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Temperature sensing with nitrogen vacancy center in diamond

Lin Hao-Bin Zhang Shao-Chun Dong Yang Zheng Yu Chen Xiang-Dong Sun Fang-Wen

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Temperature sensing with nitrogen vacancy center in diamond

Lin Hao-Bin, Zhang Shao-Chun, Dong Yang, Zheng Yu, Chen Xiang-Dong, Sun Fang-Wen
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  • Temperature is the most intuitive and widespread in various physical quantities. Violent changes in temperature usually implies the appearing of fluctuations in physical properties of an object. Therefore, temperature is often an important indicator. With the development of science and technology, the scales in many fields are being more and more miniaturized. However, there are no mature temperature measurement systems in the case where the spatial scale is less than 10 μm. In addition to the requirement for spatial resolution, the sensor ought to exert no dramatic influence on the object to be measured. The nitrogen vacancy (NV) center in diamond is a stable luminescence defect. The measurements of its spectrum and spin state can be used to obtain the information about physical quantities near the color center, such as temperature and electro-magnetic field. Owing to its stable chemical properties and high thermal conductivity, the NV center can be applied to the noninvasive detection for nano-scale researches. It can also be used in the life field because it is non-toxic to cells. Moreover, combined with different techniques, such as optical fiber, scanning thermal microscopy, NV center can be used to measure the local temperatures in different scenarios. This review focuses on the temperature properties, the method of measuring temperature, and relevant applications of NV centers.
      Corresponding author: Sun Fang-Wen, fwsun@ustc.edu.cn
    • Funds: Project supported by the National Key Research and Development Program of China (Grant No. 2017YFA0304504), the National Natural Science Foundation of China (Grant Nos. 91850102, 12005218), and the Science Fund for Distinguished Young Scholars of Heibei Province, China (Grant No. F2019516002).
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  • 图 1  不同温度零场劈裂. 横坐标为施加的微波频率, 纵坐标为归一化的荧光强度, 两条曲线代表不同的温度[13]

    Figure 1.  Zero-field splitting with different temperatures. The horizontal coordinate is the applied microwave frequency, while the vertical coordinate is the normalized fluorescence intensity[13].

    图 2  光学探测磁共振谱和零声子线随温度的变化[14]

    Figure 2.  Temperature dependent ODMR and zero-phonon line[14].

    图 3  三点快速测温法. 根据图中的3个点—f1, f2, f3拟合出1个完整的ODMR曲线. 前提是整个ODMR曲线的形状变化不大[36]

    Figure 3.  Three-point fast thermometry. A complete ODMR curve can be fitted according to the three points in the figure—f1, f2, f3[36]

    图 4  利用自旋操作消除磁场相位的影响提高温度的灵敏度. 图(b)中的$ \pi/2 $用于产生叠加态, 3个$ \pi $脉冲用于改变相位的符号, 去除磁相位的影响[28]

    Figure 4.  Spin operation is used to improve the temperature sensitivity by removing the effect of the magnetic field. The $ \pi/2 $ pulse in the panel (b) is used to generate the superposition state, and three $ \pi $ pulses are used to change the sign of the phase and remove the effect of the magnetic phase[28]

    图 5  各种体系的温度灵敏度与尺寸大小. 横坐标为传感器尺寸, 纵坐标为温度灵敏度[29]

    Figure 5.  Temperature sensitivity versus size for various systems. The horizontal coordinate is the sensor size and the vertical coordinate is the temperature sensitivity[29].

