Not exact matches
The original HUDF images were pioneering
deep - field
observations with the NASA / ESA Hubble
Space Telescope published in 2004.
The Hubble
Deep Field (HDF) is an image of a small region of the sky, based on the results of a series of
observations by the Hubble
Space Telescope.
The
Deep Space Network, managed by JPL, is an international network of antennas that supports interplanetary spacecraft missions and radio and radar astronomy
observations for the exploration of the solar system and the universe.
Multiple
observations indicate that the flowing water responsible for shaping and moving the rounded pebbles encountered in the vicinity of the rover landing area has long since been lost to
space, though some of it may still exist
deep below the surface of the planet at equatorial locations (water ice is known to exist near the surface at the poles).
Emma de Oña Wilhelmi from the Institute of
Space Sciences (IEEC - CSIC, Barcelona) and Principal Investigator of this
observation program says: «We performed
deep observation of the Crab pulsar with MAGIC to understand this phenomenon, expecting to measure the maximum energy of the pulsating photons.»
Notably, the
Deep Space Climate Observatory, an active mission launched in 2015 to provide planetwide
observations of Earth that has long ties to former Vice President Al Gore, would be terminated before its 5 - year mission was up.
«Previous
observations made by NASA's Hubble
Space Telescope and the Swift Gamma - Ray Burst Mission and
Deep Impact spacecraft gave us only upper limits for any gas emission from ISON.
While probing
space in depth — let us bear in mind that the further we look, the more we go back in time — ALMA detects the glow of tepid dust present in the most distant galaxies, i.e., the earliest ones, with better resolution than could be possible in the
deepest observations using visible or infrared light.
Most searches of objects
deep in
space require long time
observations using telescopes.
Photographed about eight days after it exploded, Supernova 1997ff (SN1997ff) was found by astronomers comparing the northern Hubble
Deep Field, a 10 - day
observation of a tiny region of sky first explored by the Hubble
Space Telescope in 1995, with a follow - up
observation in 1997.
The
observations showed that when the usual shallow cumulus clouds give way to the MJO's towering cumulonimbus storms, radiant heat trapped by clouds and moisture gradually warms a
deeper column of the lower atmosphere while the tops of the storms radiate heat into
space, cooling the upper troposphere.
Though many modeling studies have demonstrated the impact of
deep water formation changes on the overturning circulation, the observational evidence for such a linkage has been hard to come by for two reasons: (1) Deep water formation is difficult to quantify because the time and locale of production are highly variable from winter to winter, and (2) overturning circulation measures require observations that span the basin, which have been limited in space and t
deep water formation changes on the overturning circulation, the observational evidence for such a linkage has been hard to come by for two reasons: (1)
Deep water formation is difficult to quantify because the time and locale of production are highly variable from winter to winter, and (2) overturning circulation measures require observations that span the basin, which have been limited in space and t
Deep water formation is difficult to quantify because the time and locale of production are highly variable from winter to winter, and (2) overturning circulation measures require
observations that span the basin, which have been limited in
space and time.