Diamond with Sp2-Sp3 composite phase for thermometry at Millikelvin temperatures

Jianan Yin; Yang Yan; Mulin Miao; Jiayin Tang; Jiali Jiang; Hui Liu; Yuhan Chen; Yinxian Chen; Fucong Lyu; Zhengyi Mao; Yunhu He; Lei Wan; Binbin Zhou; Jian Lu

doi:10.1038/s41467-024-48137-z

Diamond with Sp²-Sp³ composite phase for thermometry at Millikelvin temperatures

Jianan Yin, Yang Yan, Mulin Miao, Jiayin Tang, Jiali Jiang, Hui Liu, Yuhan Chen, Yinxian Chen, Fucong Lyu, Zhengyi Mao, Yunhu He, Lei Wan, Binbin Zhou, Jian Lu^*

^*Corresponding author for this work

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

2 Citations (Scopus)

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Abstract

Temperature is one of the seven fundamental physical quantities. The ability to measure temperatures approaching absolute zero has driven numerous advances in low-temperature physics and quantum physics. Currently, millikelvin temperatures and below are measured through the characterization of a certain thermal state of the system as there is no traditional thermometer capable of measuring temperatures at such low levels. In this study, we develop a kind of diamond with sp²-sp³ composite phase to tackle this problem. The synthesized composite phase diamond (CPD) exhibits a negative temperature coefficient, providing an excellent fit across a broad temperature range, and reaching a temperature measurement limit of 1 mK. Additionally, the CPD demonstrates low magnetic field sensitivity and excellent thermal stability, and can be fabricated into probes down to 1 micron in diameter, making it a promising candidate for the manufacture of next-generation cryogenic temperature sensors. This development is significant for the low-temperature physics researches, and can help facilitate the transition of quantum computing, quantum simulation, and other related technologies from research to practical applications. © The Author(s) 2024

Original language	English
Article number	3871
Journal	Nature Communications
Volume	15
Issue number	1
Online published	8 May 2024
DOIs	https://doi.org/10.1038/s41467-024-48137-z
Publication status	Published - 2024

Funding

J.L. acknowledges the Shenzhen-Hong Kong Science and Technology Innovation Cooperation Zone Shenzhen Park Project (Project No: HZQB-KCZYB-2020030), the Hong Kong General Research Fund (GRF) Scheme (Project No: CityU 11216219), the Research Grants Council of Hong Kong (Project No: AoE/M−402/20.) and the Hong Kong Innovation and Technology Commission via the Hong Kong Branch of National Precious Metals Material Engineering Research Center. We thank Tianjian Carbon Material Co., Ltd. for providing diamonds. The authors would like to acknowledge Prof. Danfeng LI, Prof. Kun YU and Mr. Tit Wah CHAN for their consistent encouragement and support. The authors would like to acknowledge Ms. Ruonan ZHAO, Mr. Zhicheng PEI, Dr. Bingqiang WEI and Mr. Jingzhuo ZHOU for fruitful discussions.

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title = "Diamond with Sp2-Sp3 composite phase for thermometry at Millikelvin temperatures",

abstract = "Temperature is one of the seven fundamental physical quantities. The ability to measure temperatures approaching absolute zero has driven numerous advances in low-temperature physics and quantum physics. Currently, millikelvin temperatures and below are measured through the characterization of a certain thermal state of the system as there is no traditional thermometer capable of measuring temperatures at such low levels. In this study, we develop a kind of diamond with sp2-sp3 composite phase to tackle this problem. The synthesized composite phase diamond (CPD) exhibits a negative temperature coefficient, providing an excellent fit across a broad temperature range, and reaching a temperature measurement limit of 1 mK. Additionally, the CPD demonstrates low magnetic field sensitivity and excellent thermal stability, and can be fabricated into probes down to 1 micron in diameter, making it a promising candidate for the manufacture of next-generation cryogenic temperature sensors. This development is significant for the low-temperature physics researches, and can help facilitate the transition of quantum computing, quantum simulation, and other related technologies from research to practical applications. {\textcopyright} The Author(s) 2024",

author = "Jianan Yin and Yang Yan and Mulin Miao and Jiayin Tang and Jiali Jiang and Hui Liu and Yuhan Chen and Yinxian Chen and Fucong Lyu and Zhengyi Mao and Yunhu He and Lei Wan and Binbin Zhou and Jian Lu",

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AU - Yin, Jianan

AU - Yan, Yang

AU - Miao, Mulin

AU - Tang, Jiayin

AU - Jiang, Jiali

AU - Liu, Hui

AU - Chen, Yuhan

AU - Chen, Yinxian

AU - Lyu, Fucong

AU - Mao, Zhengyi

AU - He, Yunhu

AU - Wan, Lei

AU - Zhou, Binbin

AU - Lu, Jian

PY - 2024

Y1 - 2024

N2 - Temperature is one of the seven fundamental physical quantities. The ability to measure temperatures approaching absolute zero has driven numerous advances in low-temperature physics and quantum physics. Currently, millikelvin temperatures and below are measured through the characterization of a certain thermal state of the system as there is no traditional thermometer capable of measuring temperatures at such low levels. In this study, we develop a kind of diamond with sp2-sp3 composite phase to tackle this problem. The synthesized composite phase diamond (CPD) exhibits a negative temperature coefficient, providing an excellent fit across a broad temperature range, and reaching a temperature measurement limit of 1 mK. Additionally, the CPD demonstrates low magnetic field sensitivity and excellent thermal stability, and can be fabricated into probes down to 1 micron in diameter, making it a promising candidate for the manufacture of next-generation cryogenic temperature sensors. This development is significant for the low-temperature physics researches, and can help facilitate the transition of quantum computing, quantum simulation, and other related technologies from research to practical applications. © The Author(s) 2024

AB - Temperature is one of the seven fundamental physical quantities. The ability to measure temperatures approaching absolute zero has driven numerous advances in low-temperature physics and quantum physics. Currently, millikelvin temperatures and below are measured through the characterization of a certain thermal state of the system as there is no traditional thermometer capable of measuring temperatures at such low levels. In this study, we develop a kind of diamond with sp2-sp3 composite phase to tackle this problem. The synthesized composite phase diamond (CPD) exhibits a negative temperature coefficient, providing an excellent fit across a broad temperature range, and reaching a temperature measurement limit of 1 mK. Additionally, the CPD demonstrates low magnetic field sensitivity and excellent thermal stability, and can be fabricated into probes down to 1 micron in diameter, making it a promising candidate for the manufacture of next-generation cryogenic temperature sensors. This development is significant for the low-temperature physics researches, and can help facilitate the transition of quantum computing, quantum simulation, and other related technologies from research to practical applications. © The Author(s) 2024

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Diamond with Sp²-Sp³ composite phase for thermometry at Millikelvin temperatures

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Diamond with Sp2-Sp3 composite phase for thermometry at Millikelvin temperatures

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AoE(UGC)-ExtU-Lead: Aging, Skeletal Degeneration and Regeneration

GRF: Study the Plastic Deformation Mechanism and Thermal Stability of Ultra-strong /ductile Nano-dual-phase Alloys

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Diamond with Sp²-Sp³ composite phase for thermometry at Millikelvin temperatures