Here is a timeline of upcoming events (all times in GMT):
TIME...........EVENT
July 4
03:30......NASA television coverage begins 03:53......Start impactor auto-navigation imaging 04:21......Impactor trajectory manoeuvre No. 1 05:17 .....Impactor trajectory manoeuvre No. 2 05:39......Impactor trajectory manoeuvre No. 3 05:52......Impact 06:05......Flyby reorients to shield mode for close approach 06:06......Flyby closest approach (311 miles) 06:51......Flyby first post-impact image 06:00......Post-impact news briefing on NASA TV 06:00......Deep Impact news conference on NASA TV
NASA's Deep Impact spacecraft successfully released its impactor at 0707 GMT (2:07 am EST).
At release, the impactor was about 880,000 kilometres away from its quarry. The separation of flyby spacecraft and the washing-machine-sized, copper-fortified impactor is one in a series of important mission milestones that will cap off with a planned encounter with the comet at 05:52 GMT (1:52 a.m. on July 4, EDT).
Six hours prior to impactor release, the Deep Impact spacecraft successfully performed its fourth trajectory correction manoeuvre. The 30-second burn changed the spacecraft's velocity by about one kilometre per hour. The goal of the burn is to place the impactor as close as possible to the direct path of onrushing comet Tempel 1.
Soon after the trajectory manoeuvre was completed, the impactor engineers began the final steps that would lead to it being ready for free flight. The plan culminated with activation of the impactor's batteries at 05:12 GMT (1:12 a.m. Sunday, EDT). Deep Impact's impactor has no solar cells; the vehicle's batteries are expected to provide all the power required for its short day-long life.
In order to release the impactor, separation pyros fired allowing a spring to uncoil and separate the two spacecraft at a speed of about 35 centimetres per second. With Tempel 1 closing the distance between it and impactor at about 10 kilometres per second, there is little time for mission controllers to admire their work. Twelve minutes after impactor release the flyby began a 14-minute long divert burn that slowed its velocity relative to the impactor by 102 metres per second, moving it out of the path of the onrushing comet nucleus and setting the stage for a ringside seat of celestial fireworks to come less than 24 hours later.
Deep Impact mission controllers have confirmed the impactor's S-band antenna is talking to the flyby spacecraft. All impactor data including the expected remarkable images of its final dive into the comet's nucleus will be transmitted to the flyby craft -- which will then downlink them to Deep Space Network antennas that are listening 134 million kilometres away. While all is going as expected on the Deep Impact spacecraft the comet itself is putting on something of a show. The 14-kilometer-long comet Tempel 1 displayed another cometary outburst on July 2 when a massive, short-lived blast of ice or other particles escaped from inside the comet's nucleus and temporarily expanded the size and reflectivity of the cloud of dust and gas (coma) that surrounds it. The July 2 outburst is the fourth observed in the past three weeks. Three of the outbursts appear to have originated from the same area on the surface of the nucleus but they do not occur every time that that area faces the Sun.
"The comet is definitely full of surprises so far and probably has a few more in store for us. None of this overly concerns us nor has it forced us to modify our nominal mission plan." - Rick Grammier, Deep Impact Project Manager of NASA's Jet Propulsion Laboratory, Pasadena.
A picture of Tempel 1(left) taken by Deep Impact's medium-resolution camera is shown next to data of the comet taken by the spacecraft's infrared spectrometer. This instrument breaks apart light like a prism to reveal the "fingerprints," or signatures, of chemicals. Even though the spacecraft was over 10 days away from the comet when these data were acquired, it detected some of the molecules making up the comet's gas and dust envelope, or coma. The signatures of these molecules - including water, hydrocarbons, carbon dioxide and carbon monoxide - can be seen in the graph, or spectrum.
Image credit: NASA/JPL-Caltech/UMD
Deep Impact's impactor spacecraft is scheduled to collide with Tempel 1 at 10:52 p.m. Pacific time on July 3 (1:52 a.m. Eastern time, July 4). The mission's flyby spacecraft will use its infrared spectrometer to sample the ejected material, providing the first look at the chemical composition of a comet's nucleus. These data were acquired from June 20 to 21, 2005. The picture of Tempel 1 was taken by the flyby spacecraft's medium-resolution instrument camera. The infrared spectrometer uses the same telescope as the high-resolution instrument camera.
Swift's ultraviolet telescope recorded this picture of Tempel 1 on June 29th. Because the image is registered on the comet, the background stars appear as short trails.
If you're using small telescope (4” scope) seeing a magnitude 10 comet is similar to seeing small magnitude 10 galaxy.
So use averted vision and lower powers.
