magnetic fields inducing phase transitions that modulate whether the initial input influences the final spin state.

Contribution

It introduces a method to gate classical information in spin chains by exploiting quantum phase transitions driven by magnetic fields.

Findings

Quantum fluctuations can be used to control information flow.

External magnetic fields induce phase transitions affecting spin orientation.

The approach applies to a broad class of anisotropic spin chains.

Abstract

To push commercial electronics beyond its current size limits, atomic-scale communication channels and logic units need to be designed, making the use of quantum entities an imperative. In this regime, quantum fluctuations naturally become prominent, and are generally considered to be detrimental. Here we show that for spin-based information processing, these fluctuations can be uniquely exploited to gate the flow of classical binary information across a magnetic chain. Moreover, this information flow can be controlled with a modest external magnetic field that drives the system through different many-body quantum phases in which the orientation of the final spin does or does not reflect the orientation of the initial input. Our results are general for a wide class of anisotropic spin chains that act as magnetic cellular automata, and suggest that quantum fluctuations may play a unique role in driving classical information flow at the atomic scale.