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Stardust

Artist's impression of Stardust at comet Wild 2
Names	Discovery 4 Stardust-NExT
Mission type	Sample return
Operator	NASA / JPL
COSPAR ID	1999-003A
SATCAT no.	25618
Website	stardust.jpl.nasa.gov stardustnext.jpl.nasa.gov
Mission duration	Stardust: 6 years, 11 months, 7 days NExT: 4 years, 2 months, 7 days Total: 12 years, 1 month, 17 days
Spacecraft properties
Bus	SpaceProbe
Manufacturer	Lockheed Martin University of Washington
Launch mass	390.599 kg (861 lb)
Dry mass	305.397 kg (673 lb)
Dimensions	Bus: 1.71 × 0.66 × 0.66 m (5.6 × 2.16 × 2.16 ft)
Power	330 W (Solar array / NiH2 batteries)
Start of mission
Launch date	7 February 1999, 21:04:15.238 (1999-02-07UTC21:04:15) UTC
Rocket	Delta II 7426-9.5 #266
Launch site	Cape Canaveral SLC-17
Contractor	Lockheed Martin Space Systems
End of mission
Disposal	Decommissioned
Deactivated	Spacecraft: 24 March 2011, 23:33 (2011-03-24UTC23:34) UTC
Landing date	Capsule: 15 January 2006, 10:12 UTC
Landing site	Utah Test and Training Range 40°21.9′N 113°31.25′W / 40.3650°N 113.52083°W / 40.3650; -113.52083
Flyby of asteroid 5535 Annefrank
Closest approach	2 November 2002, 04:50:20 UTC
Distance	3,079 km (1,913 mi)
Flyby of periodic comet Wild 2
Closest approach	2 January 2004, 19:21:28 UTC
Distance	237 km (147 mi)
Flyby of comet Tempel 1
Closest approach	15 February 2011, 04:39:10 UTC
Distance	181 km (112 mi)
Instruments CIDA Comet and Interstellar Dust Analyzer DFMI Dust Flux Monitor Instrument SSC Stardust Sample Collection DSE Dynamic Science Experiment NavCam Navigation Camera
[REDACTED] Discovery program← Lunar ProspectorGenesis →

Stardust was a 390 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 these to Earth for analysis. It was the first sample return mission of its kind. En route to comet Wild 2, the craft 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.

A mission extension codenamed NExT culminated in February 2011 with Stardust intercepting comet Tempel 1, a small Solar System body previously visited by Deep Impact in 2005. Stardust ceased operations in March 2011.

On 14 August 2014, scientists announced the identification of possible interstellar dust particles from the Stardust capsule returned to Earth in 2006.

Mission background

History

Beginning in the 1980s, scientists began seeking a dedicated mission to study a comet. During the early 1990s, several missions to study comet Halley became the first successful missions to return close-up data. However, the US cometary mission, Comet Rendezvous Asteroid Flyby, was canceled for budgetary reasons. In the mid-1990s, further support was given to a cheaper, Discovery-class mission that would study comet Wild 2 in 2004.

Stardust was competitively selected in the fall of 1995 as a NASA Discovery Program mission of low-cost with highly focused science goals. Construction of Stardust began in 1996, and was subject to the maximum contamination restriction, level 5 planetary protection. However, the risk of interplanetary contamination by alien life was judged low, as particle impacts at over 1000 miles per hour, even into aerogel, were believed to be terminal for any known microorganism.

Comet Wild 2 was selected as the primary target of the mission for the rare chance to observe a long-period comet that has ventured close to the Sun. The comet has since become a short period comet after an event in 1974, where the orbit of Wild 2 was affected by the gravitational pull of Jupiter, moving the orbit inward, closer to the Sun. In planning the mission, it was expected that most of the original material from which the comet formed would still be preserved.

The primary science objectives of the mission included:

• Providing a flyby of a comet of interest (Wild 2) at a sufficiently low velocity (less than 6.5 km/s) such that non-destructive capture of comet dust is possible using an aerogel collector.
• Facilitating the intercept of significant numbers of interstellar dust particles using the same collection medium, also at as low a velocity as possible.
• Returning as many high resolution images of the comet coma and nucleus as possible, subject to the cost constraints of the mission.

The spacecraft was designed, built and operated by Lockheed Martin Astronautics as a Discovery-class mission in Denver, Colorado. JPL provided mission management for the NASA division for mission operations. The principal investigator of the mission was Dr. Donald Brownlee from the University of Washington.

Spacecraft design

The spacecraft bus measured 1.7 meters (5.6 ft) in length, and 0.66 meters (2.2 ft) in width, a design adapted from the SpaceProbe deep space bus developed by Lockheed Martin Astronautics. The bus was primarily constructed with graphite fiber panels with an aluminum honeycomb support structure underneath; the entire spacecraft was covered with polycyanate, Kapton sheeting for further protection. To maintain low costs, the spacecraft incorporated many designs and technologies used in past missions or previously developed for future missions by the Small Spacecraft Technologies Initiative (SSTI). The spacecraft featured five scientific instruments to collect data, including the Stardust Sample Collection tray, which was brought back to Earth for analysis.

Attitude control and propulsion

The spacecraft was three-axis stabilized with eight 4.41 N hydrazine monopropellant thrusters, and eight 1 Newton thrusters to maintain attitude control (orientation); necessary minor propulsion maneuvers were performed by these thrusters as well. The spacecraft was launched with 80 kilograms of propellant. Information for spacecraft positioning was provided by a star camera using FSW to determine attitude (stellar compass), an inertial measurement unit, and two sun sensors.

Communications

For communicating with the Deep Space Network, the spacecraft transmitted data across the X-band using a 0.6-meter (2 ft 0 in) parabolic high-gain antenna, medium-gain antenna (MGA) and low-gain antennas (LGA) depending on mission phase, and a 15 watt transponder design originally intended for the Cassini spacecraft.

