Optimized detection modality for radio-frequency sensing with a double resonance alignment magnetometer

akbar, ali; jensen, kasper

dc.contributor.author	akbar, ali
dc.contributor.author	jensen, kasper
dc.contributor.other	Koźbiał, Marcin
dc.contributor.other	Kołodyński, Jan
dc.contributor.other	Meraki, Adil
dc.contributor.other	Jensen, Kasper
dc.contributor.other	Elson, Lucy
dc.date.accessioned	2024-10-23T10:05:17Z
dc.date.available	2024-10-23T10:05:17Z
dc.date.issued	2024-11-05
dc.identifier.uri	https://rdmc.nottingham.ac.uk/handle/internal/11588
dc.description.abstract	In this work, we presented a comprehensive and comparative analysis of two detection modalities, i.e., polarization rotation and absorption measurement of light, for a double resonance alignment magnetometer (DRAM). To verify theoretical predictions, experiments are carried out using a room-temperature paraffin-coated Caesium vapour cell and measuring either the polarization rotation or absorption of the transmitted laser light. A detailed experimental analysis of the resonance spectra is performed to validate the theoretical findings for various input parameters. The results signify the use of a single isotropic relaxation rate thus simplifying the data analysis for optimization of the DRAM. The sensitivity measurements are performed and reveal that the polarization rotation detection mode yields larger signals and better sensitivity than absorption measurement of light.	en_UK
dc.language.iso	en	en_UK
dc.publisher	The University of Nottingham	en_UK
dc.rights	CC-BY	*
dc.rights.uri	https://creativecommons.org/licenses/by/4.0/	*
dc.subject.lcsh	Magnetometry	en_UK
dc.subject.lcsh	Quantum optics	en_UK
dc.title	Optimized detection modality for radio-frequency sensing with a double resonance alignment magnetometer	en_UK
dc.type	Dataset	en_UK
dc.identifier.doi	http://doi.org/10.17639/nott.7483
dc.subject.free	Optically pumped magnetometers, RF magnetometers, RF sensing, Quantum Optics	en_UK
dc.subject.jacs	Physical sciences::Physics::Optical physics, Laser physics	en_UK
dc.subject.lc	Q Science::QC Physics::QC350 Optics. Light, including spectroscopy	en_UK
dc.date.collection	April--October 2023	en_UK
uon.division	University of Nottingham, UK Campus::Faculty of Science::School of Physics and Astronomy	en_UK
uon.funder.controlled	Engineering & Physical Sciences Research Council	en_UK
uon.datatype	Data is text files generated by alignment based optical magnetometer.	en_UK
uon.funder.free	The European Union’s Horizon 2020 research and innovation programme	en_UK
uon.funder.free	Novo Nordisk Foundation	en_UK
uon.funder.free	National Science Center, Poland	en_UK
uon.grant	EP/T027126/1, EP/Y005260/1, NNF20OC0064182, 2019/32/Z/ST2/00026, 2023/50/E/ST2/00457	en_UK
uon.collectionmethod	Data was collected by connecting the Thorlabs balanced photodetector and single photodetector output directly into the data acquisition card (Spectrum Instrumentation M2p.5932-x4) where various input parameters of experiments were varied.	en_UK