    图 6  细胞内测温[29] (a)共聚焦下的荧光图, 虚线部分是细胞膜, 白色叉的部分表示金纳米颗粒的位置, 用来加热细胞. 圆圈表示纳米金刚石的位置. 旁边的颜色条是荧光的计数率. (b)不同金纳米颗粒的荧光条件下, 金刚石的温度差

    Figure 6.  Intracellular thermometry[29]. (a) Fluorescence with confocal microscopy. The dashed part shows the cell membrane. The cross shows the position of gold nanoparticles, which is used to heat the cell. The circle shows the position of nanodiamond. The color bar next to it shows the count rate of fluorescence. (b) Temperature difference of diamond under different fluorescence conditions of gold nanoparticles

    图 7  一体化细胞测温[48] (a)线虫示意图; (b)测量的样品室, 集成了微波、NV色心和细胞生活环境; (c)下半幅图为药物刺激下的温度变化反应, 上半幅图为对应的荧光强度; (d) 对照组

    Figure 7.  Integrated cellular thermometry[48]: (a) Schematic diagram of Caenorhabditis elegans worms; (b) sample chamber: integrated microwave, NV color center and cell living environment; (c) the lower half shows the temperature change response to drug stimulation, and the upper half shows the corresponding fluorescence intensity; (d) the control

    图 8  利用金刚石控制细胞的存活[49] (a)绿色的是蛋白质, 红色的是与金纳米颗粒混合的荧光纳米金刚石; (b)利用功率为330 μW的594 nm激光照射6 s后产生的结果: 细胞的膜隧道纳米管破裂了

    Figure 8.  Using diamond to control cell survival[49]: (a) The green is protein and the red is fluorescent nanodiamond mixed with gold nanoparticles; (b) obtained results after a 594 nm laser irradiation at a power of 330 μW for 6 s: the membrane tunneling nanotubes of the cell ruptured

    图 9  NV色心对材料的温度和磁场进行表征[52] (a)测量装置示意图, 插图的红色小点为纳米金刚石; (b)氮化镓高电子迁移率晶体管成像示意图; (c) 高分辨率磁场测量(功率为290 mW); (d), (e) 功率为1和1.73 W下沟道阻挡层的温度分布

    Figure 9.  Characterizing the temperature and magnetic field of the material with NV center[52]: (a) Schematic diagram of the measurement device, and the red dots in the inset are nanodiamonds; (b) imaging schematic of a gallium nitride high-electron mobility transistor; (c) high-resolution magnetic field measurement (290 mW); (d), (e) temperature distribution of the channel stop at different powers of 1 and 1.73 W

    图 10  利用PDMS进行局部测温[53] (a)纳米金刚石转移到PDMS上的微纳加工工艺; (b)通过ODMR拟合提取出温度信息, 并对温度进行重建之后的温度分布图

    Figure 10.  Local temperature measurement with PDMS[53]: (a) Processing of nanodiamond transferred to PDMS; (b) temperature distribution after extracting the temperature information by ODMR fitting and reconstructing the temperature

    图 11  利用光纤传感对芯片温度分布进行测量[54] (a)测量的系统, 结合了锁相放大系统与光纤系统; (b)色心传感装置示意图, 红色的螺旋线表示微波天线; (c), (d)芯片未通电与通电时的温度分布图; (e)对应于图(c)和图(d)的红色虚线测量值

    Figure 11.  Chip temperature distribution is measured using fiber optic sensing[54]: (a) System of measurement, combining the phase-locked amplification system with the fiber optic system; (b) schematic diagram of the color center sensing device, with the red spiral lines indicating the microwave antenna; (c), (d) temperature distribution of the chip when it is powered off and on; (e) corresponds to the red dashed line measurements in panel (c) and (d)

    图 12  对材料热导率进行测量[33] (a)实验装置, 电流沿着AFM的悬梁臂, 通过加热悬梁臂间接加热粘在上面的金刚石色心. 色心发出的荧光通过一个高数值孔径的显微镜收集. (b)与不同介质接触后金刚石的温度, 横坐标为加热的温度, 纵坐标为金刚石的温度

    Figure 12.  Measuring the thermal conductivity of materials[33]. (a) Experimental setup, where current is flowing along the cantilever arm of the AFM and indirectly heats a diamond color center attached to it by heating the cantilever arm. The fluorescence emitted from NV center is collected through a microscope in a high numerical aperture. (b) Temperature of the diamond contact with different mediums. The horizontal coordinate is the temperature of heating and the vertical coordinate is the temperature of the diamond

    表 1  NV色心的测量灵敏度

    Table 1.  Measurement sensitivity with NV color centers.