Power

The probe was powered by two solar arrays, providing an average of 330 watts of power. The arrays also included Whipple shields to protect the delicate surfaces from the potentially damaging cometary dust while the spacecraft was in the coma of Wild 2. The solar array design was derived primarily from the Small Spacecraft Technology Initiative (SSTI) spacecraft development guidelines. The arrays provided a unique method of switching strings from series to parallel depending on the distance from the Sun. A single nickel–hydrogen (NiH₂) battery was also included to provide the spacecraft with power when the solar arrays received too little sunlight.

Computer

The computer on the spacecraft operated using a radiation hardened RAD6000 32 bit processor card. For storing data when the spacecraft was unable to communicate with Earth, the processor card was able to store 128 megabytes, 20% of which was occupied by the flight system software. The system software is a form of VxWorks, an embedded operating system developed by Wind River Systems.

Scientific instruments

Navigation Camera (NC)
	The camera is intended for targeting comet Wild 2 during the flyby of the nucleus. It captures black and white images through a filter wheel making it possible to assemble color images and detect certain gas and dust emissions in the coma. It also captures images at various phase angles, making it possible to create a three-dimensional model of a target to better understand the origin, morphology, and mineralogical inhomogeneities on the surface of the nucleus. The camera utilizes the optical assembly from the Voyager Wide Angle Camera. It is additionally fitted with a scanning mirror to vary the viewing angle and avoid potentially damaging particles. For environmental testing and verification of the NAVCAM the only remaining Voyager spare camera assembly was used as a collimator for testing of the primary imaging optics. A target at the focal point of the spare was imaged through the optical path of the NAVCAM for verification. Objectives Determine the position of Comet P/Wild 2 during the approach and encounter Obtain high resolution images of the nucleus Lead investigator: Ray Newburn / JPL Data: PDS/SBN data catalog
Cometary and Interstellar Dust Analyzer (CIDA)
	The dust analyzer is a mass spectrometer able to provide real-time detection and analysis of certain compounds and elements. Particles enter the instrument after colliding with a silver impact plate and traveling down a tube to the detector. The detector is then able to detect the mass of separate ions by measuring the time taken for each ion to enter and travel through the instrument. Identical instruments were also included on Giotto and Vega 1 and 2. Objectives Lead investigator: Jochen Kissel / Max-Planck-Institut fur Aeronomie (website -archived) Data: PDS/SBN data archives: Early calibration, Annefrank, Raw Wild 2, Calibrated Wild 2
Dust Flux Monitor Instrument (DFMI)
	Located on the Whipple shield at the front of the spacecraft, the sensor unit provides data regarding the flux and size distribution of particles in the environment around Wild 2. It records data by generating electric pulses as a special polarized plastic (PVDF) sensor is struck by high energy particles as small as a few micrometers. Objectives Record quantitative measurements of the particle impact rate and particle mass distribution throughout the flyby of comet Wild 2. Establish the physical processes of dust emission from the nucleus, their propagation to form a coma, and the behavior of dust jets. Provide measurements of the dust flux at least once per second, and up to 10 times per second. Provide important information on the dust environment relevant to engineering concerns for spacecraft health and interpretation of anomalies. Lead investigator: Anthony Tuzzolino / University of Chicago (website) Data: PDS/SBN data archive, PDS/SBN EDR data archive
Stardust Sample Collection (SSC)
	The particle collector uses aerogel, a low-density, inert, microporous, silica-based substance, to capture dust grains as the spacecraft passes through the coma of Wild 2. After sample collection was complete, the collector receded into the Sample Return Capsule for entering the Earth's atmosphere. The capsule with encased samples would be retrieved from Earth's surface and studied. Objectives Determine the elemental, chemical, and mineralogical composition of Wild 2 at the submicron scale. Determine which compounds dominate the organic fraction of Wild 2. Establish the building materials of Wild 2 found in interplanetary dust particles (IDP) and meteorites. Determine the extent of the building materials of Wild 2 found in interplanetary dust particles (IDP) and meteorites. Establish if IDPs are consistent with Wild 2 samples. Determine if pyroxenerich chondritic aggregate IDPs are cometary. Establish if amino acids, quinones, amphiphiles, or other molecules of exobiological interest are present. Determine the state of H2O in Wild 2. Determine if there was mixing of inner nebula materials (i.e., high-temperature condensates) in the region of comet formation in the outer nebula. Characterize isotopic anomalies present which could provide signatures of the place of origin of interstellar grains Determine the high deuterium-to-hydrogen ratios seen in some IDPs common in Wild 2 solids Characterize the nature of the carbonaceous material in Wild 2, and the relationship to silicates and other mineral phases or constraints in the processes by which they were formed (ion-molecule, gas-grain, irradiation of ices, etc.) Determine if there are organic refractory mantles on silicate grains and if they resemble the organics found in IDPs and meteorites Provide evidence of preaccretional processing of grains (cosmic ray tracks, sputtered rims, altered mineralogy, etc.) Determine if GEMS (Glass with Embedded Fe Ni Metal and Sulfides) are present Principal investigator: Donald Brownlee / University of Washington Data: PDS/SBN temperature data archive, PDS/SBN positioning data archive
Dynamic Science Experiment (DSE)
	The experiment will primarily utilize the X band telecommunications system to conduct radio science on Wild 2, to determine the mass of the comet; secondarily the inertial measurement unit is utilized to estimate the impact of large particle collisions on the spacecraft. Objectives Determine the mass and bulk density of comet Wild 2. Determine the coma density and constrain the particle size distribution for comet Wild 2. Sound the solar corona at X band, including electron content of the inner corona, solar wind acceleration, turbulence, and a search for coronal mass ejections. Lead investigator: John Anderson / JPL Data: PDS/SBN data archive

Sample collection

Comet and interstellar particles are collected in ultra low density aerogel. The tennis racket-sized collector tray contained ninety blocks of aerogel, providing more than 1,000 square centimeters of surface area to capture cometary and interstellar dust grains.

