The diamond anvil cell-based high-pressure technique is a unique tool for creating new states of matter and for understanding the physics underlying some exotic phenomena.In situ sensing of spin and charge properties ...The diamond anvil cell-based high-pressure technique is a unique tool for creating new states of matter and for understanding the physics underlying some exotic phenomena.In situ sensing of spin and charge properties under high pressure is crucially important but remains technically challenging.While the nitrogen-vacancy(NV)center in diamond is a promising quantum sensor under extreme conditions,its spin dynamics and the quantum control of its spin states under high pressure remain elusive.In this study,we demonstrate coherent control,spin relaxation,and spin dephasing measurements for ensemble NV centers up to 32.8 GPa.With this in situ quantum sensor,we investigate the pressure-induced magnetic phase transition of a micron-size permanent magnet Nd2Fe14B sample in a diamond anvil cell,with a spatial resolution of ~2μm,and sensitivity of ~20 μT/Hz1/2. This scheme could be generalized to measure other parameters such as temperature,pressure and their gradients under extreme conditions.This will be beneficial for frontier research of condensed matter physics and geophysics.展开更多
Megabar pressures are of crucial importance for cutting-edge studies of condensed matter physics and geophysics.With the development of diamond anvil cell(DAC),laboratory studies of high pressure have entered the mega...Megabar pressures are of crucial importance for cutting-edge studies of condensed matter physics and geophysics.With the development of diamond anvil cell(DAC),laboratory studies of high pressure have entered the megabar era for decades.However,it is still challenging to implement in situ magnetic sensing under ultrahigh pressures.In this work,we demonstrate optically detected magnetic resonance and coherent quantum control of diamond nitrogen-vacancy(NV)center,a promising quantum sensor inside the DAC,up to 1.4 Mbar.The pressure dependence of optical and spin properties of NV centers in diamond are quantified,and the evolution of an external magnetic field has been successfully tracked at about 80 GPa.These results shed new light on our understanding of diamond NV centers and pave the way for quantum sensing under extreme conditions.展开更多
This work⑴was additionally supported by the National Key R&D Program of China under Grant No 2018YFA0305700.The financial acknowledgment section should be corrected as follows:Supported by the National Basic Rese...This work⑴was additionally supported by the National Key R&D Program of China under Grant No 2018YFA0305700.The financial acknowledgment section should be corrected as follows:Supported by the National Basic Research Program of China under Grant No 2015CB921103,the National Key R&D Program of China under Grant Nos 2016YFA0401503 and 2018YFA0305700,the Strategic Priority Research Program of Chinese Academy of Sciences under Grant No XDB28000000.展开更多
基金Supported by the National Basic Research Program of China under Grant No 2015CB921103the National Key R&D Program of China under Grant No 2016YFA0401503+2 种基金the Strategic Priority Research Program of Chinese Academy of Sciences under Grant No XDB28000000the National Natural Science Foundation of China under Grant Nos 11574386,11575288 and 51402350the Youth Innovation Promotion Association of Chinese Academy of Sciences under Grant No 2016006
文摘The diamond anvil cell-based high-pressure technique is a unique tool for creating new states of matter and for understanding the physics underlying some exotic phenomena.In situ sensing of spin and charge properties under high pressure is crucially important but remains technically challenging.While the nitrogen-vacancy(NV)center in diamond is a promising quantum sensor under extreme conditions,its spin dynamics and the quantum control of its spin states under high pressure remain elusive.In this study,we demonstrate coherent control,spin relaxation,and spin dephasing measurements for ensemble NV centers up to 32.8 GPa.With this in situ quantum sensor,we investigate the pressure-induced magnetic phase transition of a micron-size permanent magnet Nd2Fe14B sample in a diamond anvil cell,with a spatial resolution of ~2μm,and sensitivity of ~20 μT/Hz1/2. This scheme could be generalized to measure other parameters such as temperature,pressure and their gradients under extreme conditions.This will be beneficial for frontier research of condensed matter physics and geophysics.
基金supported by the Beijing Natural Science Foundation(Grant No.Z200009)Chinese Academy of Sciences(Grant Nos.YJKYYQ20190082,XDB28000000,XDB33000000,XDB25000000,and QYZDBSSW-SLH013)+2 种基金the National Natural Science Foundation of China(Grant Nos.11974020,12022509,12074422,11934018,and T2121001)the National Key Research and Development Program of China(Grant Nos.2019YFA0308100,2021YFA1400300,and 2018YFA0305700)the Youth Innovation Promotion Association of Chinese Academy of Sciences(Grant No.202003)。
文摘Megabar pressures are of crucial importance for cutting-edge studies of condensed matter physics and geophysics.With the development of diamond anvil cell(DAC),laboratory studies of high pressure have entered the megabar era for decades.However,it is still challenging to implement in situ magnetic sensing under ultrahigh pressures.In this work,we demonstrate optically detected magnetic resonance and coherent quantum control of diamond nitrogen-vacancy(NV)center,a promising quantum sensor inside the DAC,up to 1.4 Mbar.The pressure dependence of optical and spin properties of NV centers in diamond are quantified,and the evolution of an external magnetic field has been successfully tracked at about 80 GPa.These results shed new light on our understanding of diamond NV centers and pave the way for quantum sensing under extreme conditions.
文摘This work⑴was additionally supported by the National Key R&D Program of China under Grant No 2018YFA0305700.The financial acknowledgment section should be corrected as follows:Supported by the National Basic Research Program of China under Grant No 2015CB921103,the National Key R&D Program of China under Grant Nos 2016YFA0401503 and 2018YFA0305700,the Strategic Priority Research Program of Chinese Academy of Sciences under Grant No XDB28000000.
