253 Mathilde

253 Mathilde
(253) mathilde.jpg
NASA image of 253 Mathilde
Discovery[1]
Discovered by Johann Palisa
Discovery date November 12, 1885
Designations
Pronunciation /məˈtɪldə/
Alternate name(s) 1949 OL1, A915 TN
Minor planet
category		 Main belt
Epoch January 30, 2005 (JD 2453400.5)
Aphelion 501.334 Gm
3.35121 AU
Perihelion 290.564 Gm
1.94230 AU
Semi-major axis 395.949 Gm
2.64676 AU
Eccentricity 0.266157
Orbital period 1572.787 d
(4.31 yr)
Average orbital speed 17.98 km/s[3]
Mean anomaly 111.960°
Inclination 6.738°
Longitude of ascending node 179.633°
Argument of perihelion 157.475°
Physical characteristics
Dimensions 52.8[2] km
(66×48×46 km[4])
Mass 1.033(±0.044)×1017[5] kg
Mean density 1.3[5] g/cm³
Equatorial surface gravity 0.00993  m/s²
Escape velocity 22.9 m/s
Rotation period 17.406±0.010[6] d
(17 d 9 h 45 min)
Albedo 0.0436[2]
Temperature ~174[7] K
Spectral type Cb[2]
Absolute magnitude (H) 10.20[2]

253 Mathilde (pronounced /məˈtɪldə/) is a main belt asteroid about 50 km in diameter that was discovered by Johann Palisa in 1885. It has a relatively elliptical orbit that requires more than four years to circle the Sun. This asteroid has an unusually slow rate of rotation, requiring 17.4 days to complete a 360° revolution about its axis. It is a primitive C-type asteroid, which means the surface has a high proportion of carbon; giving it a dark surface that reflects only 4% of the light that falls on it.[8]

This asteroid was visited by the NEAR Shoemaker spacecraft during June 1997, on its way to asteroid 433 Eros. During the flyby, the spacecraft imaged a hemisphere of the asteroid, revealing many large craters that have gouged out depressions in the surface. Until 21 Lutetia was visited in 2010, it was the largest asteroid to be visited by a spacecraft and the first C-type asteroid to be explored.

Contents

Observation history

In 1880, Johann Palisa, the director of the Austrian Naval Observatory, was offered a position as an assistant at the newly completed Vienna Observatory. The job represented a demotion for Johann, but in turn he would have access to the new 27-inch (690 mm) refractor; the largest telescope in the world at that time. By this point Johann had already discovered 27 asteroids, and he would employ the Vienna 27-inch (690 mm) and 12-inch (300 mm) instruments to find an additional 94 asteroids before he retired.[9]

Among the discoveries of Johann Palisa was the asteroid 253 Mathilde; found on November 12, 1885. The initial orbital elements of the asteroid were then computed by V. A. Lebeuf, another Austrian astronomer working at the observatory. The name of the asteroid was suggested by Lebeuf, after Mathilde, the wife of Moritz Leowy—who was the vice director of the Paris Observatory.[1][10]

In 1995, ground-based observations determined that 253 Mathilde is a C-type asteroid. It was also found to have an unusually long period of rotation.[10]

On June 27, 1997, the NEAR Shoemaker spacecraft passed within 1,212 km of 253 Mathilde while moving at a velocity of 9.93 km/s. This close approach allowed the spacecraft to capture over 500 images of the surface,[8] and provided data for more accurate determinations of the asteroid's dimensions and mass (based on gravitational perturbation of the spacecraft).[5] However, only one hemisphere of 253 Mathilde was imaged during the fly-by.[11] This was only the third asteroid to be imaged from a nearby distance, following 951 Gaspra and 243 Ida.

Description

One of the large craters on 253 Mathilde. NASA image.