To collect the particles without damaging them, a silicon-based solid with a porous, sponge-like structure is used in which 99.8 percent of the volume is empty space. Aerogel has 1⁄1000 the density of glass, another silicon-based solid to which it may be compared. When a particle hits the aerogel, it becomes buried in the material, creating a long track, up to 200 times the length of the grain. The aerogel was packed in an aluminium grid and fitted into a Sample Return Capsule (SRC), which was to be released from the spacecraft as it passed Earth in 2006.

To analyze the aerogel for interstellar dust, one million photographs will be needed to image the entirety of the sampled grains. The images will be distributed to home computer users to aid in the study of the data using a program titled, Stardust@home. In April 2014, NASA reported they had recovered seven particles of interstellar dust from the aerogel.

• Diagram of the spacecraft.
• Stardust capsule with aerogel collector deployed
• Stardust awaiting testing of the solar arrays.
• The solar arrays being checked in the Payload Hazardous Servicing Facility.
• Stardust being checked before encapsulation.

Stardust microchip

Stardust was launched carrying two sets of identical pairs of square 10.16-centimeter (4.00 in) silicon wafers. Each pair featured engravings of well over one million names of people who participated in the public outreach program by filling out internet forms available in late 1997 and mid-1998. One pair of the microchips was positioned on the spacecraft and the other was attached to the sample return capsule.

Mission profile

Launch and trajectory

Stardust was launched at 21:04:15 UTC on 7 February 1999, by the National Aeronautics and Space Administration from Space Launch Complex 17A at the Cape Canaveral Air Force Station in Florida, aboard a Delta II 7426 launch vehicle. The complete burn sequence lasted for 27 minutes bringing the spacecraft into a heliocentric orbit that would bring the spacecraft around the Sun and past Earth for a gravity assist maneuver in 2001, to reach asteroid 5535 Annefrank in 2002 and comet Wild 2 in 2004 at a low flyby velocity of 6.1 km/s. In 2004, the spacecraft performed a course correction that would allow it to pass by Earth a second time in 2006, to release the Sample Return Capsule for a landing in Utah in the Bonneville Salt Flats.

During the second encounter with Earth, Stardust was put into a "divert maneuver" immediately after the capsule was released. The maneuver corrected the spacecraft direction to avoid entering the atmosphere. Under twenty kilograms of propellant remained onboard after the maneuver.

On 29 January 2004, the spacecraft was put in hibernation mode with only the solar panels and receiver active, in a 3-year heliocentric orbit that would return it to Earth vicinity on 14 January 2009.

A subsequent mission extension was approved on 3 July 2007, to bring the spacecraft back to full operation for a flyby of comet Tempel 1 in 2011. The mission extension was the first to revisit a small Solar System body and used the remaining propellant, signaling the end of the useful life for the spacecraft.

• Exploded diagram of the Delta II vehicle with Stardust.
• Stardust during launch with a Delta II launch vehicle.
• Trajectory of the Stardust spacecraft en route to Wild 2.

Encounter with Annefrank

At 04:50:20 UTC on 2 November 2002, Stardust encountered asteroid 5535 Annefrank from a distance of 3,079 km (1,913 mi). The solar phase angle ranged from 130 degrees to 47 degrees during the period of observations. This encounter was used primarily as an engineering test of the spacecraft and ground operations in preparation for the encounter with comet Wild 2 in 2003.

• Image of asteroid Annefrank captured on 2 November 2002.
• False-color image of asteroid Annefrank

Encounter with Wild 2

At 19:21:28 UTC, on 2 January 2004, Stardust encountered Comet Wild 2 on the sunward side with a relative velocity of 6.1 km/s at a distance of 237 km (147 mi). The original encounter distance was planned to be 150 km (93 mi), but this was changed after a safety review board increased the closest approach distance to minimize the potential for catastrophic dust collisions.

The relative velocity between the comet and the spacecraft was such that the comet actually overtook the spacecraft from behind as they traveled around the Sun. During the encounter, the spacecraft was on the Sunlit side of the nucleus, approaching at a solar phase angle of 70 degrees, reaching a minimum angle of 3 degrees near closest approach and departing at a phase angle of 110 degrees.

During the flyby the spacecraft deployed the Sample Collection plate to collect dust grain samples from the coma, and took detailed pictures of the icy nucleus.

• Comet Wild 2 as seen from Stardust on 2 January 2004.
• Image of Wild 2 taken during the closest approach phase.
• An overexposed image of Wild 2 showing plumes of material.
• A 3D anaglyph of comet Wild 2

New Exploration of Tempel 1 (NExT)

On 19 March 2006, Stardust scientists announced that they were considering the possibility of redirecting the spacecraft on a secondary mission to image Comet Tempel 1. The comet was previously the target of the Deep Impact mission in 2005, sending an impactor into the surface. The possibility of this extension could be vital for gathering images of the impact crater which Deep Impact was unsuccessful in capturing due to dust from the impact obscuring the surface.

On 3 July 2007 the mission extension was approved and renamed New Exploration of Tempel 1 (NExT). This investigation would provide the first look at the changes to a comet nucleus produced after a close approach to the Sun. NExT also would extend the mapping of Tempel 1, making it the most mapped comet nucleus to date. This mapping would help address the major questions of comet nucleus geology. The flyby mission was expected to consume almost all of the remaining fuel, signaling the end of the operability of the spacecraft.

