TY - JOUR
T1 - Radio galaxies and the acceleration of the universe beyond a redshift of one
AU - Daly, Ruth A.
N1 - Funding Information:
It is a pleasure to thank Joel Carvalho, George Djorgovski, Megan Donahue, Jean Eilek, Eddie Guerra, Paddy Leahy, Alan Marscher, Matt Mory, Chris O’Dea, Bharat Ratra, and Adam Reiss for helpful comments and discussions. This work was supported in part by US National Science Foundation Grant Nos. AST 00-96077 and AST 02-06002, by a Chandra X-ray Center data analysis Grant No. G01-2129B, and by Penn State University. The Chandra X-ray Observatory Science Center (CXC) is operated for NASA by the Smithsonian Astrophysical Observatory.
PY - 2005
Y1 - 2005
N2 - Radio galaxies provide a means to determine the coordinate distance, the luminosity distance, the dimension-less luminosity distance, or the angular size distance to sources with redshifts as large as two. Dimensionless coordinate distances for 55 supernovae and 20 radio galaxies are presented and discussed here. The radio galaxy results are consistent with those obtained using supernovae, suggesting that neither method is plagued by unknown systematic errors. The acceleration parameter q(z) and the expansion rate H(z) or dimensionless expansion rate E(z) can be determined directly from the data without having to make assumptions regarding the nature or evolution of the "dark energy". The expansion rate E(z) can be determined from the first derivative of the dimensionless coordinate distance, (dy/dz) -1 , and the acceleration parameter can be determined from a combination of the first and second derivatives of the dimensionless coordinate distance. A model-independent determination of E(z) will allow the properties and redshift evolution of the "dark energy" to be determined, and a model-independent determination of q(z) will allow the redshift at which the universe transitions from acceleration to deceleration to be determined directly. Determination of E(z) and q(z) may also elucidate possible systematic errors in the determinations of the dimensionless coordinate distances.
AB - Radio galaxies provide a means to determine the coordinate distance, the luminosity distance, the dimension-less luminosity distance, or the angular size distance to sources with redshifts as large as two. Dimensionless coordinate distances for 55 supernovae and 20 radio galaxies are presented and discussed here. The radio galaxy results are consistent with those obtained using supernovae, suggesting that neither method is plagued by unknown systematic errors. The acceleration parameter q(z) and the expansion rate H(z) or dimensionless expansion rate E(z) can be determined directly from the data without having to make assumptions regarding the nature or evolution of the "dark energy". The expansion rate E(z) can be determined from the first derivative of the dimensionless coordinate distance, (dy/dz) -1 , and the acceleration parameter can be determined from a combination of the first and second derivatives of the dimensionless coordinate distance. A model-independent determination of E(z) will allow the properties and redshift evolution of the "dark energy" to be determined, and a model-independent determination of q(z) will allow the redshift at which the universe transitions from acceleration to deceleration to be determined directly. Determination of E(z) and q(z) may also elucidate possible systematic errors in the determinations of the dimensionless coordinate distances.
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U2 - 10.1016/j.asr.2003.08.045
DO - 10.1016/j.asr.2003.08.045
M3 - Article
AN - SCOPUS:18444407821
SN - 0273-1177
VL - 35
SP - 116
EP - 121
JO - Advances in Space Research
JF - Advances in Space Research
IS - 1
ER -