    温度灵敏度/$({\rm{mK} }\cdot{ {\rm{Hz}^{-1/2} } })$ 方法 样品 NV色心浓度或者碳含量 参考文献
    0.43 利用自旋锁相结合ODMR 块状 0.1—1 × 106 (99.99% ${ }^{12} {\rm{C}}$) [35]
    0.76 增加NV色心的浓度 块状 2.84 × 106 [43]
    1.6 借助磁场消磁测量温度 块状 0.15 × 106 [40]
    5 对自旋能级进行相干操控 块状 99.995% ${ }^{12} {\rm{C}}$ [28]
    9 对自旋能级进行相干操控 块状 99.99% ${ }^{12}{\rm{ C}}$ [29]
    10 对自旋能级进行相干操控 块状 1.1% 13C [27]
    10.1 利用多脉冲进行相干操控 块状 1.1% 13C [37]
    11 利用居里温度下磁场的改变推算出温度 100 nm 500个NV [41]
    0.076 利用居里温度下磁场的改变推算出温度 金刚石立柱 单个NV [42]
    130 对自旋能级进行相干操控 50 nm 无相关数据 [28]
    300 NV色心电子态的超精细结构 50 nm 100个NV [32]
    DownLoad: CSV
  • [1]

    van Oort E, Manson N B, Glasbeek M 1988 J. Phys. C: Solid State Phys. 21 4385Google Scholar

    [2]

    Gruber A 1997 Science 276 2012Google Scholar

    [3]

    Jelezko F, Gaebel T, Popa I, Domhan M, Gruber A, Wrachtrup J 2004 Phys. Rev. Lett. 93 130501Google Scholar

    [4]

    Fuchs G D, Dobrovitski V V, Hanson R, Batra A, Weis C D, Schenkel T, Awschalom D D 2008 Phys. Rev. Lett. 101 117601Google Scholar

    [5]

    Neumann P, Kolesov R, Jacques V, Beck J, Tisler J, Batalov A, Rogers L, Manson N B, Balasubramanian G, Jelezko F, Wrachtrup J 2009 New J. Phys. 11 013017Google Scholar

    [6]

    Childress L, Hanson R 2013 MRS Bull. 38 134Google Scholar

    [7]

    Chen X, Zou C, Gong Z, Dong C, Guo G, Sun F 2015 Light Sci. Appl. 4 e230Google Scholar

    [8]

    Han K Y, Kim S K, Eggeling C, Hell S W 2010 Nano Lett. 10 3199Google Scholar

    [9]

    Arroyo-Camejo S, Adam M P, Besbes M, Hugonin J P, Jacques V, Greffet J J, Roch J F, Hell S W, Treussart F 2013 ACS Nano 7 10912Google Scholar

    [10]

    Maze J R, Stanwix P L, Hodges J S, Hong S, Taylor J M, Cappellaro P, Jiang L, Dutt M V G, Togan E, Zibrov A S, Yacoby A, Walsworth R L, Lukin M D 2008 Nature 455 644Google Scholar

    [11]

    Dolde F, Fedder H, Doherty M W, Nbauer T, Rempp F, Balasubramanian G, Wolf T, Reinhard F, Hollenberg L C L, Jelezko F, Wrachtrup J 2011 Nat. Phys. 7 459Google Scholar

    [12]

    Ovartchaiyapong P, Lee K W, Myers B A, Jayich A C B 2014 Nat. Commun. 5 4429Google Scholar

    [13]

    Acosta V M, Bauch E, Ledbetter M P, Waxman A, Bouchard L S, Budker D 2010 Phys. Rev. Lett. 104 070801Google Scholar

    [14]

    Chen X D, Dong C H, Sun F W, Zou C L, Cui J M, Han Z F, Guo G C 2011 Appl. Phys. Lett. 99 161903Google Scholar

    [15]

    Hayashi T, Fukuda N, Uchiyama S, Inada N 2015 PLoS One 10 e0117677Google Scholar

    [16]

