Tempel 1

Last updated
9P/Tempel
PIA02142 Tempel 1 bottom sharped.jpg
Composite of images of nucleus obtained by the Deep Impact impactor
Discovery
Discovered by Wilhelm Tempel
Discovery dateApril 3, 1867
Designations
  • 9P/1867 G1
  • 1867 II
  • 9P/1873 G1
  • 1873 I
  • 1873a
  • 1879 III
  • 1879b
  • 9P/1967 L1
  • 1966 VII
  • 9P/1972 A1
  • 1972 V
  • 1972a
  • 1978 II
  • 1977i
  • 1983 XI
  • 1982j
  • 1989 I
  • 1987e1
  • 1994 XIX
  • 1993c
Orbital characteristics
Epoch 2023-02-25 [1]
Aphelion 4.757 AU
Perihelion 1.545 AU [1]
(1.77 AU after 2024 Jupiter approach) [2] [3]
Semi-major axis 3.151 AU
Eccentricity 0.5097
Orbital period 5.59 years (2,040 days)
Inclination 10.474°
68.64°
Argument of
periapsis 		179.54°
Last perihelionMarch 4, 2022 [1]
August 2, 2016 [1]
Next perihelion2028-Feb-12 [3]
Earth MOID 0.52 AU (78 million km)
Physical characteristics
Dimensions 7.6 km × 4.9 km (4.7 mi × 3.0 mi) [4] [5]
Mass 7.2×1013 to 7.9×1013 kg [5] [6]
Mean density
0.62 g/cm3 [7]
40.7 hours [4]

Tempel 1 (official designation: 9P/Tempel) is a periodic Jupiter-family comet discovered by Wilhelm Tempel in 1867. It completes an orbit of the Sun every 5.6 years. Tempel 1 was the target of the Deep Impact space mission, which photographed a deliberate high-speed impact upon the comet in 2005. It was re-visited by the Stardust spacecraft on February 14, 2011, and came back to perihelion in August 2016. On 26 May 2024, it will make a modest approach of 0.55 AU to Jupiter [4] [2] which will lift the perihelion distance and 9P will next come to perihelion on 12 February 2028 when it will be 1.77 AU from the Sun. [3]

Contents

Discovery and orbital history

Tempel 1 was discovered on April 3, 1867, by Wilhelm Tempel, who was working at Marseille. At the time of discovery, it approached perihelion once every 5.68 years (designations 9P/1867 G1 and 1867 II). [8] [9] It was subsequently observed in 1873 (9P/1873 G1, 1873 I, 1873a) and in 1879 (1879 III, 1879b). [10]

Photographic attempts during 1898 and 1905 failed to recover the comet, and astronomers surmised that it had disintegrated, when in reality, its orbit had changed. Tempel 1's orbit occasionally brings it sufficiently close to Jupiter to be altered, with a consequent change in the comet's orbital period. [2] This occurred in 1881 (closest approach to Jupiter of 0.55 AU), lengthening the orbital period to 6.5 years. Perihelion also changed, increasing by 50 million kilometres, to 2.1 AU, rendering the comet far less visible from Earth. [2] Perihelion did not drop below 2 AU until 1944 after a 1941 approach to Jupiter. [11]

Detail of crater-like features on Comet Tempel 1 in image taken by Deep Impact's impactor Comet Temple 1 detail.jpg
Detail of crater-like features on Comet Tempel 1 in image taken by Deep Impact's impactor

