Thin Film Ferroelectric Photonic-electronic Memory

Overview

Journal Light Sci Appl

Publisher Springer Nature

Date 2024 Aug 23

PMID 39179550

Authors

Gong Zhang

Yue Chen

Zijie Zheng

Rui Shao

Jiuren Zhou

Zuopu Zhou

Leming Jiao

Jishen Zhang

Haibo Wang

Qiwen Kong

Chen Sun

Kai Ni

Jixuan Wu

Jiezhi Chen

Xiao Gong

Affiliations

Soon will be listed here.

Abstract

To reduce system complexity and bridge the interface between electronic and photonic circuits, there is a high demand for a non-volatile memory that can be accessed both electrically and optically. However, practical solutions are still lacking when considering the potential for large-scale complementary metal-oxide semiconductor compatible integration. Here, we present an experimental demonstration of a non-volatile photonic-electronic memory based on a 3-dimensional monolithic integrated ferroelectric-silicon ring resonator. We successfully demonstrate programming and erasing the memory using both electrical and optical methods, assisted by optical-to-electrical-to-optical conversion. The memory cell exhibits a high optical extinction ratio of 6.6 dB at a low working voltage of 5 V and an endurance of 4 × 10 cycles. Furthermore, the multi-level storage capability is analyzed in detail, revealing stable performance with a raw bit-error-rate smaller than 5.9 × 10. This ground-breaking work could be a key technology enabler for future hybrid electronic-photonic systems, targeting a wide range of applications such as photonic interconnect, high-speed data communication, and neuromorphic computing.

Citing Articles

Non-volatile photonic-electronic memory via 3D monolithic ferroelectric-silicon ring resonator.

Chen H Light Sci Appl. 2024; 13(1):271.

PMID: 39327444 PMC: 11427707. DOI: 10.1038/s41377-024-01625-9.

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