# Asymptotic entanglement in quantum walks from delocalized initial states

**Authors:** Alexandre C. Orthey Jr, Edgard P. M. Amorim

arXiv: 1703.02603 · 2017-08-03

## TL;DR

This paper investigates how the initial state delocalization affects the long-term entanglement between spin and position in one-dimensional quantum walks, revealing increased maximal entanglement with delocalized states.

## Contribution

It provides an analytical connection between initial state delocalization and asymptotic entanglement, extending understanding of entanglement dynamics in quantum walks.

## Key findings

- Delocalized initial states increase the number of spin states achieving maximal entanglement.
- A simple relation between initial spin angles determines the set of maximally entangled states.
- Numerical simulations confirm analytical predictions of entanglement behavior.

## Abstract

We study the entanglement between the internal (spin) and external (position) degrees of freedom of the one-dimensional discrete time quantum walk starting from local and delocalized initial states whose time evolution is driven by Hadamard and Fourier coins. We obtain the dependence of the asymptotic entanglement with the initial dispersion of the state and establish a way to connect the asymptotic entanglement between local and delocalized states. We find out that the delocalization of the state increases the number of initial spin states which achieves maximal entanglement from two states (local) to a continuous set of spin states (delocalized) given by a simple relation between the angles of the initial spin state. We also carry out numerical simulations of the average entanglement along the time to confront with our analytical results.

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1703.02603/full.md

## References

26 references — full list in the complete paper: https://tomesphere.com/paper/1703.02603/full.md

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Source: https://tomesphere.com/paper/1703.02603