    Jaque D, del Rosal B, Rodrguez E M, Maestro L M, Haro-Gonzlez P, Sol J G 2014 Nanomedicine 9 1047Google Scholar

    [17]

    Somero G N 1995 Annu. Rev. Physiol. 57 43Google Scholar

    [18]

    Suzuki M, Tseeb V, Oyama K, Ishiwata S I 2007 Biophys. J. 92 2Google Scholar

    [19]

    Zohar O, Ikeda M, Shinagawa H, Inoue H, Nakamura H, Elbaum D, Alkon D L, Yoshioka T 1998 Biophys. J. 74 82Google Scholar

    [20]

    Astakhov V P, Outeiro J 2019 Importance of Temperature in Metal Cutting and Its Proper Measurement/Modeling (Cham: Springer International Publishing) pp1–47

    [21]

    Shi L, Dames C, Lukes J R, Reddy P, Duda J, Cahill D G, Lee J, Marconnet A, Goodson K E, Bahk J H, Shakouri A, Prasher R S, Felts J, King W P, Han B, Bischof J C 2015 Nanoscale and Microscale Thermophys. Eng. 19 127Google Scholar

    [22]

    Brites C D S, Balabhadra S, Carlos L D 2019 Adv. Opt. Mater. 7 1801239Google Scholar

    [23]

    Doherty M W, Acosta V M, Jarmola A, Barson M S J, Manson N B, Budker D, Hollenberg L C L 2014 Phys. Rev. B 90 041201Google Scholar

    [24]

    Li C C, Gong M, Chen X D, Li S, Zhao B W, Dong Y, Guo G C, Sun F W 2017 Diamond Relat. Mater. 74 119Google Scholar

    [25]

    Schirhagl R, Chang K, Loretz M, Degen C L 2014 Annu. Rev. Phys. Chem. 65 83Google Scholar

    [26]

    Toyli D M, Christle D J, Alkauskas A, Buckley B B, Van de Walle C G, Awschalom D D 2012 Phys. Rev. X 2 031001Google Scholar

    [27]

    Toyli D M, de las Casas C F, Christle D J, Dobrovitski V V, Awschalom D D 2013 Proc. Natl. Acad. Sci. 110 8417Google Scholar

    [28]

    Neumann P, Jakobi I, Dolde F, Burk C, Reuter R, Waldherr G, Honert J, Wolf T, Brunner A, Shim J H, Suter D, Sumiya H, Isoya J, Wrachtrup J 2013 Nano Lett. 13 2738Google Scholar

    [29]

    Kucsko G, Maurer P C, Yao N Y, Kubo M, Noh H J, Lo P K, Park H, Lukin M D 2013 Nature 500 54Google Scholar

    [30]

    Fedotov I V, Blakley S, Serebryannikov E E, Safronov N A, Velichansky V L, Scully M O, Zheltikov A M 2014 Appl. Phys. Lett. 105 261109Google Scholar

    [31]

    Kraus H, Soltamov V A, Fuchs F, Simin D, Sperlich A, Baranov P G, Astakhov G V, Dyakonov V 2015 Sci. Rep. 4 5303Google Scholar

    [32]

    Plakhotnik T, Aman H, Chang H C 2015 Nanotechnology 26 245501Google Scholar

    [33]

    Laraoui A, Aycock-Rizzo H, Gao Y, Lu X, Riedo E, Meriles C A 2015 Nat. Commun. 6 8954Google Scholar

    [34]

    Jelezko F, Wrachtrup J 2006 Phys. Status Solidi A 203 3207Google Scholar

    [35]

    Wojciechowski A M, Karadas M, Osterkamp C, Jankuhn S, Meijer J, Jelezko F, Huck A, Andersen U L 2018 Appl. Phys. Lett. 113 013502Google Scholar

    [36]

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Metrics
  • Abstract views:  9378
  • PDF Downloads:  464
  • Cited By: 0
Publishing process
  • Received Date:  30 September 2021
  • Accepted Date:  26 October 2021
  • Available Online:  25 March 2022
  • Published Online:  20 March 2022

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