The mission objectives included the following:

Primary objectives

• Extend the current understanding of the processes that affect the surfaces of comet nuclei by documenting the changes that have occurred on comet Tempel 1 between two successive perihelion passages, or orbits around the Sun.
• Extend the geologic mapping of the nucleus of Tempel 1 to elucidate the extent and nature of layering, and help refine models of the formation and structure of comet nuclei.
• Extend the study of smooth flow deposits, active areas and known exposure of water ice.

Secondary objectives

• Potentially image and characterize the crater produced by Deep Impact in July 2005, to better understand the structure and mechanical properties of cometary nuclei and elucidate crater formation processes on them.
• Measure the density and mass distribution of dust particles within the coma using the Dust Flux Monitor Instrument.
• Analyze the composition of dust particles within the coma using the Comet and Interstellar Dust Analyzer instrument.

Encounter with Tempel 1

At 04:39:10 UTC on 15 February 2011, Stardust-NExT encountered Tempel 1 from a distance of 181 km (112 mi). An estimated 72 images were acquired during the encounter. These showed changes in the terrain and revealed portions of the comet never seen by Deep Impact. The impact site from Deep Impact was also observed, though it was barely visible due to material settling back into the crater.

• Tempel 1 from the Stardust-NExT spacecraft during closest approach.
• 'Before and after' comparison images of Tempel 1 by Deep Impact (left) and Stardust (right).

End of extended mission

On 24 March 2011 at approximately 23:00 UTC, Stardust conducted a burn to consume its remaining fuel. The spacecraft had little fuel left and scientists hoped the data collected would help in the development of a more accurate system for estimating fuel levels on spacecraft. After the data had been collected, no further antenna aiming was possible and the transmitter was switched off. The spacecraft sent an acknowledgement from approximately 312 million km (194 million mi) away in space.

Sample return

At 05:57 UTC on 15 January 2006, the Sample Return Capsule successfully separated from Stardust and re-entered the Earth's atmosphere at 09:57 UTC, at a velocity of 12.9 km/s, the fastest reentry speed into Earth's atmosphere ever achieved by a man-made object. The capsule followed a drastic reentry profile, going from a velocity of Mach 36 to subsonic speed within 110 seconds. Peak deceleration was 34 g, encountered 40 seconds into the reentry at an altitude of 55 km over Spring Creek, Nevada. The PICA heat shield reached a temperature of more than 2,900 °C during this steep reentry. The capsule then parachuted to the ground, finally landing at 10:12 UTC at the Utah Test and Training Range (40°21.9′N 113°31.25′W / 40.3650°N 113.52083°W / 40.3650; -113.52083), near the U.S. Army Dugway Proving Ground. The capsule was then transported by military aircraft from Utah to Ellington Air Force Base in Houston, Texas, then transferred by road to the Planetary Materials Curatorial facility at Johnson Space Center in Houston to begin analysis. NASA officials claimed "prudence" dictated that the materials be transferred in secrecy, though no security threats were apparent.

[REDACTED] Stardust lands in Utah successfully at Wikinews

Sample processing

The sample container was taken to a clean room with a cleanliness factor 100 times that of a hospital operating room to ensure the interstellar and comet dust was not contaminated. Preliminary estimations suggested at least a million microscopic specks of dust were embedded in the aerogel collector. Ten particles were found to be at least 100 micrometers (0.1 mm) and the largest approximately 1000 micrometers (1 mm). An estimated 45 interstellar dust impacts were also found on the sample collector, which reside on the back side of the cometary dust collector. Dust grains are being observed and analyzed by a volunteer team through the distributed computing project, Stardust@Home.

In December 2006, seven papers were published in the scientific journal Science, discussing initial details of the sample analysis. Among the findings are: a wide range of organic compounds, including two that contain biologically usable nitrogen; indigenous aliphatic hydrocarbons with longer chain lengths than those observed in the diffuse interstellar medium; abundant amorphous silicates in addition to crystalline silicates such as olivine and pyroxene, proving consistency with the mixing of Solar System and interstellar matter, previously deduced spectroscopically from ground observations; hydrous silicates and carbonate minerals were found to be absent, suggesting a lack of aqueous processing of the cometary dust; limited pure carbon (CHON) was also found in the samples returned; methylamine and ethylamine was found in the aerogel but was not associated with specific particles.

In 2010, Dr. Andrew Westphal announced that Stardust@home volunteer Bruce Hudson found a track (labeled "I1043,1,30") among the many images of the aerogel that may contain an interstellar dust grain. The program allows for any volunteer discoveries to be recognized and named by the volunteer. Hudson named his discovery "Orion".

In April 2011, scientists from the University of Arizona discovered evidence for the presence of liquid water in comet Wild 2. They have found iron and copper sulfide minerals that must have formed in the presence of water. The discovery shatters the existing paradigm that comets never get warm enough to melt their icy bulk. In the spring of 2014, the recovery of particles of interstellar dust from the Discovery program's Stardust mission was announced.

[REDACTED] Stardust comet samples "visible to the naked eye" at Wikinews

Spacecraft location

The return capsule is currently located at the National Air and Space Museum in Washington, DC. It began exhibition there on October 1, 2008, the 50th anniversary of the establishment of NASA. The return capsule is displayed in sample collection mode, alongside a sample of the aerogel used to collect samples.

Results

The comet samples show that the outer regions of the early Solar System were not isolated and were not a refuge where interstellar materials could commonly survive. The data suggest that high-temperature inner Solar System material formed and was subsequently transferred to the Kuiper Belt.

