Selective Temperature Sensing in Nanodiamonds Using Dressed States

IF 4.4 Q1 OPTICS
Nathaniel M. Beaver, Paul Stevenson
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Abstract

Temperature sensing at the nanoscale is a significant experimental challenge. Here, an approach using dressed states is reported to make a leading quantum sensor – the nitrogen-vacancy (NV) center in diamond – selectively sensitive to temperature, even in the presence of normally confounding magnetic fields. Using an experimentally straightforward approach, the magnetic sensitivity of the NV center is suppressed by a factor of seven, while retaining full temperature sensitivity and narrowing the NV center linewidth. These results demonstrate the power of engineering the sensor Hamiltonian using external control fields to enable sensing with improved specificity to target signals.

Abstract Image

纳米金刚石利用凹陷状态进行选择性温度传感
纳米尺度的温度传感是一项重大的实验挑战。本文报告了一种利用掺杂态的方法,使领先的量子传感器--金刚石中的氮空位(NV)中心--对温度选择性地敏感,即使在通常存在干扰磁场的情况下也是如此。利用一种直接的实验方法,NV 中心的磁灵敏度被抑制了 7 倍,同时保持了完全的温度灵敏度并缩小了 NV 中心的线宽。这些结果表明,利用外部控制场对传感器哈密顿进行工程设计,可以提高传感对目标信号的特异性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.90
自引率
0.00%
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