Tempel 1 was rediscovered in 1967 (as 9P/1967 L1, 1966 VII) after British astronomer Brian G. Marsden performed precise calculations of the comet's orbit that took into account Jupiter's perturbations. Marsden found that further close approaches to Jupiter in 1941 (0.41 AU) and 1953 (0.77 AU) had decreased both the perihelion distance and the orbital period to values smaller than when the comet was initially discovered (5.84 and 5.55 years, respectively). [2] These approaches moved Tempel 1 into its present libration around the 1:2 resonance with Jupiter. Despite an unfavorable 1967 return, Elizabeth Roemer of the Catalina Observatory took several photographs. [2] Initial inspection revealed nothing, but in late 1968 she found a June 8, 1967 exposure (Tempel 1 had passed perihelion in January) that held the image of an 18th magnitude diffuse object very close to where Marsden had predicted the comet to be. At least two images are required for orbit computation, so the next return had to be awaited. [2]

Roemer and L. M. Vaughn recovered the comet on January 11, 1972, from Steward Observatory (9P/1972 A1, 1972 V, 1972a). [2] The comet became widely observed, reached a maximum brightness of magnitude 11 during May, and was last seen on July 10. Since that time the comet has been seen at every apparition, in 1978 (1978 II, 1977i), 1983 (1983 XI, 1982j), 1989 (1989 I, 1987e1), 1994 (1994 XIUX, 1993c), 2000, and 2005. [2]

Physical characteristics

Tempel 1 in X-ray light by Chandra PIA02118.jpg
Tempel 1 in X-ray light by Chandra

Tempel 1 is not a bright comet; its brightest apparent magnitude since discovery has been 11, far below naked-eye visibility. Its nucleus measures 7.6 km × 4.9 km (4.7 mi × 3.0 mi). [4] [5] Measurements taken by the Hubble Space Telescope in visible light [13] and the Spitzer Space Telescope in infrared light [14] suggest a low albedo of only 4%. A two-day rotation rate was also determined. [15] The comet was also seen to emit x-rays due to highly charged solar wind ions removing electrons via charge exchange from gases outflowing from Tempel 1's nucleus. [12]

Exploration

Deep Impact space mission

Animation of Deep Impact's trajectory from 12 January 2005 to 8 August 2013 .mw-parser-output .legend{page-break-inside:avoid;break-inside:avoid-column}.mw-parser-output .legend-color{display:inline-block;min-width:1.25em;height:1.25em;line-height:1.25;margin:1px 0;text-align:center;border:1px solid black;background-color:transparent;color:black}.mw-parser-output .legend-text{} Deep Impact 1 Tempel 1 Earth 103P/Hartley Animation of Deep Impact trajectory.gif
Animation of Deep Impact's trajectory from 12 January 2005 to 8 August 2013
   Deep Impact 1  Tempel 1   Earth    103P/Hartley
The head-on collision of comet 9P/Tempel and the Deep Impact impactor Deep Impact HRI.jpeg
The head-on collision of comet 9P/Tempel and the Deep Impact impactor

On 4 July 2005 at 05:52 UTC (01:52 EDT), Tempel 1 was deliberately struck by one component of the NASA Deep Impact probe, one day before perihelion. The impact was photographed by the other component of the probe, which recorded a bright spray from the impact site. The impact was also observed by earthbound and space telescopes, which recorded a brightening of several magnitudes.

The crater that formed was not visible to Deep Impact due to the cloud of dust raised by the impact, but was estimated to be between 100 and 250 meters in diameter [16] and 30 meters deep. Spitzer Space Telescope observations of the ejecta detected dust particles finer than human hair and discovered the presence of silicates, carbonates, smectite, metal sulfides (such as fool's gold), amorphous carbon and polycyclic aromatic hydrocarbons. [17] Spitzer also detected water ice in the ejecta, consistent with surface water ice detected by Deep Impact's spectrometer instrument. [18] The water ice came from 1 meter below the surface crust (the devolatized layer around the nucleus). [18]

NEXT mission

Before and after comparison images from Deep Impact and Stardust, showing the crater formed by Deep Impact on the right hand image. DeepImpactTempelCrater.jpg
Before and after comparison images from Deep Impact and Stardust, showing the crater formed by Deep Impact on the right hand image.
Animation of Stardust's trajectory from 7 February 1999 to 7 April 2011 Stardust * 81P/Wild * Earth * 5535 Annefrank * Tempel 1 Animation of Stardust trajectory.gif
Animation of Stardust's trajectory from 7 February 1999 to 7 April 2011
  Stardust ·   81P/Wild  ·   Earth  ·   5535 Annefrank  ·  Tempel 1