253 Mathilde is very dark, with an albedo comparable to fresh asphalt,[12] and is thought to share the same composition as CI1 or CM2 carbonaceous chondrite meteorites, with a surface dominated by phyllosilicate minerals.[13] The asteroid has a number of extremely large craters, with the individual craters being named for coal fields and basins around the world.[14] The two largest craters, Ishikari (29.3 km) and Karoo (33.4 km), are as wide as the asteroid's average radius.[4] The impacts appear to have spalled large volumes off the asteroid, as suggested by the angular edges of the craters.[8] No differences in brightness or colour were visible in the craters and there was no appearance of layering, so the asteroid's interior must be very homogeneous. There are indications of material movement along the downslope direction.[4]

The density measured by NEAR Shoemaker, 1,300 kg/m³, is less than half that of a typical carbonaceous chondrite; this may indicate that the asteroid is very loosely packed rubble pile.[5] The same is true of several C-type asteroids studied by ground-based telescopes equipped with adaptive optics systems (45 Eugenia, 90 Antiope, 87 Sylvia and 121 Hermione). Up to 50% of the interior volume of 253 Mathilde consists of open space. However, the existence of a 20-km-long scarp may indicate that the asteroid does have some structural strength, so it could contain some large internal components.[11] The low interior density is an inefficient transmitter of impact shock through the asteroid, which also helps to preserve the surface features to a high degree.[4]

Mathilde's orbit is eccentric, taking it to the outer reaches of the Main belt. Nonetheless, the orbit lies entirely between the orbits of Mars and Jupiter; it does not cross the planetary orbits. It also has one of the slowest rotation periods of the known asteroids—most asteroids have a rotation period in the range of 2–24 hours.[15] Because of the slow rotation rate, NEAR Shoemaker was only able to photograph 60% of the asteroid's surface. The slow rate of rotation may be accounted for by a satellite orbiting the asteroid, but a search of the NEAR images revealed none larger than 10 km in diameter out to 20 times the radius of 253 Mathilde.[16]

