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Magnetometry Using Ramsey Interferometry in a Yb Atomic Beam


Affiliations
1 Department of Physics, Indian Institute of Science, Bengaluru 560 012, India
 

We use the Ramsey separated oscillatory fields technique in a 400°C thermal beam of ytterbium (Yb) atoms to measure the Larmor precession frequency (and hence the magnetic field) with high precision. For the experiment, we use the strongly allowed 1S01P1 transition at 399 nm, and choose the odd isotope 171Yb with nuclear spin I = 1/2, so that the ground state has only two magnetic sublevels mF=±1/2. With a magnetic field of 22.2 G and a separation of about 400 mm between the oscillatory fields, the central Ramsey fringe is at 16.64 kHz and has a width of 350 Hz. The technique can be readily adapted to a cold atomic beam, which is expected to give more than an orderof- magnitude improvement in precision. The signal-to- noise ratio is comparable to other techniques of magnetometry; therefore it should be useful for all kinds of precision measurements such as searching for a permanent electric dipole moment in atoms.

Keywords

Magnetometry, Oscillatory Fields, Precession Frequency, Ytterbium Atoms.
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  • Magnetometry Using Ramsey Interferometry in a Yb Atomic Beam

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Authors

Ketan D. Rathod
Department of Physics, Indian Institute of Science, Bengaluru 560 012, India
Vasant Natarajan
Department of Physics, Indian Institute of Science, Bengaluru 560 012, India

Abstract


We use the Ramsey separated oscillatory fields technique in a 400°C thermal beam of ytterbium (Yb) atoms to measure the Larmor precession frequency (and hence the magnetic field) with high precision. For the experiment, we use the strongly allowed 1S01P1 transition at 399 nm, and choose the odd isotope 171Yb with nuclear spin I = 1/2, so that the ground state has only two magnetic sublevels mF=±1/2. With a magnetic field of 22.2 G and a separation of about 400 mm between the oscillatory fields, the central Ramsey fringe is at 16.64 kHz and has a width of 350 Hz. The technique can be readily adapted to a cold atomic beam, which is expected to give more than an orderof- magnitude improvement in precision. The signal-to- noise ratio is comparable to other techniques of magnetometry; therefore it should be useful for all kinds of precision measurements such as searching for a permanent electric dipole moment in atoms.

Keywords


Magnetometry, Oscillatory Fields, Precession Frequency, Ytterbium Atoms.



DOI: https://doi.org/10.18520/cs%2Fv109%2Fi3%2F592-595