Litcius/Paper detail

Suppression of thermal coupling noise in the SERF atomic co-magnetometer

Jiasen Ruan, Lihong Duan, Yang Fu, Yang Lv, Wenfeng Fan, Xinxiu Zhou, Wei Quan

2023Results in Physics12 citationsDOIOpen Access PDF

Abstract

Heating the alkali metal vapor cell to obtain high atomic density is a prerequisite for realizing the high-precision measurement for spin-exchange relaxation-free (SERF) co-magnetometer. However, the thermo-magnetic and thermo-optical coupling noise caused by the temperature diffusion from the alkali vapor cell is one of the main factors restricting the co-magnetometer performance at present. Here the influence of heating on the SERF co-magnetometer was comprehensively studied, and the thermal error model of the system was established. A novel heat insulation structure for the co-magnetometer was designed, and the effectiveness was verified through monitoring of characteristic temperature points. Compared to the conventional oven support, the average maximum temperature difference within 12 h of the optical path and magnetic shielding systems (OPMSS) decreased by 52%, the bias instability of the co-magnetometer decreased by 24%, and the noise of the co-magnetometer at 1 Hz decreased by 33%. The experimental results demonstrate that this method reduces the temperature fluctuation of the OPMSS, effectively suppresses the thermal coupling noise, and thus improves the performance of the SERF co-magnetometer. Moreover, this method is also applicable to other quantum sensors based on alkali metal vapor cell.

Topics & Concepts

MagnetometerCoupling (piping)Noise (video)Magnetic noiseMaterials scienceElectromagnetic shieldingAlkali metalNuclear magnetic resonanceRelaxation (psychology)Analytical Chemistry (journal)ChemistryCondensed matter physicsMagnetic fieldAtomic physicsPhysicsComposite materialImage (mathematics)PsychologyOrganic chemistryComputer scienceArtificial intelligenceChromatographySocial psychologyQuantum mechanicsAtomic and Subatomic Physics ResearchQuantum optics and atomic interactionsAdvanced MRI Techniques and Applications