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Main Authors: Shen, Xueyang, Chu, Ruixuan, Xu, Ding, Gao, Yuan, Zhou, Wen, Zhang, Wei
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.10667
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author Shen, Xueyang
Chu, Ruixuan
Xu, Ding
Gao, Yuan
Zhou, Wen
Zhang, Wei
author_facet Shen, Xueyang
Chu, Ruixuan
Xu, Ding
Gao, Yuan
Zhou, Wen
Zhang, Wei
contents Phase-change materials (PCMs)-based integrated photonic memory offers a viable pathway for the development of neuromorphic computing chip. The sizable optical contrast in the telecom band between amorphous and crystalline phases of PCM, in particular, Ge2Sb2Te5 (GST), is used for multilevel programming. However, the high extinction coefficient k of crystalline GST leads to high optical loss, posing a serious challenge for scaling up the device array for practical use. In this work, we focus on the atomic understanding and application of the so-called low-loss PCM, Sb2Se3, through multiscale simulations. First, we elucidate the bonding origin of the wavelength dependent optical properties of amorphous and crystalline Sb2Se3 via ab initio calculations. Given the suppressed k in the telecom band, we design a programable mode converter (PMC) waveguide device that utilizes only the contrast in refractive index n between amorphous and crystalline Sb2Se3 to encode multiple optical levels per waveguide device. The finite-difference time-domain simulations show that a single PMC device can achieve 5-bit programming precision (32 levels) via direct laser writing, and the photonic tensor core formed by the PMC array could possibly be scaled to 128*128. Finally, a thorough comparison between low-loss PCM and conventional PCM is provided.
format Preprint
id arxiv_https___arxiv_org_abs_2603_10667
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Low-loss phase-change material based programmable mode converter for photonic computing
Shen, Xueyang
Chu, Ruixuan
Xu, Ding
Gao, Yuan
Zhou, Wen
Zhang, Wei
Materials Science
Phase-change materials (PCMs)-based integrated photonic memory offers a viable pathway for the development of neuromorphic computing chip. The sizable optical contrast in the telecom band between amorphous and crystalline phases of PCM, in particular, Ge2Sb2Te5 (GST), is used for multilevel programming. However, the high extinction coefficient k of crystalline GST leads to high optical loss, posing a serious challenge for scaling up the device array for practical use. In this work, we focus on the atomic understanding and application of the so-called low-loss PCM, Sb2Se3, through multiscale simulations. First, we elucidate the bonding origin of the wavelength dependent optical properties of amorphous and crystalline Sb2Se3 via ab initio calculations. Given the suppressed k in the telecom band, we design a programable mode converter (PMC) waveguide device that utilizes only the contrast in refractive index n between amorphous and crystalline Sb2Se3 to encode multiple optical levels per waveguide device. The finite-difference time-domain simulations show that a single PMC device can achieve 5-bit programming precision (32 levels) via direct laser writing, and the photonic tensor core formed by the PMC array could possibly be scaled to 128*128. Finally, a thorough comparison between low-loss PCM and conventional PCM is provided.
title Low-loss phase-change material based programmable mode converter for photonic computing
topic Materials Science
url https://arxiv.org/abs/2603.10667