On-Demand, Direct Printing of Nanodiamonds at the Quantum Level

Zhaoyi Xu; Lingzhi Wang; Xiao Huan; Heekwon Lee; Jihyuk Yang; Zhiwen Zhou; Mojun Chen; Shiqi Hu; Yu Liu; Shien-Ping Feng; Tongtong Zhang; Feng Xu; Zhiqin Chu; Ji Tae Kim

doi:10.1002/advs.202103598

On-Demand, Direct Printing of Nanodiamonds at the Quantum Level

Zhaoyi Xu, Lingzhi Wang, Xiao Huan, Heekwon Lee, Jihyuk Yang, Zhiwen Zhou, Mojun Chen, Shiqi Hu, Yu Liu, Shien-Ping Feng, Tongtong Zhang, Feng Xu, Zhiqin Chu^*, Ji Tae Kim^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

9 Citations (Scopus)

49 Downloads (CityUHK Scholars)

Abstract

The quantum defects in nanodiamonds, such as nitrogen-vacancy (NV) centers, are emerging as a promising candidate for nanoscale sensing and imaging, and the controlled placement with respect to target locations is vital to their practical applications. Unfortunately, this prerequisite continues to suffer from coarse positioning accuracy, low throughput, and process complexity. Here, it is reported on direct, on-demand electrohydrodynamic printing of nanodiamonds containing NV centers with high precision control over quantity and position. After thorough characterizations of the printing conditions, it is shown that the number of printed nanodiamonds can be controlled at will, attaining the single-particle level precision. This printing approach, therefore, enables positioning NV center arrays with a controlled number directly on the universal substrate without any lithographic process. The approach is expected to pave the way toward new horizons not only for experimental quantum physics but also for the practical implementation of such quantum systems.

Original language	English
Article number	2103598
Journal	Advanced Science
Volume	9
Issue number	5
Online published	23 Dec 2021
DOIs	https://doi.org/10.1002/advs.202103598
Publication status	Published - 14 Feb 2022
Externally published	Yes

Research Keywords

electrohydrodynamic printing
lithography-free manufacturing
nanodiamonds
nitrogen vacancy centers
quantum nanomaterials

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This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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title = "On-Demand, Direct Printing of Nanodiamonds at the Quantum Level",

abstract = "The quantum defects in nanodiamonds, such as nitrogen-vacancy (NV) centers, are emerging as a promising candidate for nanoscale sensing and imaging, and the controlled placement with respect to target locations is vital to their practical applications. Unfortunately, this prerequisite continues to suffer from coarse positioning accuracy, low throughput, and process complexity. Here, it is reported on direct, on-demand electrohydrodynamic printing of nanodiamonds containing NV centers with high precision control over quantity and position. After thorough characterizations of the printing conditions, it is shown that the number of printed nanodiamonds can be controlled at will, attaining the single-particle level precision. This printing approach, therefore, enables positioning NV center arrays with a controlled number directly on the universal substrate without any lithographic process. The approach is expected to pave the way toward new horizons not only for experimental quantum physics but also for the practical implementation of such quantum systems.",

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author = "Zhaoyi Xu and Lingzhi Wang and Xiao Huan and Heekwon Lee and Jihyuk Yang and Zhiwen Zhou and Mojun Chen and Shiqi Hu and Yu Liu and Shien-Ping Feng and Tongtong Zhang and Feng Xu and Zhiqin Chu and Kim, {Ji Tae}",

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AU - Xu, Zhaoyi

AU - Wang, Lingzhi

AU - Huan, Xiao

AU - Lee, Heekwon

AU - Yang, Jihyuk

AU - Zhou, Zhiwen

AU - Chen, Mojun

AU - Hu, Shiqi

AU - Liu, Yu

AU - Feng, Shien-Ping

AU - Zhang, Tongtong

AU - Xu, Feng

AU - Chu, Zhiqin

AU - Kim, Ji Tae

PY - 2022/2/14

Y1 - 2022/2/14

N2 - The quantum defects in nanodiamonds, such as nitrogen-vacancy (NV) centers, are emerging as a promising candidate for nanoscale sensing and imaging, and the controlled placement with respect to target locations is vital to their practical applications. Unfortunately, this prerequisite continues to suffer from coarse positioning accuracy, low throughput, and process complexity. Here, it is reported on direct, on-demand electrohydrodynamic printing of nanodiamonds containing NV centers with high precision control over quantity and position. After thorough characterizations of the printing conditions, it is shown that the number of printed nanodiamonds can be controlled at will, attaining the single-particle level precision. This printing approach, therefore, enables positioning NV center arrays with a controlled number directly on the universal substrate without any lithographic process. The approach is expected to pave the way toward new horizons not only for experimental quantum physics but also for the practical implementation of such quantum systems.

AB - The quantum defects in nanodiamonds, such as nitrogen-vacancy (NV) centers, are emerging as a promising candidate for nanoscale sensing and imaging, and the controlled placement with respect to target locations is vital to their practical applications. Unfortunately, this prerequisite continues to suffer from coarse positioning accuracy, low throughput, and process complexity. Here, it is reported on direct, on-demand electrohydrodynamic printing of nanodiamonds containing NV centers with high precision control over quantity and position. After thorough characterizations of the printing conditions, it is shown that the number of printed nanodiamonds can be controlled at will, attaining the single-particle level precision. This printing approach, therefore, enables positioning NV center arrays with a controlled number directly on the universal substrate without any lithographic process. The approach is expected to pave the way toward new horizons not only for experimental quantum physics but also for the practical implementation of such quantum systems.

KW - electrohydrodynamic printing

KW - lithography-free manufacturing

KW - nanodiamonds

KW - nitrogen vacancy centers

KW - quantum nanomaterials

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DO - 10.1002/advs.202103598

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JF - Advanced Science

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On-Demand, Direct Printing of Nanodiamonds at the Quantum Level

Abstract

Research Keywords

Publisher's Copyright Statement

UN SDGs

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