Glycine

In 2009 it was announced by NASA that scientists had identified one of the fundamental chemical building blocks of life in a comet for the first time: glycine, an amino acid, was detected in the material ejected from Comet Wild 2 in 2004 and grabbed by the Stardust probe. Glycine has been detected in meteorites before and there are also observations in interstellar gas clouds, but the Stardust find is described as a first in cometary material. Isotope analysis indicates that the Late Heavy Bombardment included cometary impacts after the Earth coalesced but before life evolved. Carl Pilcher, who leads NASA's Astrobiology Institute commented that "The discovery of glycine in a comet supports the idea that the fundamental building blocks of life are prevalent in space, and strengthens the argument that life in the Universe may be common rather than rare."

See also

• List of missions to comets
• Genesis
• Hayabusa
• List of unmanned spacecraft by program
• Robotic spacecraft
• Space exploration
• Space probe
• Timeline of artificial satellites and space probes
• Timeline of first orbital launches by country
• Timeline of Solar System exploration

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39. ^ "Stardust Reentry Simulation". YouTube user "Evelyn Parker". 2013-09-13. Data in the simulation agrees with readings by the airborne observation team monitoring the reentry, available at "Stardust Capsule Reentry Movie". YouTube user "jotape". 2006-02-01.
40. ReVelle, D. O.; Edwards, W. N. (2007). "Stardust – An artificial, low-velocity "meteor" fall and recovery: 15 January 2006" (PDF). Meteoritics & Planetary Science. 42. The Meteoritical Society: 271–299. Bibcode:2007M&PS...42..271R. doi:10.1111/j.1945-5100.2007.tb00232.x.
41. Winter, Michael W.; Trumble, Kerry A. (2010). "Spectroscopic Observation of the Stardust Re-Entry in the Near UV with SLIT: Deduction of Surface Temperatures and Plasma Radiation" (PDF). NASA.
42. "NASA's Comet Tale Draws to a Successful Close in Utah Desert". NASA. Retrieved 2008-03-04.
43. "Stardust's Cargo Comes to Houston under Veil of Secrecy". chron.com. Retrieved 2008-03-04.
44. "The building blocks of planets within the 'terrestrial' region of protoplanetary disks". University of Nottingham. Retrieved 2008-03-04.
45. Rincon, Paul (2010-03-05). "Probe may have found cosmic dust". BBC.
46. Westphal, A. J.; Allen, C.; Bajt, S.; Bastien, R.; Bechtel, H.; Bleuet, P.; Borg, J.; Brenker, F.; Bridges, J.; et al. Analysis of "Midnight" Tracks in the Stardust Interstellar Dust Collector: Possible Discovery of a Contemporary Interstellar Dust Grain (PDF). 41st Lunar and Planetary Science Conference.
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49. https://airandspace.si.edu/multimedia-gallery/2008-13195hjpg
50. Brownlee, Don (2014-02-05). "The Stardust Mission: Analyzing Samples from the Edge of the Solar System". Annual Review of Earth and Planetary Sciences. 42: 179–205. Bibcode:2014AREPS..42..179B. doi:10.1146/annurev-earth-050212-124203.
51. Matzel, Jennifer E. P. (2010-04-23). "Constraints on the Formation Age of Cometary Material from the NASA Stardust Mission". Science. 328 (5977): 483–486. Bibcode:2010Sci...328..483M. doi:10.1126/science.1184741. PMID 20185683.
52. Morbidelli, A.; Chambers, J.; Lunine, J. I.; Petit, J. M.; Robert, F.; Valsecchi, G. B.; Cyr, K. E. (February 2010). "Source regions and timescales for the delivery of water to the Earth". Meteoritics & Planetary Science. 35 (6): 1309–1320. Bibcode:2000M&PS...35.1309M. doi:10.1111/j.1945-5100.2000.tb01518.x.
53. "'Life chemical' detected in comet". BBC News. 2009-08-18.

External links

• Stardust website at NASA.gov
• Stardust website by NASA's Jet Propulsion Laboratory
• Stardust-NExT website by NASA's Jet Propulsion Laboratory

v t e NASA Planetary Missions Program Office
Discovery program Missions Main NEAR Shoemaker Mars Pathfinder Lunar Prospector Stardust Genesis CONTOUR MESSENGER Deep Impact Dawn Kepler GRAIL InSight Lucy Psyche VERITAS DAVINCI Opportunity ASPERA-3 EPOXI NExT Moon Mineralogy Mapper Strofio MEGANE Proposals Finalists Mission 12 Comet Hopper Titan Mare Explorer Mission 13 and 14 NEOCam Mission 15 and 16 Io Volcano Observer Trident Candidates Enceladus Life Finder Icebreaker Life ISOCHRON JET LIFE MANTIS Mars Geyser Hopper Moon Diver PADME Phobos Surveyor Whipple
New Frontiers program Missions New Horizons Juno OSIRIS-REx Dragonfly Proposals Finalists Mission 2 MoonRise Mission 3 MoonRise SAGE Mission 4 CAESAR Candidates CONDOR CORSAIR ELF ELSAH Oceanus SPRITE VICI VISAGE VOX
Solar System Exploration program Missions DART JUICE instruments Europa Clipper
Underline indicates active current missions Italics indicate missions yet to launch Symbol indicates failure en route or before intended mission data returned