In part, because the crater formed during the Deep Impact collision could not be imaged during the initial flyby, [16] on 3 July 2007, NASA approved the New Exploration of Tempel 1 (or NExT) mission. The low-cost mission utilized the already existing Stardust spacecraft, which had studied Comet Wild 2 in 2004. Stardust was placed into a new orbit so that it approached Tempel 1. It passed at a distance of approximately 181 km (112 mi) on February 15, 2011, 04:42 UTC. [19] This was the first time that a comet was visited twice.

On February 15, NASA scientists identified the crater formed by Deep Impact in images from Stardust. The crater is estimated to be 150 m (490 ft) in diameter and has a bright mound in the center likely created when material from the impact fell back into the crater. [20] Energy of impactor According to NASA "The impactor delivers 19 Gigajoules (that's 4.8 tons of TNT) of kinetic energy to excavate the crater. This kinetic energy is generated by the combination of the mass of the impactor (370 kg; 816 lbs) and its velocity when it impacts (~10.2 km/s)". According to NASA, "The energy from the impact will excavate a crater approximately 100m wide and 28m deep". [21]

The geometry of the flyby allowed investigators to obtain considerably more three-dimensional information about the nucleus from stereo pairs of images than during Deep Impact's encounter. [22] Scientists were able to quickly spot locations where an elevated flow-like formation of icy material on the comet's surface receded due to sublimation between encounters. [22]

Close approaches

Comets are in unstable orbits that evolve due to perturbations and outgassing. Tempel 1 passed within 0.04 AU – or 5.9 million km (3.7 million mi) – of the dwarf planet Ceres on November 11, 2011. [4] Then, as a Jupiter-family comet, it will spend years interacting with the giant planet Jupiter, and by October 2084 perihelion will be lifted as high as 1.98 AU. [23] Then perihelion will start dropping again and it will pass 0.0191 AU (2.86 million km; 1.78 million mi) from Mars on October 17, 2183. [4]

9P/Tempel closest Mars approach on 2183-Oct-17 [4]
Date & time of
closest approach		Mars distance
(AU)		Sun distance
(AU)		Velocity
wrt Mars
(km/s)		Velocity
wrt Sun
(km/s)		Uncertainty
region
(3-sigma)		Reference
2183-Oct-17 16:25 ± 2 hours0.0191  AU (2.86 million  km ; 1.78 million  mi ; 7.4  LD )1.506 AU (225.3 million km; 140.0 million mi; 586 LD)6.5829.92± 6620 km Horizons

Related Research Articles

<span class="mw-page-title-main">Comet</span> Natural object in space that releases gas

A comet is an icy, small Solar System body that warms and begins to release gases when passing close to the Sun, a process called outgassing. This produces an extended, gravitationally unbound atmosphere or coma surrounding the nucleus, and sometimes a tail of gas and dust gas blown out from the coma. These phenomena are due to the effects of solar radiation and the outstreaming solar wind plasma acting upon the nucleus of the comet. Comet nuclei range from a few hundred meters to tens of kilometers across and are composed of loose collections of ice, dust, and small rocky particles. The coma may be up to 15 times Earth's diameter, while the tail may stretch beyond one astronomical unit. If sufficiently close and bright, a comet may be seen from Earth without the aid of a telescope and can subtend an arc of up to 30° across the sky. Comets have been observed and recorded since ancient times by many cultures and religions.

<span class="mw-page-title-main">Comet Hale–Bopp</span> Long-period comet

Comet Hale–Bopp is a comet that was one of the most widely observed of the 20th century and one of the brightest seen for many decades.

