HD as a probe for detecting mass variation on a cosmological time scale

HD as a probe for detecting mass variation on a cosmological time scale

The strong electronic absorption systems of the B1 Sigma u+-X1 Sigma g+ Lyman and the C1Pi u-X1 Sigma g+ Werner bands can be used to probe possible mass-variation effects on a cosmological time scale from spectra observed at high redshift, not only in H2 but also in the second most abundant hydrogen...

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Veröffentlicht in:Physical review letters 2008-03, Vol.100 (9), p.093007-093007, Article 093007
Hauptverfasser: Ivanov, T I, Roudjane, M, Vieitez, M O, de Lange, C A, Tchang-Brillet, W-U L, Ubachs, W
Format: Artikel
Sprache:eng
Schlagworte:
ABSORPTION
ACCURACY
ASTROPHYSICS
COMPARATIVE EVALUATIONS
ELECTRONS
EXTREME ULTRAVIOLET RADIATION
HYDROGEN
MASS
Physics
PHYSICS OF ELEMENTARY PARTICLES AND FIELDS
PROTONS
RED SHIFT
RESOLUTION
SPECTRA
WAVELENGTHS
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Beschreibung
Zusammenfassung:The strong electronic absorption systems of the B1 Sigma u+-X1 Sigma g+ Lyman and the C1Pi u-X1 Sigma g+ Werner bands can be used to probe possible mass-variation effects on a cosmological time scale from spectra observed at high redshift, not only in H2 but also in the second most abundant hydrogen isotopomer HD. High resolution laboratory determination of the most prominent HD lines at extreme ultraviolet wavelengths is performed at an accuracy of delta lambda/lambda approximately 5 x 10(-8), forming a database for comparison with astrophysical data. Sensitivity coefficients Ki = d ln lambda i/d ln mu are determined for HD from quantum ab initio calculations as a function of the proton-electron mass ratio mu. Strategies to deduce possible effects beyond first-order baryon/lepton mass ratio deviations are discussed.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.100.093007