This title appears in the Scientific Report :
2022
Please use the identifier:
http://hdl.handle.net/2128/33360 in citations.
Please use the identifier: http://dx.doi.org/10.7566/JPSCP.37.021209 in citations.
New Application of a Sona Transition Unit: Observation of Direct Transitions between Quantum States with Energy Differences of 10 neV and Below
New Application of a Sona Transition Unit: Observation of Direct Transitions between Quantum States with Energy Differences of 10 neV and Below
For more than 50 years Sona transition units have been used at polarized sources to exchange the occupation numbers between “pure” hyperfine substates. For instance, hydrogen atoms in the hyperfine substate |F=1,mF=+1⟩ are transferred into |F=1,mF=−1⟩when these atoms are passing a static magnetic fi...
Saved in:
Personal Name(s): | Kannis, Chrysovalantis S. (Corresponding author) |
---|---|
Engels, Ralf W. / Hanhart, Christoph / Soltner, Helmut / Huxold, Lukas / Grigoryev, Kirill / Lehrach, Andreas / Büscher, Markus / Sefzick, Thomas | |
Contributing Institute: |
Zentralinstitut für Technologie; ZEA-1 Zentralinstitut für Elektronik; ZEA-2 Elektronische Eigenschaften; PGI-6 Kernphysikalische Großgeräte; IKP-4 Experimentelle Hadrondynamik; IKP-2 |
Published in: |
Proceedings of the 24th International Spin Symposium (SPIN2021) - Journal of the Physical Society of Japan, 2022. - ISBN 4-89027-150-3 - doi:10.7566/JPSCP.37.021209 |
Imprint: |
Journal of the Physical Society of Japan
2022
|
Physical Description: |
021209 |
DOI: |
10.7566/JPSCP.37.021209 |
Conference: | 24th International Spin Symposium (SPIN2021), Matsue (Japan (Hybrid)), 2021-10-18 - 2021-10-22 |
Document Type: |
Contribution to a book Contribution to a conference proceedings |
Research Program: |
Cosmic Matter in the Laboratory Accelerator Research and Development |
Subject (ZB): | |
Link: |
OpenAccess |
Publikationsportal JuSER |
Please use the identifier: http://dx.doi.org/10.7566/JPSCP.37.021209 in citations.
For more than 50 years Sona transition units have been used at polarized sources to exchange the occupation numbers between “pure” hyperfine substates. For instance, hydrogen atoms in the hyperfine substate |F=1,mF=+1⟩ are transferred into |F=1,mF=−1⟩when these atoms are passing a static magnetic field gradient between two opposing solenoidal magnetic fields. Thus, the magnetic field direction, i.e., the quantization axis, is rotated faster than the spin orientation can follow due to the Larmor precession.In parallel, the atoms traveling through the zero crossing of the static magnetic field experience in their rest frame an oscillating magnetic field. This oscillation is equivalent to an external radio frequency field of frequency f=vatom/λthat can induce transitions between hyperfine substates with the energy difference ΔE=n⋅h⋅f, where n is an integer. Here, the distance between the opposite coils determines the wavelength λ, thus the beam velocity vatom can be used to manipulate the frequency f to induce transitions between quantum states with energy differences of 10 neV and below. These tiny energy differences can be found between hyperfine substates of hydrogen atoms at low magnetic fields in the Breit–Rabi diagram. Here first measurements, their interpretation and possible applications are presented. |