Electron spin resonance (ESR) spectroscopy has broad applications in physics, chemistry and biology. As a complementary tool, zero-field ESR (ZF-ESR) spectroscopy has been proposed for decades and shown its own benefits for investigating the electron fine and hyperfine interaction. However, the ZF-ESR method has been rarely used due to the low sensitivity and the requirement of much larger samples than conventional ESR. In this work, we present a method for deploying ZF-ESR spectroscopy at the nanoscale by using a highly sensitive quantum sensor, the nitrogen-vacancy center in diamond. We also measure the nanoscale ZF-ESR spectrum of a few P1 centers in diamond, and show that the hyperfine coupling constant can be directly extracted from the spectrum. This method opens the door to practical applications of ZF-ESR spectroscopy, such as investigation of the structure and polarity information in spin-modified organic and biological systems.
@article{arxiv.2002.07974,
title = {Nanoscale zero-field electron spin resonance spectroscopy},
author = {Fei Kong and Pengju Zhao and Xiangyu Ye and Zhecheng Wang and Zhuoyang Qin and Pei Yu and Jihu Su and Fazhan Shi and Jiangfeng Du},
journal= {arXiv preprint arXiv:2002.07974},
year = {2020}
}