Diamond micro-chip for quantum microscopy

Shahidul Asif; Hang Chen; Johannes Cremer; Shantam Ravan; Jeyson Támara-Isaza; Saurabh Lamsal; Reza Ebadi; Yan Li; Ling Jie Zhou; Cui Zu Chang; John Q. Xiao; Amir Yacoby; Ronald L. Walsworth; Mark J.H. Ku

doi:10.1116/5.0223774

Diamond micro-chip for quantum microscopy

Shahidul Asif, Hang Chen, Johannes Cremer, Shantam Ravan, Jeyson Támara-Isaza, Saurabh Lamsal, Reza Ebadi, Yan Li, Ling Jie Zhou, Cui Zu Chang, John Q. Xiao, Amir Yacoby, Ronald L. Walsworth, Mark J.H. Ku

Physics

Research output: Contribution to journal › Article › peer-review

Abstract

The nitrogen-vacancy (NV) center in diamond is an increasingly popular quantum sensor for microscopy of electrical current, magnetization, and spins. However, efficient NV-sample integration with a robust, high-quality interface remains an outstanding challenge to realize scalable, high-throughput microscopy. In this work, we characterize a diamond micro-chip (DMC) containing a (111)-oriented NV ensemble and demonstrate its utility for high-resolution quantum microscopy. We perform strain imaging of the DMC and find minimal detrimental strain variation across a field of view of tens of micrometer. We find good ensemble NV spin coherence and optical properties in the DMC, suitable for sensitive magnetometry. We then use the DMC to demonstrate wide-field microscopy of electrical current and show that diffraction-limited quantum microscopy can be achieved. We also demonstrate the deterministic transfer of DMCs with multiple materials of interest for next-generation electronics and spintronics. Lastly, we develop a polymer-based technique for DMC placement. This work establishes the DMC's potential to expand the application of NV quantum microscopy in materials, device, geological, biomedical, and chemical sciences.

Original language	English (US)
Article number	044405
Journal	AVS Quantum Science
Volume	6
Issue number	4
DOIs	https://doi.org/10.1116/5.0223774
State	Published - Dec 1 2024

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Atomic and Molecular Physics, and Optics
Condensed Matter Physics
Computer Networks and Communications
Physical and Theoretical Chemistry
Computational Theory and Mathematics
Electrical and Electronic Engineering

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title = "Diamond micro-chip for quantum microscopy",

abstract = "The nitrogen-vacancy (NV) center in diamond is an increasingly popular quantum sensor for microscopy of electrical current, magnetization, and spins. However, efficient NV-sample integration with a robust, high-quality interface remains an outstanding challenge to realize scalable, high-throughput microscopy. In this work, we characterize a diamond micro-chip (DMC) containing a (111)-oriented NV ensemble and demonstrate its utility for high-resolution quantum microscopy. We perform strain imaging of the DMC and find minimal detrimental strain variation across a field of view of tens of micrometer. We find good ensemble NV spin coherence and optical properties in the DMC, suitable for sensitive magnetometry. We then use the DMC to demonstrate wide-field microscopy of electrical current and show that diffraction-limited quantum microscopy can be achieved. We also demonstrate the deterministic transfer of DMCs with multiple materials of interest for next-generation electronics and spintronics. Lastly, we develop a polymer-based technique for DMC placement. This work establishes the DMC's potential to expand the application of NV quantum microscopy in materials, device, geological, biomedical, and chemical sciences.",

author = "Shahidul Asif and Hang Chen and Johannes Cremer and Shantam Ravan and Jeyson T{\'a}mara-Isaza and Saurabh Lamsal and Reza Ebadi and Yan Li and Zhou, {Ling Jie} and Chang, {Cui Zu} and Xiao, {John Q.} and Amir Yacoby and Walsworth, {Ronald L.} and Ku, {Mark J.H.}",

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doi = "10.1116/5.0223774",

language = "English (US)",

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T1 - Diamond micro-chip for quantum microscopy

AU - Asif, Shahidul

AU - Chen, Hang

AU - Cremer, Johannes

AU - Ravan, Shantam

AU - Támara-Isaza, Jeyson

AU - Lamsal, Saurabh

AU - Ebadi, Reza

AU - Li, Yan

AU - Zhou, Ling Jie

AU - Chang, Cui Zu

AU - Xiao, John Q.

AU - Yacoby, Amir

AU - Walsworth, Ronald L.

AU - Ku, Mark J.H.

PY - 2024/12/1

Y1 - 2024/12/1

N2 - The nitrogen-vacancy (NV) center in diamond is an increasingly popular quantum sensor for microscopy of electrical current, magnetization, and spins. However, efficient NV-sample integration with a robust, high-quality interface remains an outstanding challenge to realize scalable, high-throughput microscopy. In this work, we characterize a diamond micro-chip (DMC) containing a (111)-oriented NV ensemble and demonstrate its utility for high-resolution quantum microscopy. We perform strain imaging of the DMC and find minimal detrimental strain variation across a field of view of tens of micrometer. We find good ensemble NV spin coherence and optical properties in the DMC, suitable for sensitive magnetometry. We then use the DMC to demonstrate wide-field microscopy of electrical current and show that diffraction-limited quantum microscopy can be achieved. We also demonstrate the deterministic transfer of DMCs with multiple materials of interest for next-generation electronics and spintronics. Lastly, we develop a polymer-based technique for DMC placement. This work establishes the DMC's potential to expand the application of NV quantum microscopy in materials, device, geological, biomedical, and chemical sciences.

AB - The nitrogen-vacancy (NV) center in diamond is an increasingly popular quantum sensor for microscopy of electrical current, magnetization, and spins. However, efficient NV-sample integration with a robust, high-quality interface remains an outstanding challenge to realize scalable, high-throughput microscopy. In this work, we characterize a diamond micro-chip (DMC) containing a (111)-oriented NV ensemble and demonstrate its utility for high-resolution quantum microscopy. We perform strain imaging of the DMC and find minimal detrimental strain variation across a field of view of tens of micrometer. We find good ensemble NV spin coherence and optical properties in the DMC, suitable for sensitive magnetometry. We then use the DMC to demonstrate wide-field microscopy of electrical current and show that diffraction-limited quantum microscopy can be achieved. We also demonstrate the deterministic transfer of DMCs with multiple materials of interest for next-generation electronics and spintronics. Lastly, we develop a polymer-based technique for DMC placement. This work establishes the DMC's potential to expand the application of NV quantum microscopy in materials, device, geological, biomedical, and chemical sciences.

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Diamond micro-chip for quantum microscopy

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