Plan ahead of the event, to setup in good time; and that basically means going to a dark sky site. The cloud of debris may take several hours to form and so European observers may actually get a better view of the event than observers around the Pacific ocean.
It may actually be bright enough to be a naked eye object. but i suspect it will only be bright enough for binoculars.
But then again, there may not be a large debris cloud formed - or NASA could miss…
The Deep Impact spacecraft continues to close on Comet Tempel 1, a comet roughly the size of Manhattan. Early on July 3 (EDT), the Deep Impact spacecraft will separate in to two individual robotic spaceships, one called Flyby and the other called Impactor. During the next 24 hours, both Flyby and Impactor will fire rockets and undergo complex manoeuvres in preparation for Impactor's planned collision with Comet Tempel 1.
On July 4 (1:52 am EDT) if everything goes as scheduled, the 370-kilogram Impactor will strike Tempel 1's surface at over 14,000 kilometres per hour. Impactor will attempt to photograph the oncoming comet right up to the time of collision, while Flyby photographs the result from nearby. The above image was taken on 19 June from about 13 million kilometres out and used to help identify the central nucleus of the comet inside the diffuse coma. Telescopes around the Earth, including the Hubble Space Telescope, will also be closely watching the distant silent space ballet. The result may give crucial information about the structure of comets and the early history of our Solar System.
NASA's Deeep Impact spacecraft have observed a massive, short-lived outburst of ice or other particles from comet Tempel 1 that temporarily expanded the size and reflectivity of the cloud of dust and gas (coma) that surrounds the comet nucleus.
The outburst, which was detected as a dramatic brightening of the comet on June 22, is the second of two such events observed in the past two weeks. A smaller outburst was seen on June 14 by ground-based observers, the Hubble Space Telescope and Deep Impact.
The raw images of the medium resolution imager on the Deeep Impact spacecraft from June 22 - June 24, 2005 are displayed in this movie. A brightening by a factor of about 5 and rapid decay to baseline brightness can be seen on June 22. As the comet moves through space, background stars pass into and out of the field of view, and cosmic rays hitting the detector give an appearance of flickering, that is an artefact of space cameras that remain to be removed.
"This most recent outburst was six times larger than the one observed on June 14, but the ejected material dissipated almost entirely within about a half day" - Astronomer Michael A'Hearn, University of Maryland, leader of the Deep Impact mission.
A'Hearn noted that data from the spectrometer aboard the spacecraft showed that during the June 22 outburst, the amount of water vapour in the coma doubled, while the amount of other gases, including carbon dioxide, increased even more.
"Outbursts such as this may be a very common phenomenon on many comets, but they are rarely observed in sufficient detail to understand them because it is normally so difficult to obtain enough time on telescopes to discover such phenomena. We likely would have missed this exciting event, except that we are now getting almost continuous coverage of the comet with the spacecraft's imaging and spectroscopy instruments" - Michael A'Hearn.
Deep Impact co-investigator Jessica Sunshine, with Science Applications International Corporation (SAIC), agreed that observing such activity twice in one week suggests outbursts are fairly common.
"We must now consider them as a significant part of the processing that occurs on comets as they heat up when approaching the sun. The spectrometer is working very well and we already are able to see changes in the make up of the fresh material extruded from the comet. We are still a long way from the comet, so this bodes very well for our ability to observe and characterize changes in the comet's materials, before, during, and after our impact " - Jessica Sunshine, who leads the analysis of data from the spectrometer.
Science team member Tony Farnham, also of the University of Maryland, noted that although the duration (less than 18 hours) of both outburst events was comparable, the June 22 event was much more spectacular, exhibiting intricate features in the coma where material was blown off the surface. A'Hearn and other mission scientists say that most outbursts are believed to be associated with the heating of comet material by the Sun. Comet Tempel 1 is near perihelion, or the point in its orbit at which it is closest to the Sun.
"For the June 22 event, it is the rapid dispersal of this outburst that raises the most questions. It looks as though the puff was nearly instantaneous and that simple radial expansion is not enough to make the brightness go down as fast as it did. Thus the particles must also either be vaporizing, and thus disappearing, or getting much darker after release, and 'disappearing' in that way" - Michael A'Hearn
"This adds to the level of excitement as we come down to the final days before encounter. But this comet outburst will require no modification to mission plan and in no way affects spacecraft safety." - Rick Grammier, Deep Impact project manager at NASA's Jet Propulsion Lab.
