Your search keyword '"microwave absorber clouds"' showing total 2 results

1. Frequency–Redshift Relation of the Cosmic Microwave Background.

Author

Hofmann, Ralf and Meinert, Janning

Subjects

COSMIC background radiation, REDSHIFT, MOLECULAR rotation, ENERGY conservation, MATHEMATICAL functions

Abstract

We point out that a modified temperature–redshift relation (T-z relation) of the cosmic microwave background (CMB) cannot be deduced by any observational method that appeals to an a priori thermalisation to the CMB temperature T of the excited states in a probe environment of independently determined redshift z. For example, this applies to quasar-light absorption by a damped Lyman-alpha system due to atomic as well as ionic fine-splitting transitions or molecular rotational bands. Similarly, the thermal Sunyaev-Zel'dovich (thSZ) effect cannot be used to extract the CMB's T-z relation. This is because the relative line strengths between ground and excited states in the former and the CMB spectral distortion in the latter case both depend, apart from environment-specific normalisations, solely on the dimensionless spectral variable x = h ν k B T . Since the literature on extractions of the CMB's T-z relation always assumes (i) ν (z) = (1 + z) ν (z = 0) , where ν (z = 0) is the observed frequency in the heliocentric rest frame, the finding (ii) T (z) = (1 + z) T (z = 0) just confirms the expected blackbody nature of the interacting CMB at z > 0 . In contrast to the emission of isolated, directed radiation, whose frequency–redshift relation (ν -z relation) is subject to (i), a non-conventional ν -z relation ν (z) = f (z) ν (z = 0) of pure, isotropic blackbody radiation, subject to adiabatically slow cosmic expansion, necessarily has to follow that of the T-z relation T (z) = f (z) T (z = 0) and vice versa. In general, the function f (z) is determined by the energy conservation of the CMB fluid in a Friedmann–Lemaitre–Robertson–Walker universe. If the pure CMB is subject to an SU(2) rather than a U(1) gauge principle, then f (z) = 1 / 4 1 / 3 (1 + z) for z ≫ 1 , and f (z) is non-linear for z ∼ 1 . [ABSTRACT FROM AUTHOR]

Published

2023

2. Frequency–Redshift Relation of the Cosmic Microwave Background

Author

Ralf Hofmann and Janning Meinert

Subjects

thermal ground state, thermal Sunyaev-Zel’dovich effect, microwave absorber clouds, cosmic microwave background, Astronomy, QB1-991

Abstract

We point out that a modified temperature–redshift relation (T-z relation) of the cosmic microwave background (CMB) cannot be deduced by any observational method that appeals to an a priori thermalisation to the CMB temperature T of the excited states in a probe environment of independently determined redshift z. For example, this applies to quasar-light absorption by a damped Lyman-alpha system due to atomic as well as ionic fine-splitting transitions or molecular rotational bands. Similarly, the thermal Sunyaev-Zel’dovich (thSZ) effect cannot be used to extract the CMB’s T-z relation. This is because the relative line strengths between ground and excited states in the former and the CMB spectral distortion in the latter case both depend, apart from environment-specific normalisations, solely on the dimensionless spectral variable x=hνkBT. Since the literature on extractions of the CMB’s T-z relation always assumes (i) ν(z)=(1+z)ν(z=0), where ν(z=0) is the observed frequency in the heliocentric rest frame, the finding (ii) T(z)=(1+z)T(z=0) just confirms the expected blackbody nature of the interacting CMB at z>0. In contrast to the emission of isolated, directed radiation, whose frequency–redshift relation (ν-z relation) is subject to (i), a non-conventional ν-z relation ν(z)=f(z)ν(z=0) of pure, isotropic blackbody radiation, subject to adiabatically slow cosmic expansion, necessarily has to follow that of the T-z relation T(z)=f(z)T(z=0) and vice versa. In general, the function f(z) is determined by the energy conservation of the CMB fluid in a Friedmann–Lemaitre–Robertson–Walker universe. If the pure CMB is subject to an SU(2) rather than a U(1) gauge principle, then f(z)=1/41/3(1+z) for z≫1, and f(z) is non-linear for z∼1.

Published

2023