v t e Spacecraft missions to minor planets and comets
List of minor planets and comets visited by spacecraft List of artificial objects on extraterrestrial surfaces
Active	New Horizons (multiple flybys) OSIRIS-APEX (orbiter) Hayabusa2♯ (lander) Lucy (multiple flybys) Psyche (orbiter) Hera (orbiter) AIDA
Past	Flybys Cassini–Huygens Chang'e 2 Clementine CONTOUR Deep Impact EPOXI Deep Space 1 Galileo Halley Armada Giotto Sakigake Suisei Vega 1 Vega 2 International Cometary Explorer LICIACube NEA Scout NEAR Shoemaker Pioneer 7 PROCYON Rosetta Stardust Ulysses Orbiters Dawn NEAR Shoemaker Rosetta Timeline Landers Hayabusa MINERVA Hayabusa2 MASCOT Rover-1A / HIBOU Rover-1B / OWL Rover-2 NEAR Shoemaker Philae Impactors Deep Impact DART AIDA Sample return Hayabusa Hayabusa2 Stardust OSIRIS-REx
Planned	Tianwen-2 (multiple flybys and sample return, 2025) DESTINY+ (multiple flybys, 2028) MBR Explorer (multiple flybys and orbiter, 2028) Comet Interceptor (flyby, 2029)
Proposed	Shensuo (flybys, 2024) ASTER (orbiter, 2025) Ramses (2029) Interstellar Probe (flyby, 2030–2042)
Cancelled or not developed	AGORA AIM Asteroid Redirect Mission Athena CAESAR Castalia Centaurus Chimera Clementine 2 Comet Hopper CONDOR CORSAIR CRAF Don Quijote HAMMER Hayabusa Mk2 Janus MAOSEP MANTIS Marco Polo New Horizons 2 OKEANOS Vesta
Related	Asteroid belt Asteroid capture Asteroid mining Colonization of asteroids Ceres Pluto Exploration Small Solar System bodies Near-Earth object Trans-Neptunian object Colonization Trojan Vesta
Probes are listed in chronological order of launch. indicates mission failures.

v t e Spacecraft missions to minor planets and comets
List of minor planets and comets visited by spacecraft List of artificial objects on extraterrestrial surfaces
Active	New Horizons (multiple flybys) OSIRIS-APEX (orbiter) Hayabusa2♯ (lander) Lucy (multiple flybys) Psyche (orbiter) Hera (orbiter) AIDA
Past	Flybys Cassini–Huygens Chang'e 2 Clementine CONTOUR Deep Impact EPOXI Deep Space 1 Galileo Halley Armada Giotto Sakigake Suisei Vega 1 Vega 2 International Cometary Explorer LICIACube NEA Scout NEAR Shoemaker Pioneer 7 PROCYON Rosetta Stardust Ulysses Orbiters Dawn NEAR Shoemaker Rosetta Timeline Landers Hayabusa MINERVA Hayabusa2 MASCOT Rover-1A / HIBOU Rover-1B / OWL Rover-2 NEAR Shoemaker Philae Impactors Deep Impact DART AIDA Sample return Hayabusa Hayabusa2 Stardust OSIRIS-REx
Planned	Tianwen-2 (multiple flybys and sample return, 2025) DESTINY+ (multiple flybys, 2028) MBR Explorer (multiple flybys and orbiter, 2028) Comet Interceptor (flyby, 2029)
Proposed	Shensuo (flybys, 2024) ASTER (orbiter, 2025) Ramses (2029) Interstellar Probe (flyby, 2030–2042)
Cancelled or not developed	AGORA AIM Asteroid Redirect Mission Athena CAESAR Castalia Centaurus Chimera Clementine 2 Comet Hopper CONDOR CORSAIR CRAF Don Quijote HAMMER Hayabusa Mk2 Janus MAOSEP MANTIS Marco Polo New Horizons 2 OKEANOS Vesta
Related	Asteroid belt Asteroid capture Asteroid mining Colonization of asteroids Ceres Pluto Exploration Small Solar System bodies Near-Earth object Trans-Neptunian object Colonization Trojan Vesta
Probes are listed in chronological order of launch. indicates mission failures.