Deep Impact - which consists of a sub-compact-car-sized flyby spacecraft and an impactor spacecraft about the size of a washing machine - carries a spectrometer and three imaging instruments. The three imaging instruments, two on the flyby spacecraft and one on the impactor, are essentially digital cameras connected to telescopes. The spectrometer is on the flyby spacecraft and uses the same telescope as the flyby's high-resolution imager. A spectrometer takes light that is emitted, absorbed, or scattered by materials (such as the dust and gas of the comet) and breaks it into its component wavelengths, or spectrum. It does this in much the same way that a prism breaks visible light into its component spectrum: red, orange, yellow, green, blue, indigo, violet). However, visible light represents only a narrow range of the spectrum of light. The Deep Impact spectrometer measures light in the infrared range rather than visible light. By analyzing data from a spectrometer scientists can determine the composition of the materials being studied.
The Deep Impact scientists will be able to analyze data from their spectrometer to determine the composition of the material that is ejected from the crater during impact and to observe how the composition of that material changes over time. The final prelude to that impact will begin early on July 3, some 24 hours before the 1:52 a.m. (EDT) July 4th impact, when the flyby spacecraft will launch the impactor into the path of the onrushing comet.
Like a copper penny pitched up into the air just in front of a speeding tractor-trailer truck, the 820-pound impactor will be run down by the comet early on July 4. It will collide with the nucleus at an impact, or closing, speed of some 23,000 miles per hour. A'Hearn and his fellow mission scientists expect the impact to create a crater several hundred feet in size; ejecting ice, dust and gas from the crater and revealing pristine material beneath. The impact will have no significant effect on the orbit of Tempel 1, which poses no threat to Earth.
Nearby, Deep Impact's 'flyby' spacecraft will use its medium and high resolution imagers and infrared spectrometer to collect and send back to Earth pictures and spectra of the event. In addition, the Hubble and Spitzer space telescopes, the Chandra X-ray Observatory, and large and small telescopes on Earth also will observe the impact and its aftermath.
The Hubble Space Telescope has given astronomers a sneak preview of what they might see July 4 when the deep impact probe strikes comet 9P/Tempel 1, creating a cosmic display that may be visible with the naked eye in areas around the Pacific. One of a series of simulated photos taken by the orbiting observatory while preparing for the July 4th encounter shows a 1,400-mile plume of dust spewing from the comet toward the sun.
Johns Hopkins University astronomy professor Paul Feldman said light from the sun most may heat a pocket of volatile gas trapped beneath the surface, causing the eruption. Feldman said the images have made him even more optimistic about what Hubble might be able to see.
"If sunlight can cause some material to come out and give us this jet, maybe when Deep Impact hits it will release a lot of material" - Paul Feldman. The Deep Impact spacecraft will release a probe that is set to collide with the Tempel 1 comet early on the morning of July 4. Researchers are hoping for their first look into the heart of the comet, perhaps offering clues about the formation of the solar system.
The collision will be observed by the fly-by portion of the probe as well as NASA's space telescopes and telescopes on Earth. The force of the collision will be equivalent to 4 1/2 tons of TNT, creating a flash that may be visible to the naked eye. In the United States it would be visible only in areas west of a line from Chicago to Atlanta. In the recent photo, Hubble was 75 million miles away from the comet when the visible light images were taken June 14.
"Hopefully, when the Deep Impact space probe hits the comet we'll see some of the same changes, or something better" - Cheryl Gundy, spokeswoman for the Baltimore-based Space Telescope Science Institute, which coordinates use of the orbiting telescope.
The two images, taken seven hours apart on June 14, show Tempel 1 and its new jet. The image at left, taken at 2:17 a.m. (EDT), is a view of the comet before the outburst. The bright dot is light reflecting from the comet's nucleus, which appears star-like in these images because it is too small even for Hubble to resolve. The nucleus, a potato-shaped object, is 14 kilometres wide and 4 kilometres long. Hubble's viewing the nucleus is as difficult as someone trying to spot a potato in Salt Lake City from New York City. The photo at right, snapped at 1415 GMT, reveals the jet (the bright fan-shaped area). The jet extends about 2,200 kilometres, which is roughly half the distance across the U.S. It is pointing in the direction of the Sun. Comets frequently show outbursts in activity, but astronomers still don't know exactly why they occur. Tempel 1 has been moving closer to the Sun, and perhaps the increasing heat opened up a crack in the comet's dark, crusty surface. Dust and gas trapped beneath the surface could then spew out of the crack, forming a jet. Or, perhaps a portion of the crust itself was lifted off the nucleus by the pressure of heated gases beneath the surface. This porous crust might then crumble into small dust particles shortly after leaving the nucleus, producing a fan-shaped coma on the sunward side. Whatever the cause, the new feature may not last for long