Prior to this survey, astronomers were in a curious position. They knew a lot about star formation occurring in nearby galaxies thanks to UV telescope facilities such as NASA's Galex observatory, which operated from 2003 to 2013. And, thanks to Hubble's near-infrared and visible capability, they had also studied star birth in the most distant galaxies. We see these distant galaxies in their most primitive stages due to the vast amount of time it takes their light to reach us.
However, between 5 and 10 billion light-years away from us -- corresponding to a time period when most of the stars in the Universe were born -- there was a lack of the data needed to fully understand star formation. The hottest, most massive and youngest stars, which emit light in the ultraviolet, were often neglected as subjects of direct observation, leaving a significant gap in our knowledge of the cosmic timeline.
The addition of ultraviolet data to the Hubble Ultra Deep Field using Hubble's Wide Field Camera 3 gives astronomers access to direct observations of regions of unobscured star formation and may help us to fully understand how stars formed. By observing at these wavelengths, researchers get a direct look at which galaxies are forming stars and, just as importantly, where the stars are forming. This enables astronomers to understand how galaxies like the Milky Way grew in size from small collections of very hot stars to the massive structures they are today.
The patch of sky in this image has been previously studied by astronomers in a series of visible and near-infrared exposures taken from 2004 to 2009: the Hubble Ultra Deep Field. Now, with the addition of ultraviolet light, they have combined the full range of colours available to Hubble, stretching all the way from ultraviolet to near- infrared light. The resulting image, made from 841 orbits of telescope viewing time, contains approximately 10 000 galaxies, extending back to within a few hundred million years of the Big Bang.
Since the Earth's atmosphere filters most ultraviolet light, this work can only be accomplished with a space-based telescope like Hubble. Ultraviolet surveys like this are incredibly important in planning for the James Webb Space Telescope (JWST) as Hubble is the only telescope currently able to obtain the ultraviolet data that researchers will need to combine with infrared data from JWST.
Notes for editors
The team responsible for this data consists of H. Teplitz and M. Rafelski (IPAC/Caltech), P. Kurczynski (Rutgers University), N. Bond (Goddard Space Flight Center), E. Soto (Catholic University), N. Grogin and A. Koekemoer (STScI), H. Atek (Ecole Polytechnique Federale de Lausanne, Switzerland), T. Brown and D. Coe (STScI), J. Colbert and Y. Dai (IPAC/Caltech), H. Ferguson (STScI), S. Finkelstein (University of Texas, Austin), J. Gardner (Catholic University), E. Gawiser (Rutgers University), M. Giavalisco (University of Massachusetts, Amherst), C. Gronwall (Penn State University), D. Hanish (IPAC/Caltech), K.-S. Lee (Perdue University), Z. Levay (STScI), D. De Mello (Catholic University), S. Ravindranath and R. Ryan (STScI), B. Siana (University of California, Riverside), C. Scarlata (University of Minnesota, Minneapolis), E. Voyer (CNRS, Marseille), and R. Windhorst (Arizona State University).
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