v t e Comets
Features Nucleus Coma Tails Antitail Comet dust Meteor shower Types Periodic Numbered Lost Long period Halley-type Jupiter-family Encke-type Main-belt Non-periodic Near-parabolic Hyperbolic Unknown-orbit Great Comet Sungrazing (Kreutz) Extinct Exocomet Interstellar Related Naming of comets Observational history of comets Centaur Comet discoverers LINEAR Extraterrestrial atmosphere Oort cloud Small Solar System body Asteroid Exploration List of missions to comets List of comets visited by spacecraft Latest C/2024 S1 (ATLAS) C/2024 G3 (ATLAS) C/2023 P1 (Nishimura) C/2023 H2 (Lemmon) C/2023 E1 (ATLAS) C/2023 A3 (Tsuchinshan–ATLAS) C/2022 E3 (ZTF) C/2021 O3 (PanSTARRS) C/2021 J1 (Maury-Attard) C/2021 A1 (Leonard) C/2020 F8 (SWAN) C/2020 F5 (MASTER) C/2020 F3 (NEOWISE) C/2019 Y4 (ATLAS) C/2019 Y1 (ATLAS) C/2019 U6 (Lemmon) 2I/Borisov P/2019 LD2 (ATLAS) C/2018 Y1 (Iwamoto) C/2018 C2 (Lemmon) C/2017 U7 C/2017 K2 (PanSTARRS) C/2016 U1 (NEOWISE) C/2015 V2 (Johnson) C/2015 G2 (MASTER) C/2015 ER61 (PanSTARRS) C/2014 UN271 (Bernardinelli–Bernstein) C/2014 Q2 (Lovejoy) C/2014 Q1 (PanSTARRS) Culture and speculation Antimatter comet Comets in fiction Comet vintages
Lists of comets (more) Periodic comets Until 1985 (all) 1P/Halley 2P/Encke 3D/Biela 4P/Faye 5D/Brorsen 6P/d'Arrest 7P/Pons–Winnecke 8P/Tuttle 9P/Tempel 10P/Tempel 11P/Tempel–Swift–LINEAR 12P/Pons–Brooks 13P/Olbers 14P/Wolf 15P/Finlay 16P/Brooks 17P/Holmes 18D/Perrine–Mrkos 19P/Borrelly 20D/Westphal 21P/Giacobini–Zinner 22P/Kopff 23P/Brorsen–Metcalf 24P/Schaumasse 25D/Neujmin 26P/Grigg–Skjellerup 27P/Crommelin 28P/Neujmin 29P/Schwassmann–Wachmann 30P/Reinmuth 31P/Schwassmann–Wachmann 32P/Comas Solà 33P/Daniel 34D/Gale 35P/Herschel–Rigollet 36P/Whipple 37P/Forbes 38P/Stephan–Oterma 39P/Oterma 40P/Väisälä 41P/Tuttle–Giacobini–Kresák 42P/Neujmin 43P/Wolf–Harrington 44P/Reinmuth 45P/Honda–Mrkos–Pajdušáková 46P/Wirtanen 47P/Ashbrook–Jackson 48P/Johnson 49P/Arend–Rigaux 50P/Arend 51P/Harrington 52P/Harrington–Abell 53P/Van Biesbroeck 54P/de Vico–Swift–NEAT 55P/Tempel–Tuttle 56P/Slaughter–Burnham 57P/du Toit–Neujmin–Delporte 58P/Jackson–Neujmin 59P/Kearns–Kwee 60P/Tsuchinshan 61P/Shajn–Schaldach 62P/Tsuchinshan 63P/Wild 64P/Swift–Gehrels 65P/Gunn 66P/du Toit 67P/Churyumov–Gerasimenko 68P/Klemola 69P/Taylor 70P/Kojima 71P/Clark 72P/Denning–Fujikawa 73P/Schwassmann–Wachmann 74P/Smirnova–Chernykh 75D/Kohoutek 76P/West–Kohoutek–Ikemura 77P/Longmore 78P/Gehrels 79P/du Toit–Hartley 80P/Peters–Hartley 81P/Wild 82P/Gehrels 83D/Russell 84P/Giclas 85D/Boethin After 1985 (notable) 88P/Howell 92P/Sanguin 96P/Machholz 97P/Metcalf–Brewington 103P/Hartley 107P/Wilson–Harrington 108P/Ciffréo 109P/Swift–Tuttle 122P/de Vico 126P/IRAS 141P/Machholz 144P/Kushida 147P/Kushida–Muramatsu 153P/Ikeya–Zhang 156P/Russell–LINEAR 161P/Hartley–IRAS 162P/Siding Spring 168P/Hergenrother 169P/NEAT 177P/Barnard 178P/Hug–Bell 205P/Giacobini 209P/LINEAR 238P/Read 246P/NEAT 249P/LINEAR 252P/LINEAR 255P/Levy 273P/Pons–Gambart 289P/Blanpain 311P/PanSTARRS 322P/SOHO 323P/SOHO 332P/Ikeya–Murakami 333P/LINEAR 354P/LINEAR 362P 460P/PanSTARRS Comet-like asteroids 596 Scheila 2060 Chiron (95P) 4015 Wilson–Harrington (107P) 7968 Elst–Pizarro (133P) 165P/LINEAR 166P/NEAT 167P/CINEOS 60558 Echeclus (174P) 118401 LINEAR (176P) 238P/Read 259P/Garradd 311P/PanSTARRS 324P/La Sagra 331P/Gibbs 354P/LINEAR 358P/PANSTARRS P/2013 R3 (Catalina-PANSTARRS) (300163) 2006 VW139 Lost Recovered 9P/Tempel 11P/Tempel–Swift–LINEAR 15P/Finlay 17P/Holmes 27P/Crommelin 54P/de Vico–Swift–NEAT 55P/Tempel–Tuttle 57P/du Toit–Neujmin–Delporte 69P/Taylor 72P/Denning–Fujikawa 80P/Peters–Hartley 97P/Metcalf–Brewington 107P/Wilson–Harrington 113P/Spitaler 122P/de Vico 157P/Tritton 205P/Giacobini 206P/Barnard–Boattini 226P/Pigott–LINEAR–Kowalski 271P/van Houten–Lemmon 289P/Blanpain Destroyed 3D/Biela D/1993 F2 (Shoemaker–Levy 9) Not found D/1770 L1 (Lexell) 5D/Brorsen 18D/Perrine–Mrkos 20D/Westphal 25D/Neujmin 34D/Gale 75D/Kohoutek 83D/Russell 85D/Boethin Visited by spacecraft 21P/Giacobini–Zinner (1985) 1P/Halley (1986) 26P/Grigg–Skjellerup (1992) 19P/Borrelly (2001) 81P/Wild (2004) 9P/Tempel (2005, 2011) C/2006 