论文信息 - Hubble Space Telescope STIS Observations of GRB 000301C: CCD Imaging and Near-Ultraviolet MAMA Spectroscopy - 字舞流文

Hubble Space Telescope STIS Observations of GRB 000301C: CCD Imaging and Near-Ultraviolet MAMA Spectroscopy

We present Space Telescope Imaging Spectrograph observations of the optical transient (OT) counterpart of the γ-ray burster GRB 000301C obtained 5 days after the burst, on 2000 March 6. CCD clear-aperture imaging reveals a R ≃ 21.50 ± 0.15 source with no apparent host galaxy. An 8000 s, 1150 Å < λ < 3300 Å near-ultraviolet MAMA prism spectrum shows a flat or slightly rising continuum (in fλ) between 2800 and 3300 Å, with a mean flux of × 10-18 ergs s-1 cm-2 Å-1, and a sharp break centered at 2797 ± 25 Å. We interpret this as the H I Lyman break at z = 2.067 ± 0.025, indicating the presence of a cloud with an H I column density log N > 18 on the line of sight to the OT. This measured redshift is conservatively a lower limit to the GRB redshift. However, as all other GRBs that have deep Hubble Space Telescope images appear to lie on the stellar field of a host galaxy, and as the large H I column density measured here and in later ground-based observations is unlikely on a random line of sight, we believe we are probably seeing absorption from H I in the host galaxy. In any case, this represents the largest direct redshift determination of a γ-ray burster to date. Our data are compatible with an OT spectrum represented by a power law with an intrinsic index α = 1.2 (fν ∝ ν-α) and no extinction in the host galaxy, or with α = 0.5 and extinction by SMC-like dust in the OT rest frame with AV = 0.15. The large N and the lack of a detected host are similar to the situation for damped Lyα absorbers at z > 2.

Alan M. Levine | B. L. Jensen | Mark R. Metzger | Henry C. Ferguson | James E. Rhoads | David W. Hogg | Kailash C. Sahu | Don J. Lindler | Alain Smette | J. Gorosabel | Theodore R. Gull | Johan P. U. Fynbo | R. Gibbons | T. L. Cline | Mario Livio | Andrew S. Fruchter | Jens Hjorth | Stephen E. Thorsett | Kevin Hurley | Holger Pedersen | Jack I. Trombka | Larry Petro | Elena Pian | D. Hogg | M. Livio | J. Hjorth | A. Fruchter | J. Gorosabel | B. Jensen | C. Kouveliotou | E. Pian | H. Ferguson | J. Rhoads | A. Levine | K. Sahu | K. Hurley | D. Lindler | T. Cline | H. Pedersen | R. Wijers | M. Metzger | L. Petro | S. Thorsett | A. Smette | J. Fynbo | T. Gull | Chryssa Kouveliotou | D. A. Smith | D. Macchetto | Ralph A. M. J. Wijers | J. Trombka | D. Macchetto | Donald A. Smith | R. Gibbons

[1] H. Nicklas,et al. VLT Spectroscopy of GRB 990510 and GRB 990712: Probing the Faint and Bright Ends of the Gamma-Ray Burst Host Galaxy Population , 2000, astro-ph/0009025.

[2] K. Z. Stanek,et al. Resolving Gamma-Ray Burst 000301C with a Gravitational Microlens , 2000, astro-ph/0008049.

[3] J. Fynbo,et al. The afterglow of the short/intermediate-duration gamma-ray burst GRB 000301C: A jet at z = 2:04 ?;??;??? , 2000, astro-ph/0005609.

[4] D. Frail,et al. A Jet Model for the Afterglow Emission from GRB 000301C , 2000, astro-ph/0005465.

[5] A. Fruchter,et al. The Near-Infrared and Multiwavelength Afterglow of GRB 000301C , 2000, astro-ph/0004057.

[6] B. Draine. Gamma-Ray Bursts in Molecular Clouds: H2 Absorption and Fluorescence , 2000 .

[7] M. Steinmetz,et al. Damped Lyα Absorber and the Faint End of the Galaxy Luminosity Function at High Redshift , 1999, astro-ph/9911447.

[8] E. Mazets,et al. Localizations of 13 Gamma-Ray Bursts by the All-Sky Monitor on the Rossi X-Ray Timing Explorer , 1999 .

[9] D. Turnshek,et al. Discovery of DampedLyα Systems at Redshifts Less than 1.65 and Results on Their Incidence and Cosmological Mass Density , 1999, astro-ph/9909164.

[10] B. Draine,et al. Dust Sublimation by Gamma-ray Bursts and Its Implications , 1999, astro-ph/9909020.

[11] B. Draine. H_2 Absorption and Fluorescence for Gamma Ray Bursts in Molecular Clouds , 1999, astro-ph/9907232.

