A determination of H0 with the CLASS gravitational lens B1608+656: II. Mass models and the Hubble constant from lensing
Abstract
EDITED FROM PAPER: We present mass models of the four-image gravitational lens system B1608+656. A mass model for the lens galaxies has been determined that reproduces the image positions, two out of three flux-density ratios and the model time delays. Using the time delays determined by Fassnacht et al. (1999a), we find that the best isothermal mass model gives H0=59+7-6 km/s/Mpc for Omegam=1 and Omegal=0.0, or H0=(65-63)+7-6 km/s/Mpc for Omegam=0.3 and Omegal = 0.0-0.7 (95.4% statistical confidence). A systematic error of +/-15 km/s/Mpc is estimated. This cosmological determination of H0 agrees well with determinations from three other gravitational lens systems (i.e. B0218+357, Q0957+561 and PKS1830-211), SNe Ia, the S-Z effect and local determinations. The current agreement on H0 from four out of five gravitational lens systems (i) emphasizes the reliability of its determination from isolated gravitational lens systems and (ii) suggests that a close-to-isothermal mass profile can describe disk galaxies, ellipticals and central cluster ellipticals. The average of H0 from B0218+357, Q0957+561, B1608+656 and PKS1830-211, gives H0(GL)=69 +/-7 km/s/Mpc for a flat universe with Omegam=1 or H0(GL)=74 +/-8 km/s/Mpc for Omegam=0.3 and Omegal=0.0-0.7. When including PG1115+080, these values decrease to 64 +/-11 km/s/Mpc and 68 +/-13 km/s/Mpc (2-sigma errors), respectively.
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