<span class="mw-page-title-main">Near-Earth object</span> Small Solar System body with an orbit that can bring it close to Earth

A near-Earth object (NEO) is any small Solar System body orbiting the Sun whose closest approach to the Sun (perihelion) is less than 1.3 times the Earth–Sun distance. This definition applies to the object's orbit around the Sun, rather than its current position, thus an object with such an orbit is considered an NEO even at times when it is far from making a close approach of Earth. If an NEO's orbit crosses the Earth's orbit, and the object is larger than 140 meters (460 ft) across, it is considered a potentially hazardous object (PHO). Most known PHOs and NEOs are asteroids, but about 0.35% are comets.

<i>Stardust</i> (spacecraft) Fourth mission of the Discovery program; sample return from the periodic Comet Wild 2

Stardust was a 385-kilogram robotic space probe launched by NASA on 7 February 1999. Its primary mission was to collect dust samples from the coma of comet Wild 2, as well as samples of cosmic dust, and return them to Earth for analysis. It was the first sample return mission of its kind. En route to Comet Wild 2, it also flew by and studied the asteroid 5535 Annefrank. The primary mission was successfully completed on 15 January 2006 when the sample return capsule returned to Earth.

<span class="mw-page-title-main">81P/Wild</span> Periodic comet with six-year orbit

Comet 81P/Wild, also known as Wild 2, is a comet named after Swiss astronomer Paul Wild, who discovered it on January 6, 1978, using a 40-cm Schmidt telescope at Zimmerwald, Switzerland.

<span class="mw-page-title-main">Discovery Program</span> Ongoing solar system exploration program by NASA

The Discovery Program is a series of Solar System exploration missions funded by the U.S. National Aeronautics and Space Administration (NASA) through its Planetary Missions Program Office. The cost of each mission is capped at a lower level than missions from NASA's New Frontiers or Flagship Programs. As a result, Discovery missions tend to be more focused on a specific scientific goal rather than serving a general purpose.

<span class="mw-page-title-main">46P/Wirtanen</span> Periodic comet with 5 year orbit

46P/Wirtanen is a small short-period comet with a current orbital period of 5.4 years. It was the original target for close investigation by the Rosetta spacecraft, planned by the European Space Agency, but an inability to meet the launch window caused Rosetta to be sent to 67P/Churyumov–Gerasimenko instead. It belongs to the Jupiter family of comets, all of which have aphelia between 5 and 6 AU. Its diameter is estimated at 1.4 kilometres (0.9 mi). In December 2019, astronomers reported capturing an outburst of the comet in substantial detail by the TESS space telescope.

<span class="mw-page-title-main">2867 Šteins</span>

2867 Šteins is an irregular, diamond-shaped background asteroid from the inner regions of the asteroid belt, approximately 5 kilometers in diameter. It was discovered on 4 November 1969 by Soviet astronomer Nikolai Chernykh at the Crimean Astrophysical Observatory in Nauchnij on the Crimean peninsula. In September 2008, ESA's spacecraft Rosetta flew by Šteins, making it one of few minor planets ever visited by a spacecraft. The bright E-type asteroid features 23 named craters and has a rotation period of 6.05 hours. It was named for Soviet Latvian astronomer Kārlis Šteins.

<i>Deep Impact</i> (spacecraft) NASA space probe launched in 2005

Deep Impact was a NASA space probe launched from Cape Canaveral Air Force Station on January 12, 2005. It was designed to study the interior composition of the comet Tempel 1 (9P/Tempel), by releasing an impactor into the comet. At 05:52 UTC on July 4, 2005, the Impactor successfully collided with the comet's nucleus. The impact excavated debris from the interior of the nucleus, forming an impact crater. Photographs taken by the spacecraft showed the comet to be more dusty and less icy than had been expected. The impact generated an unexpectedly large and bright dust cloud, obscuring the view of the impact crater.

