Diamond quantum magnetometer with dc sensitivity of sub-10 pT Hz−1/2 toward measurement of biomagnetic field

We present a sensitive diamond quantum sensor with a magnetic field sensitivity of 9. 40. 10. 2em{0ex}pT/Hz in a near-dc frequency range of 5 to 100 Hz. This sensor is based on the continuous-wave optically detected magnetic resonance of an ensemble of nitrogen-vacancy centers along the 111 direction in a diamond (111) single crystal. The long T₂^20. 2em{0ex} in our diamond and the reduced intensity noise in laser-induced fluorescence result in remarkable sensitivity among diamond quantum sensors. Based on an Allan-deviation analysis, we demonstrate that a subpicotesla field of 0. 3 pT is detectable by interrogating the magnetic field for a few thousand seconds. The sensor head is compatible with various practical applications and allows a minimum measurement distance of about 1 mm from the sensing region. The proposed sensor facilitates the practical application of diamond quantum sensors. The sensitivity presented is realized without a magnetic flux concentrator, so that a sensitivity of tens of fT/Hz can be achievable by using a flux concentrator.