See also

References

  1. 1.0 1.1 Moore, Sir Patrick (1999). The Wandering Astronomer. CRC Press. ISBN 0750306939. 
  2. 2.0 2.1 2.2 2.3 2.4 Unless otherwise noted, parameters are per: Yeomans, Donald K. (August 29, 2003). "253 Mathilde". JPL Small-Body Database Browser. NASA. http://ssd.jpl.nasa.gov/sbdb.cgi?sstr=253. Retrieved 2007-08-29. 
  3. For semi-major axis a, orbital period T and eccentricity e, the average orbital speed is given by:
    \begin{align} v_o & = \frac{2\pi a}{T}\left[1-\frac{e^2}{4}-\frac{3e^4}{64} - \dots \right] \\ & = 18.31\ \mbox{km/s} \left[ 1 - 0.0177 - 0.00008 - \cdots \right] \\ & \approx 17.98\ \mbox {km/s} \\ \end{align}\!\,
    For the circumference of an ellipse, see: H. St̀eocker, J. Harris (1998). Handbook of Mathematics and Computational Science. Springer. pp. 386. ISBN 0387947469. 
  4. 4.0 4.1 4.2 4.3 J. Veverka et al (1999). "NEAR Encounter with Asteroid 253 Mathilde: Overview". Icarus 140: 3–16. doi:10.1006/icar.1999.6120. http://adsabs.harvard.edu/abs/1999Icar..140....3V. Retrieved 2007-08-29. 
  5. 5.0 5.1 5.2 5.3 D. K. Yeomans et al (1997). "Estimating the mass of asteroid 253 Mathilde from tracking data during the NEAR flyby". Science 278 (5346): 2106–9. doi:10.1126/science.278.5346.2106. PMID 0009405343. http://www.sciencemag.org/cgi/content/full/278/5346/2106. Retrieved 2007-08-29. 
  6. Stefano Mottola et al (1995). "The slow rotation of 253 Mathilde". Planetary and Space Science 43 (12): 1609–1613. doi:10.1016/0032-0633(95)00127-1. http://adsabs.harvard.edu/abs/1995P&SS...43.1609M. Retrieved 2007-02-04. 
  7. For asteroid albedo α, semimajor axis a, solar luminosity L_0, Stefan-Boltzmann constant σ and the asteroid's infrared emissivity ε (~0.9), the approximate mean temperature T is given by:
    \begin{align} T & = \left ( \frac{(1 - \alpha) L_0}{\epsilon \sigma 16 \pi a^2} \right )^{\frac{1}{4}} \\ & = \left ( \frac{(1 - 0.0436) (3.827 \times 10^{26}\ \mbox{W})} {0.9 (5.670 \times 10^{-8}\ \mbox{W/m}^2\mbox{K}^4) 16 \cdot 3.142 (3.959 \times 10^{11}\ \mbox{m})^2} \right )^{\frac{1}{4}} \\ & = 173.7\ \mbox{K} \end{align}
    See: Torrence V. Johnson, Paul R. Weissman, Lucy-Ann A. McFadden (2007). Encyclopedia of the Solar System. Elsevier. pp. 294. ISBN 0120885891. 
  8. 8.0 8.1 8.2 Williams, David R. (December 18, 2001). "NEAR Flyby of Asteroid 253 Mathilde". NASA. http://nssdc.gsfc.nasa.gov/planetary/mission/near/near_mathilde.html. Retrieved 2006-08-10. 
  9. Raab, Herbert (2002). "Johann Palisa, the most successful visual discoverer of" (PDF). Astronomical Society of Linz. http://www.astrometrica.at/Papers/Palisa.pdf. Retrieved 2007-08-27. 
  10. 10.0 10.1 Savage, D.; Young, L.; Diller, G.; Toulouse, A. (February 1996). "Near Earth Asteroid Rendezvous (NEAR) Press Kit". NASA. http://www.nasa.gov/home/hqnews/presskit/1996/NEAR_Press_Kit/NEARpk.txt. Retrieved 2007-08-29. 
  11. 11.0 11.1 Cheng, Andrew F. (2004). "Implications of the NEAR mission for internal structure of Mathilde and Eros". Advances in Space Research 33 (9): 1558–1563. doi:10.1016/S0273-1177(03)00452-6. http://adsabs.harvard.edu/abs/2004AdSpR..33.1558C. Retrieved 2007-08-29. 
  12. Pon, Brian (June 30, 1999). "Pavement Albedo". Heat Island Group. http://eetd.lbl.gov/HeatIsland/Pavements/Albedo/. Retrieved 2007-08-27. 
  13. Kelley, M. S.; Gaffey, M. J.; Reddy, V. (March 12–16, 2007). "Near-IR Spectroscopy and Possible Meteorite Analogs for Asteroid (253)". 38th Lunar and Planetary Science Conference. League City, Texas: Lunar & Planetary Institute. pp. 2366. http://adsabs.harvard.edu/abs/2007LPI....38.2366K. Retrieved 2007-08-29. 
  14. Blue, Jennifer (August 29, 2007). "Categories for Naming Features on Planets and Satellites". USGS. http://planetarynames.wr.usgs.gov/append6.html#Asteroids. Retrieved 2007-08-29. 
  15. Lang, Kenneth R. (2003). "2. Asteroids and meteorites, Size, color and spin". NASA's Cosmos. NASA. http://ase.tufts.edu/cosmos/view_chapter.asp?id=15&page=3. Retrieved 2007-08-29. 
  16. W. J. Merline et al (1998). "Search for Satellites of 253 Mathilde from Near-Earth Asteroid Rendezvous Flyby Data". Meteoritics & Planetary Science 33: A105. doi:10.1006/icar.1999.6120. http://adsabs.harvard.edu/abs/1998M&PSA..33..105M. Retrieved 2007-08-29. 

External links

Minor planets navigator

252 Clementina       ·       253 Mathilde       ·       254 Augusta
Small Solar System bodies
Lists: Asteroid groups and families · Asteroid moons · Binary asteroids · Minor planets
See also: List of minor planets, Meanings of minor planet names, Pronunciation of asteroid names, and Solar System