<span class="mw-page-title-main">Comet Rendezvous Asteroid Flyby</span> Cancelled NASA mission plan

The Comet Rendezvous Asteroid Flyby (CRAF) was a cancelled plan for a NASA-led exploratory mission designed by the Jet Propulsion Laboratory during the mid-to-late 1980s and early 1990s, that planned to send a spacecraft to encounter an asteroid, and then to rendezvous with a comet and fly alongside it for nearly three years. The project was eventually canceled when it went over budget; most of the money still left was redirected to its twin spacecraft, Cassini–Huygens, destined for Saturn, so it could survive Congressional budget cutbacks. Most of CRAF's scientific objectives were later accomplished by the smaller NASA spacecraft Stardust and Deep Impact, and by ESA's flagship Rosetta mission.

<span class="mw-page-title-main">10P/Tempel</span> Periodic comet with 5 year orbit

10P/Tempel, also known as Tempel 2, is a periodic Jupiter-family comet with a 5 year orbital period. It was discovered on July 4, 1873 by Wilhelm Tempel. The next perihelion passage is 2 August 2026 when the comet will have a solar elongation of 164 degrees at approximately apparent magnitude 8. Closest approach to Earth will be one day later on 3 August 2026 at a distance of 0.414 AU (61.9 million km).

<span class="mw-page-title-main">Comet nucleus</span> Central part of a comet

The nucleus is the solid, central part of a comet, formerly termed a dirty snowball or an icy dirtball. A cometary nucleus is composed of rock, dust, and frozen gases. When heated by the Sun, the gases sublime and produce an atmosphere surrounding the nucleus known as the coma. The force exerted on the coma by the Sun's radiation pressure and solar wind cause an enormous tail to form, which points away from the Sun. A typical comet nucleus has an albedo of 0.04. This is blacker than coal, and may be caused by a covering of dust.

<span class="mw-page-title-main">73P/Schwassmann–Wachmann</span> Multiple fragment periodic comet with 5-year orbit

73P/Schwassmann–Wachmann, also known as Schwassmann–Wachmann 3 or SW3 for short, is a periodic comet that has a 5.4 year orbital period and that has been actively disintegrating since 1995. When it came to perihelion in March 2017, fragment 73P-BT was separating from the main fragment 73P-C. Fragments 73P-BU and 73P-BV were detected in July 2022. The main comet came to perihelion on 25 August 2022, when the comet was 0.97 AU from the Sun and 1 AU from Earth. It will be less than 80 degrees from the Sun from 25 May 2022 until August 2023. On 3 April 2025 it will make a modest approach of 0.3 AU to Jupiter. 73P will next come to perihelion on 23 December 2027 when it will be 0.92 AU from the Sun and on the far side of the Sun 1.9 AU from Earth.

<i>EPOXI</i> Extended mission of the Deep Impact space probe

EPOXI was a compilation of NASA Discovery program missions led by the University of Maryland and principal investigator Michael A'Hearn, with co-operation from the Jet Propulsion Laboratory and Ball Aerospace. EPOXI uses the Deep Impact spacecraft in a campaign consisting of two missions: the Deep Impact Extended Investigation (DIXI) and Extrasolar Planet Observation and Characterization (EPOCh). DIXI aimed to send the Deep Impact spacecraft on a flyby of another comet, after its primary mission was completed in July 2005, while EPOCh saw the spacecraft's photographic instruments as a space observatory, studying extrasolar planets.

<span class="mw-page-title-main">103P/Hartley</span> Periodic comet with 6 year orbit

Comet Hartley 2, designated as 103P/Hartley by the Minor Planet Center, is a small periodic comet with an orbital period of 6.48 years. It was discovered by Malcolm Hartley in 1986 at the Schmidt Telescope Unit, Siding Spring Observatory, Australia. Its diameter is estimated to be 1.2 to 1.6 kilometres.