[12] D. Hogg,et al. Hubble Space Telescope and Palomar Imaging of GRB 990123: Implications for the Nature of Gamma-Ray Bursts and Their Hosts , 1999, astro-ph/9902236.

[13] S. Djorgovski,et al. The Host Galaxy of GRB 990123 , 1999, astro-ph/9902182.

[14] H. Ferguson,et al. The Lyα Forest of the Quasar in the Hubble Deep Field South , 1999, astro-ph/9901022.

[15] D. Hogg,et al. The Faint-Galaxy Hosts of Gamma-Ray Bursts , 1998, astro-ph/9807262.

[16] S. Warren,et al. Extended Lyα emission from a damped Ly α absorber at z=1.93, and the relation between damped Ly α absorbers and Lyman-break galaxies , 1998, astro-ph/9812434.

[17] Lee D. Feinberg,et al. The Space Telescope Imaging Spectrograph Design , 1998 .

[18] Caltech,et al. Spectroscopy of the Host Galaxy of the Gamma-Ray Burst 980703 , 1998, astro-ph/9808188.

[19] S. Djorgovski,et al. The Host Galaxy of GRB 970508 , 1998, astro-ph/9807315.

[20] M. Livio,et al. The Fading Optical Counterpart of GRB 970228, 6 Months and 1 Year Later , 1998, astro-ph/9807295.

[21] D. Schlegel,et al. Maps of Dust Infrared Emission for Use in Estimation of Reddening and Cosmic Microwave Background Radiation Foregrounds , 1998 .

[22] S. Djorgovski,et al. Identification of a host galaxy at redshift z = 3.42 for the γ-ray burst of 14 December 1997 , 1998, Nature.

[23] Lee D. Feinberg,et al. The On-Orbit Performance of the Space Telescope Imaging Spectrograph , 1998, Astronomical Telescopes and Instrumentation.

[24] T. Piran,et al. Spectra and Light Curves of Gamma-Ray Burst Afterglows , 1997, astro-ph/9712005.

[25] B. Paczyński. Are Gamma-Ray Bursts in Star-Forming Regions? , 1997, astro-ph/9710086.

[26] M. Steinmetz,et al. Damped Lyα Absorber at High Redshift: Large Disks or Galactic Building Blocks? , 1997, astro-ph/9706201.

[27] S. Djorgovski,et al. Spectral constraints on the redshift of the optical counterpart to the γ-ray burst of 8 May 1997 , 1997, Nature.

[28] L. A. Antonelli,et al. Discovery of an X-ray afterglow associated with the γ-ray burst of 28 February 1997 , 1997, Nature.

[29] L. A. Antonelli,et al. Discovery of the X-Ray Afterglow of the Gamma-Ray Burst of February 28 1997 , 1997, astro-ph/9706065.

[30] M. Livio,et al. The optical counterpart to γ-ray burst GRB970228 observed using the Hubble Space Telescope , 1997, Nature.

[31] C. Kouveliotou,et al. Transient optical emission from the error box of the γ-ray burst of 28 February 1997 , 1997, Nature.

[32] D. Weinberg,et al. The Population of Damped Lyα and Lyman Limit Systems in the Cold Dark Matter Model , 1996, astro-ph/9609072.

[33] S. Djorgovski,et al. Identification of a galaxy responsible for a high-redshift Lyman-α absorption system , 1996, Nature.

[34] Armando Blanco,et al. On the Interstellar Extinction Hump and Laboratory Carbonaceous Grains , 1996 .

[35] S. Djorgovski,et al. Identification of a Galaxy Responsible for a High-Redshift Damped Ly α Absorption System , 1996 .

[36] C. Hogan,et al. Imaging and Spectroscopy of Damped LY alpha Quasi-stellar Object Absorption-Line Clouds , 1995 .

[37] C. Steidel,et al. The Hubble Space Telescope quasar absorption line key project. v. redshift evolution of lyman limit absorption in the spectra of a large sample of quasars , 1995 .

[38] N. Suntzeff,et al. The Distances to Five Type~II Supernovae Using the Expanding Photosphere Method and the Value of $H_0$ , 1994, astro-ph/9407098.

[39] P. Mészáros,et al. Spectral properties of blast-wave models of gamma-ray burst sources , 1993, astro-ph/9311071.

[40] Y. Pei,et al. Interstellar dust from the Milky Way to the Magellanic Clouds , 1992 .

[41] T. Piran,et al. Gamma-ray bursts as the death throes of massive binary stars , 1992, astro-ph/9204001.

[42] C. Kouveliotou,et al. Spatial distribution of γ-ray bursts observed by BATSE , 1992, Nature.

[43] Bohdan Paczynski,et al. Cosmological gamma-ray bursts , 1991 .

[44] R. Klebesadel,et al. Observations of Gamma-Ray Bursts of Cosmic Origin , 1973 .