Rubidium spectroscopy at high-pressure buffer gas conditions: detailed balance in the optical interaction of an absorber coupled to a reservoir
Optical spectroscopy of atoms and molecules is a field where one usually operates very far from thermal equilibrium conditions. A prominent example is spectroscopy of thin vapors, where the pump irradiation leads to a non equilibrium distribution within the electronic structure that is well shielded...
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| Main Authors | , , , , , , , |
| Format | Paper Journal Article |
| Language | English |
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28.11.2019
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| Abstract | Optical spectroscopy of atoms and molecules is a field where one usually operates very far from thermal equilibrium conditions. A prominent example is spectroscopy of thin vapors, where the pump irradiation leads to a non equilibrium distribution within the electronic structure that is well shielded from the environment. Here we describe experimental work investigating absorption and emission lines of rubidium vapor subject to a noble buffer gas environment with pressure 100 to 200 bar, a regime interpolating between usual gas phase and liquid solid state conditions. Frequent elastic collisions in the dense buffer gas sample cause a large coupling to the environment. We give a detailed account of recent observations of the Kennard Stepanov scaling, a Boltzmann like thermodynamic frequency scaling between absorption and emission profiles, for both atomic and molecular rubidium species in the gaseous environment. Our observations are interpreted as due to the thermalization of alkali noble gas submanifolds in both ground and electronically excited states respectively. Both pressure broadening and shift of the high pressure buffer gas D lines system are determined. We also discuss some prospects, including possible advances in collisional laser cooling and optical thermometry. |
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| AbstractList | Physica Scripta, Volume 93, Number 12, 2018 Optical spectroscopy of atoms and molecules is a field where one usually
operates very far from thermal equilibrium conditions. A prominent example is
spectroscopy of thin vapors, where the pump irradiation leads to a non
equilibrium distribution within the electronic structure that is well shielded
from the environment. Here we describe experimental work investigating
absorption and emission lines of rubidium vapor subject to a noble buffer gas
environment with pressure 100 to 200 bar, a regime interpolating between usual
gas phase and liquid solid state conditions. Frequent elastic collisions in the
dense buffer gas sample cause a large coupling to the environment. We give a
detailed account of recent observations of the Kennard Stepanov scaling, a
Boltzmann like thermodynamic frequency scaling between absorption and emission
profiles, for both atomic and molecular rubidium species in the gaseous
environment. Our observations are interpreted as due to the thermalization of
alkali noble gas submanifolds in both ground and electronically excited states
respectively. Both pressure broadening and shift of the high pressure buffer
gas D lines system are determined. We also discuss some prospects, including
possible advances in collisional laser cooling and optical thermometry. Optical spectroscopy of atoms and molecules is a field where one usually operates very far from thermal equilibrium conditions. A prominent example is spectroscopy of thin vapors, where the pump irradiation leads to a non equilibrium distribution within the electronic structure that is well shielded from the environment. Here we describe experimental work investigating absorption and emission lines of rubidium vapor subject to a noble buffer gas environment with pressure 100 to 200 bar, a regime interpolating between usual gas phase and liquid solid state conditions. Frequent elastic collisions in the dense buffer gas sample cause a large coupling to the environment. We give a detailed account of recent observations of the Kennard Stepanov scaling, a Boltzmann like thermodynamic frequency scaling between absorption and emission profiles, for both atomic and molecular rubidium species in the gaseous environment. Our observations are interpreted as due to the thermalization of alkali noble gas submanifolds in both ground and electronically excited states respectively. Both pressure broadening and shift of the high pressure buffer gas D lines system are determined. We also discuss some prospects, including possible advances in collisional laser cooling and optical thermometry. |
| Author | ge, Ralf Weller, Lars Ockenfels, Till Vewinger, Frank Christopoulos, Stavros Moroshkin, Peter Gerwers, Benedikt Weitz, Martin |
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| BackLink | https://doi.org/10.1088/1402-4896/aae723$$DView published paper (Access to full text may be restricted) https://doi.org/10.48550/arXiv.1911.12586$$DView paper in arXiv |
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| DOI | 10.48550/arxiv.1911.12586 |
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| SubjectTerms | Absorption Buffers Coupling (molecular) D lines Elastic scattering Electronic structure Emission analysis Equilibrium conditions Gas sampling Laser cooling Manifolds (mathematics) Physics - Atomic and Molecular Clusters Physics - Atomic Physics Pressure broadening Rare gases Rubidium Spectrum analysis Thermalization (energy absorption) Vapor phases |
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| Title | Rubidium spectroscopy at high-pressure buffer gas conditions: detailed balance in the optical interaction of an absorber coupled to a reservoir |
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