USTC Obtained Single-spin Electron Paramagnetic Resonance Spectrum with Kilohertz Spectral Resolution
2020-06-18

A high-resolution paramagnetic resonance detection method based on the diamond nitrogen-vacancy (NV) color center quantum sensor was proposed and experimentally implemented, which is led by academician Du Jiangfeng from CAS Key Laboratory of Microscale Magnetic Resonance of University of Science and Technology of China (USTC) of Chinese Academy of Sciences (CAS). They obtained the single spin paramagnetic resonance spectrum with kilohertz (kHz) spectral resolution. This research was published in Science Advances, entitled “Kilohertz electron paramagnetic response specialty of single nitrogen centers at zero magnetic field”.

Electron paramagnetic resonance spectroscopy is an important scientific research method in material science, which is commonly used to obtain the information about dynamics and structure of molecules. A major development trend of this technology is to get as accurate information as possible from as few samples as possible, which requires enhancing both spatial resolution and spectral resolution.

In recent decades, the spatial resolution has been improved considerably, and the detection of single-spin paramagnetic resonance even reached to the nanoscale due to the emergence of new detection technology. However, the spectral resolution remains in the megahertz (MHz) scale because of uncontrollable external noise, which prevents further analysis of the structure, local environment and other information at the single molecular level. Therefore, a new method has to be found in order to break through the current limitation of spectral resolution caused by noise.

In addition to actively suppressing noise, another more direct and effective way is to make the measured spin naturally insensitive to external noise. A certain kind of spin states can resist the disturbance of external magnetic field noise, and the spectral lines generated by electron when transiting between these spin states will be narrowed. This physical phenomenon exists widely in ion traps, nuclear magnetic resonance, and phosphorous-silicon systems. It has been reported that this phenomenon also exists for a kind of paramagnetic material under zero magnetic field in previous research. However, the detection sensitivity of traditional paramagnetic resonance technology is related to the magnitude of magnetic field, and the detection efficiency in zero field is extremely low, which limits the practical application. Therefore, the research team used NV color center quantum sensor in diamond to detect paramagnetic resonance. Previous work has proved that the NV color center still has single-spin level detection sensitivity even at zero field.

In order to observe the narrowing of the spectral lines and realize high-resolution spectroscopy detection, it is also necessary to eliminate the broadening of the spectral line caused by the NV sensor itself. Inspired by the correlation detection in nuclear magnetic resonance (NMR), Du Jiangfeng’s team designed a paramagnetic resonance correlation sequence suitable for zero field, which greatly suppressed the intrinsic broadening of NV sensors. Using this new method, researchers successfully detected the narrowing transition of the electron spin of a single nitrogen atom in diamond in their experiment. Compared with the traditional method, the spectral resolution has been improved considerably by 27 times, reaching 8.6 kHz.

The comparison of the paramagnetic resonance spectrum between the traditional method (top) and the new method (bottom) of noise-insensitive. It clearly shows that the spectral resolution has been significantly improved, and more precise coupling information has been observed. (Image by DU Jiangfeng et al.)

This experimental results shows that the paramagnetic resonance technology based on NV quantum sensor can achieve both high spatial and high spectral resolution. At the same time, this method is not limited by harsh environmental conditions (such as vacuum or low temperature), which is very competitive in biological applications. More detailed information of structural, dynamic changes and local environmental characteristics of a single molecule can be analyzed.

Paper line: https://advances.sciencemag.org/content/6/22/eaaz8244

(Written by Mairehaba, edited by LU Hongyu, USTC News Center)


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