P1 (2007) 103P/Hartley (2010) 67P/Churyumov–Gerasimenko (2014) Near-Parabolic comets (notable) Until 1990 C/-43 K1 (Caesar's Comet) X/1106 C1 (Great Comet of 1106) C/1264 N1 (Great Comet of 1264) C/1402 D1 (Great Comet of 1402) C/1471 Y1 (Great Comet of 1472) C/1577 V1 (Great Comet of 1577) C/1652 Y1 C/1680 V1 (Great Comet of 1680, Kirsch's Comet, Newton's Comet)) C/1702 H1 (Comet of 1702) C/1729 P1 (Comet of 1729, Comet Sarabat) C/1743 X1 (Great Comet of 1744, Comet Klinkenberg-Chéseaux) C/1760 A1 (Great Comet of 1760) C/1769 P1 (Great Comet of 1769) C/1807 R1 (Great Comet of 1807) C/1811 F1 (Great Comet of 1811) C/1819 N1 (Great Comet of 1819) C/1823 Y1 (Great Comet of 1823) C/1843 D1 (Great March Comet of 1843) C/1847 T1 (Miss Mitchell's Comet) C/1858 L1 (Comet Donati) C/1861 G1 (Comet Thatcher) C/1861 J1 (Great Comet of 1861) C/1865 B1 (Great Southern Comet of 1865) X/1872 X1 (Pogson's Comet) C/1874 H1 (Comet Coggia) C/1881 K1 (Comet Tebbutt) C/1882 R1 (Great Comet of 1882) C/1887 B1 (Great Southern Comet of 1887) C/1901 G1 (Great Comet of 1901) C/1910 A1 (Great January Comet of 1910) C/1911 O1 (Brooks) C/1911 S3 (Beljawsky) C/1927 X1 (Skjellerup–Maristany) C/1931 P1 (Ryves) C/1941 B2 (de Kock-Paraskevopoulos) C/1947 X1 (Southern Comet) C/1948 V1 (Eclipse) C/1956 R1 (Arend–Roland) C/1957 P1 (Mrkos) C/1961 O1 (Wilson-Hubbard) [de] C/1961 R1 (Humason) C/1962 C1 (Seki-Lines) C/1963 A1 (Ikeya) C/1963 R1 (Pereyra) C/1964 N1 (Ikeya) C/1965 S1 (Ikeya-Seki) C/1969 T1 (Tago-Sato-Kosaka) [de] C/1969 Y1 (Bennett) C/1970 K1 (White–Ortiz–Bolelli) C/1973 E1 (Kohoutek) C/1975 V1 (West) C/1980 E1 (Bowell) C/1983 H1 (IRAS–Araki–Alcock) C/1989 W1 (Aarseth-Brewington) C/1989 X1 (Austin) C/1989 Y1 (Skorichenko–George) After 1990 C/1990 K1 (Levy) C/1992 J1 (Spacewatch–Rabinowitz) C/1993 Y1 (McNaught–Russell) C/1995 O1 (Hale–Bopp) C/1996 B2 (Hyakutake) C/1997 L1 (Zhu–Balam) C/1998 H1 (Stonehouse) C/1998 J1 (SOHO) C/1999 F1 (Catalina) C/1999 S4 (LINEAR) C/2000 WM1 (LINEAR) C/2001 A2 (LINEAR) C/2001 OG108 (LONEOS) C/2001 Q4 (NEAT) C/2002 T7 (LINEAR) C/2002 V1 (NEAT) C/2004 F4 (Bradfield) C/2004 Q2 (Machholz) C/2006 A1 (Pojmański) C/2006 M4 (SWAN) C/2006 P1 (McNaught) C/2007 E2 (Lovejoy) C/2007 F1 (LONEOS) C/2007 N3 (Lulin) C/2007 Q3 (Siding Spring) C/2007 W1 (Boattini) C/2009 F6 (Yi–SWAN) C/2009 R1 (McNaught) C/2010 X1 (Elenin) C/2011 L4 (PANSTARRS) C/2011 W3 (Lovejoy) C/2012 E2 (SWAN) C/2012 F6 (Lemmon) C/2012 K1 (PANSTARRS) C/2012 S1 (ISON) C/2013 A1 (Siding Spring) C/2013 R1 (Lovejoy) C/2013 US10 (Catalina) C/2013 V5 (Oukaimeden) C/2014 E2 (Jacques) C/2014 Q1 (PanSTARRS) C/2014 Q2 (Lovejoy) C/2015 ER61 (PanSTARRS) C/2015 V2 (Johnson) C/2017 K2 (PanSTARRS) 1I/2017 U1 ʻOumuamua C/2018 Y1 (Iwamoto) 2I/Borisov C/2019 U6 (Lemmon) C/2019 Y4 (ATLAS) C/2020 F3 (NEOWISE) C/2020 F8 (SWAN) C/2021 A1 (Leonard) C/2022 E3 (ZTF) C/2023 A3 (Tsuchinshan–ATLAS) C/2023 P1 (Nishimura) After 1910 (by name) Aarseth-Brewington Arend–Roland Austin Beljawsky Bennett Boattini Borisov Bowell Bradfield Brooks Catalina C/1999 F1 C/2013 US10 de Kock–Paraskevopoulos Eclipse Elenin Hale-Bopp Humason Hyakutake Ikeya C/1963 A1 C/1964 N1 Ikeya-Seki IRAS–Araki–Alcock ISON Iwamoto Jacques Johnson Kohoutek Lemmon C/2012 F6 C/2018 C2 C/2019 U6 Leonard Levy LINEAR C/1999 S4 C/2000 WM1 C/2001 A2 C/2002 T7 LONEOS C/2001 OG108 C/2007 F1 Lovejoy C/2007 E2 C/2011 W3 C/2013 R1 C/2014 Q2 Lulin Machholz McNaught C/2006 P1 C/2009 R1 McNaught–Russell Mrkos NEAT C/2001 Q4 C/2002 V1 NEOWISE Nishimura Oukaimeden ʻOumuamua Pan-STARRS C/2011 L4 C/2012 K1 311P/PanSTARRS C/2014 Q1 C/2015 ER61 C/2017 K2 Pereyra Pojmański Ryves Seki–Lines Siding Spring C/2007 Q3 C/2013 A1 Skjellerup–Maristany Skorichenko–George SOHO Southern Spacewatch–Rabinowitz Stonehouse SWAN C/2006 M4 C/2012 E2 C/2020 F8 Tago-Sato-Kosaka [de] Tsuchinshan–ATLAS West White–Ortiz–Bolelli Wilson–Hubbard [de] Yi–SWAN Zhu–Balam ZTF
Category

• NASA space probes
• Missions to comets
• Discovery Program
• Derelict satellites in heliocentric orbit
• Sample return missions
• Spacecraft launched in 1999
• Spacecraft launched by Delta II rockets
• Missions to main-belt asteroids
• Derelict space probes