All-silicon non-volatile optical memory based on photon avalanche-induced trapping

Yuan Yuan; Yiwei Peng; Stanley Cheung; Wayne V. Sorin; Sean Hooten; Zhihong Huang; Di Liang; Jiuyi Zhang; Marco Fiorentino; Raymond G. Beausoleil

doi:10.1038/s42005-025-01934-4

Communications Physics (Jan 2025)

All-silicon non-volatile optical memory based on photon avalanche-induced trapping

Yuan Yuan,
Yiwei Peng,
Stanley Cheung,
Wayne V. Sorin,
Sean Hooten,
Zhihong Huang,
Di Liang,
Jiuyi Zhang,
Marco Fiorentino,
Raymond G. Beausoleil

Affiliations

Yuan Yuan: Hewlett Packard Labs, Hewlett Packard Enterprise
Yiwei Peng: Hewlett Packard Labs, Hewlett Packard Enterprise
Stanley Cheung: Hewlett Packard Labs, Hewlett Packard Enterprise
Wayne V. Sorin: Hewlett Packard Labs, Hewlett Packard Enterprise
Sean Hooten: Hewlett Packard Labs, Hewlett Packard Enterprise
Zhihong Huang: Hewlett Packard Labs, Hewlett Packard Enterprise
Di Liang: Electrical Engineering and Computer Science Department, University of Michigan
Jiuyi Zhang: Hewlett Packard Labs, Hewlett Packard Enterprise
Marco Fiorentino: Hewlett Packard Labs, Hewlett Packard Enterprise
Raymond G. Beausoleil: Hewlett Packard Labs, Hewlett Packard Enterprise

DOI: https://doi.org/10.1038/s42005-025-01934-4
Journal volume & issue: Vol. 8, no. 1
pp. 1 – 11

Abstract

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Abstract Implementing on-chip non-volatile optical memories has long been an actively pursued goal, promising significant enhancements in the capability and energy efficiency of photonic integrated circuits. Here, we demonstrate an non-volatile optical memory exclusively using the most common semiconductor material, silicon. By manipulating the photon avalanche effect, we introduce a trapping effect at the silicon-silicon oxide interface, which in turn demonstrates a non-volatile reprogrammable optical memory cell with a record-high 4-bit encoding, robust retention and endurance. This silicon avalanche-induced trapping memory provides a distinctively cost-efficient and high-reliability route to realize optical data storage in standard silicon foundry processes. We demonstrate its applications in trimming in optical interconnects and in-memory computing. Our in-memory computing test case reduces energy consumption by approximately 83% compared to conventional optical approaches.

Published in Communications Physics

ISSN: 2399-3650 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Science: Astronomy: Astrophysics; Science: Physics
Website: https://www.nature.com/commsphys/

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