<span class="mw-page-title-main">C/2013 A1 (Siding Spring)</span> Oort cloud comet

C/2013 A1 is an Oort cloud comet discovered on 3 January 2013 by Robert H. McNaught at Siding Spring Observatory using the 0.5-meter (20 in) Uppsala Southern Schmidt Telescope.

<span class="mw-page-title-main">252P/LINEAR</span> Periodic comet and near-earth object

Comet 252P/LINEAR is a periodic comet and near-Earth object discovered by the LINEAR survey on April 7, 2000. The comet is a Jupiter family comet, meaning that it passes quite close to the orbit of Jupiter.

<span class="mw-page-title-main">460P/PanSTARRS</span> Near-Earth object and periodic comet of the Jupiter family

460P/PanSTARRS (also known with the provisional designation P/2016 BA14) is a near-Earth object and periodic comet of the Jupiter family, with an orbital period of 5.25 years. In March 2016 it passed at distance of 2.2 million miles (3.5 million km, or 9 lunar distances) from Earth. It was the closest approach by a comet since 1770 and 3rd closest recorded comet to Earth. The close flyby enabled the size of the nucleus to be calculated at about 1 km (0.62 mi) in diameter, which was much bigger than expected. The comet is very dark, reflecting about 2-3 percent of the visible light, about the same as a charcoal briquette. It has a very similar orbit as numbered comet 252P/LINEAR, and may be related to it (e.g. split off of).

<span class="nowrap">C/2014 UN<sub>271</sub></span> (Bernardinelli–Bernstein) Largest known Oort cloud comet

C/2014 UN271 (Bernardinelli–Bernstein), simply known as C/2014 UN271 or Comet Bernardinelli–Bernstein (nicknamed BB), is a large Oort cloud comet discovered by astronomers Pedro Bernardinelli and Gary Bernstein in archival images from the Dark Energy Survey. When first imaged in October 2014, the object was 29 AU (4.3 billion km; 2.7 billion mi) from the Sun, almost as far as Neptune's orbit and the greatest distance at which a comet has been discovered. With a nucleus diameter of at least 120 km (75 mi), it is the largest Oort cloud comet known. It is approaching the Sun and will reach its perihelion of 10.9 AU (just outside of Saturn's orbit) in January 2031. It will not be visible to the naked eye because it will not enter the inner Solar System.

