Salvato in:
Dettagli Bibliografici
Autori principali: Jing, Jixiang, Wang, Yicheng, Wang, Zhuoran, Luo, Yumeng, Ma, Linjie, Zhang, Tongtong, Song, Chunlin, Li, Jiangyu, Li, Kwai Hei, Ki, Dong-Keun, Kim, Ji Tae, Chu, Zhiqin
Natura: Preprint
Pubblicazione: 2025
Soggetti:
Accesso online:https://arxiv.org/abs/2509.23032
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866916973374341120
author Jing, Jixiang
Wang, Yicheng
Wang, Zhuoran
Luo, Yumeng
Ma, Linjie
Zhang, Tongtong
Song, Chunlin
Li, Jiangyu
Li, Kwai Hei
Ki, Dong-Keun
Kim, Ji Tae
Chu, Zhiqin
author_facet Jing, Jixiang
Wang, Yicheng
Wang, Zhuoran
Luo, Yumeng
Ma, Linjie
Zhang, Tongtong
Song, Chunlin
Li, Jiangyu
Li, Kwai Hei
Ki, Dong-Keun
Kim, Ji Tae
Chu, Zhiqin
contents Nanodiamonds (NDs) are key materials for building nanoscale quantum sensing, imaging and communication devices. Scalable configuration of single NDs on heterogeneous platforms, forming photonic quantum source arrays, will be an essential solution towards realizing next-generation practical and industrial quantum devices. However, NDs are challenging to manipulate because their size, shape and surface chemistry vary substantially. Here, we show a simple method based on electrostatic-trapping to rapidly and reliably pattern single ND arrays on arbitrary substrates at scale. Our method, which uses carefully engineered microscale hole templates and electrostatic force, captures single NDs across 8-inch wafers with 82.5% yields within 5 min. Systematic experimental and theoretical studies show the number of deposited NDs primarily depends on the diameter of the hole trap. The method is compatible with mature CMOS technologies, enabling the mass production of scalable and integrable quantum devices. This advancement is expected to accelerate the commercialization and industrial adoption of ND-based technologies.
format Preprint
id arxiv_https___arxiv_org_abs_2509_23032
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Wafer-scale integration of single nanodiamonds via electrostatic-trapping
Jing, Jixiang
Wang, Yicheng
Wang, Zhuoran
Luo, Yumeng
Ma, Linjie
Zhang, Tongtong
Song, Chunlin
Li, Jiangyu
Li, Kwai Hei
Ki, Dong-Keun
Kim, Ji Tae
Chu, Zhiqin
Optics
Nanodiamonds (NDs) are key materials for building nanoscale quantum sensing, imaging and communication devices. Scalable configuration of single NDs on heterogeneous platforms, forming photonic quantum source arrays, will be an essential solution towards realizing next-generation practical and industrial quantum devices. However, NDs are challenging to manipulate because their size, shape and surface chemistry vary substantially. Here, we show a simple method based on electrostatic-trapping to rapidly and reliably pattern single ND arrays on arbitrary substrates at scale. Our method, which uses carefully engineered microscale hole templates and electrostatic force, captures single NDs across 8-inch wafers with 82.5% yields within 5 min. Systematic experimental and theoretical studies show the number of deposited NDs primarily depends on the diameter of the hole trap. The method is compatible with mature CMOS technologies, enabling the mass production of scalable and integrable quantum devices. This advancement is expected to accelerate the commercialization and industrial adoption of ND-based technologies.
title Wafer-scale integration of single nanodiamonds via electrostatic-trapping
topic Optics
url https://arxiv.org/abs/2509.23032