References

  1. 1 2 3 4 MPC
  2. 1 2 3 4 5 6 7 8 9 Kronk, Gary. "9P/Tempel 1". cometography.com. Retrieved 18 April 2023.
  3. 1 2 3 "Horizons Batch for 9P/Tempel 1 (90000191) on 2028-Feb-12" (Perihelion occurs when rdot flips from negative to positive). JPL Horizons. Archived from the original on 2022-06-15. Retrieved 2022-06-15. (JPL#K223/6 Soln.date: 2022-Jun-08)
  4. 1 2 3 4 5 6 7 "JPL Small-Body Database Browser: 9P/Tempel 1" (2023-01-03 last obs). Retrieved 2008-12-16.
  5. 1 2 3 "Comet 9P/Tempel 1". The Planetary Society. Archived from the original on 2006-02-09. Retrieved 2008-12-16.
  6. Using a spherical diameter of 6.25 km; volume of a sphere * a rubble pile density of 0.62 g/cm3 yields a mass (m=d*v) of 7.9E+13 kg
  7. D. T. Britt; G. J. Consol-magno SJ; W. J. Merline (2006). "Small Body Density and Porosity: New Data, New Insights" (PDF). Lunar and Planetary Science XXXVII. Retrieved 2008-12-16.
  8. "In Depth | 9P/Tempel 1". NASA Solar System Exploration. Retrieved 2022-08-04.
  9. "Tempel 1: Biography of a comet". www.esa.int. Retrieved 2022-08-04.
  10. Rao, Joe (2005-06-03). "The History of Tempel 1, the 'Deep Impact' Target". Space.com. Retrieved 2022-08-04.
  11. Kinoshita, Kazuo (2018-07-07). "9P/Tempel". Comet Orbit. Retrieved 2023-07-19.
  12. 1 2 Lisse, Carey M.; Dennerl, K.; Christian, D. J.; Wolk, S. J.; Bodewits, D.; Zurbuchen, T. H.; Hansen, K. C.; Hoekstra, R.; Combi, M.; Fry, C. D.; Dryer, M.; Mäkinen, T; Sun, W. (2007). "Chandra observations of Comet 9P/Tempel 1 during the Deep Impact campaign". Icarus. 190 (2): 391–405. Bibcode:2007Icar..190..391L. doi:10.1016/j.icarus.2007.03.004.
  13. "Deep Impact – Exploring the Interior of a Comet" (PDF).
  14. Lisse, Carey M.; A'Hearn, M. F.; Groussin, O.; Fernández, Y. R.; Belton, M. J. S.; VanCleve, J.; Charmandaris, V.; Meech, K. J.; McGleam, C. (2005). "Rotationally Resolved 8-35 Micron Spitzer Space Telescope Observations of the Nucleus of Comet 9P/Tempel 1". Astrophysical Journal. 625 (2): L139–L142. Bibcode:2005ApJ...625L.139L. doi:10.1086/431238.
  15. "Space Telescopes Sharpen View of Comet for UM-Led Deep Impact". www.newswise.com. Retrieved 2018-01-10.
  16. 1 2 Lakdawalla, Emily (2011-01-19). "Stardust prepares for a first-second look at a comet: Tempel 1 on February 14". Planetary Society blog. The Planetary Society. Archived from the original on 2012-04-01. Retrieved 2011-02-19.
  17. Lisse, Carey M.; VanCleve, J.; Adams, A. C.; A'Hearn, M. F.; Fernández, Y. R.; Farnham, T. L.; Armus, L.; Grillmair, C. J.; Ingalls, J.; Belton, M. J. S.; Groussin, O.; McFadden, L. A.; Meech, K. J.; Schultz, P. H.; Clark, B. C..; Feaga, L. M.; Sunshine, J. M. (2006). "Spitzer Spectral Observations of the Deep Impact Ejecta". Science. 313 (5787): 635–640. Bibcode:2006Sci...313..635L. doi:10.1126/science.1124694.
  18. 1 2 Sunshine, Jessica M.; Groussin, O.; Schultz, P. H.; A'Hearn, M. F.; Feaga, L. M.; Farnham, T. L.; Klaasen, K. P. (2007). "The distribution of water ice in the interior of Comet Tempel 1" (PDF). Icarus. 190 (2): 284–294. Bibcode:2007Icar..190..284S. doi:10.1016/j.icarus.2007.04.024.
  19. Able, D. C. (2011-02-14). "NASA's Stardust Spacecraft Completes Comet Flyby". Stardust-Next Mission. JPL. Archived from the original on 2011-02-18. Retrieved 2011-02-16.
  20. Tony Greicius (15 February 2011). "Tempel 1 Impact Site". NASA. Retrieved 16 February 2011.
  21. "The Deep Impact Spacecraft". NASA. 6 June 2013.
  22. 1 2 Lakdawalla, Emily (2011-02-16). "Some early scientific impressions of Stardust's Tempel 1 flyby". The Planetary Society Blog. The Planetary Society. Archived from the original on 2011-02-21. Retrieved 2011-02-16.
  23. "Horizons Batch for 9P/Tempel 1 on 2084-Oct-14" (Perihelion occurs when rdot flips from negative to positive). JPL Horizons. Archived from the original on 2023-07-12. Retrieved 2023-07-12. (JPL#K2234/6 Soln.date: 2023-May-04)

Further reading

Numbered comets
Previous
8P/Tuttle 		Tempel 1Next
10P/Tempel
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.