SEARCH

SEARCH BY CITATION

References

  • Alexander C. M. O’D., Barber D. J., and Hutchison R. 1989. The microstructure of Semarkona and Bishunpur. Geochimica et Cosmochimica Acta 53:30453057.
  • Aoki T. and Akai J. 2008. Carbon materials in Antarctic and non-Antarctic carbonaceous chondrites: High-resolution transmission electron microscopy. Journal of Mineralogical and Petrological Sciences 103:173182.
  • Beckerling W. and Bischoff A. 1995. Occurrence and composition of relict minerals in micrometeorites from Greenland Antarctica—Implications for their origins. Planetary and Space Science 43:435449.
  • Bischoff A., Palme H., Ash R. D., Clayton R. N., Schultz L., Herpers U., Stöffler D., Grady M. M., Pillinger C. T., Sprttel B., Weber H., Grund T., Endreß M., and Weber D. 1993. Paired Renazzo-type (CR) carbonaceous chondrites from the Sahara. Geochimica et Cosmochimica Acta 57:15871603.
  • Bradley J. P., Germani M. S., and Brownlee D. E. 1989. Automated thin-film analyses of anhydrous interplanetary dust particles in the analytical electron microscope. Earth and Planetary Science Letters 93:113.
  • Brearley A. J. 1995. Aqueous alteration and brecciation in Bells, an unusual, saponite-bearing, CM chondrite. Geochimica et Cosmochimica Acta 59:22912317.
  • Duprat J., Engrand C., Maurette M., Gounelle M., Kurat G., and Fraiable L. H. 2005a. Micrometeorites from central Antarctica snow (abstract #1678). 36th Lunar and Planetary Science Conference. CD-ROM.
  • Duprat J., Engrand C., Maurette M., Gounelle M., Kurat G., and Hammer C. 2005b. The micrometeorites program at Dome C. The European Astronomical Society 14:5156.
  • Duprat J., Engrand C., Maurette M., Gounelle M., Kurat G., and Hammer C. 2007. Micrometeorites from central Antarctic snow: The CONCORDIA collection. Advances in Space Research 39:605611.
  • Endreß M., Keil K., Bischoff A., Spettel B., Clayton R. N., and Mayeda T. K. 1994. Origin of dark clasts in the Acfer 059/El Djouf 001 CR2 chondrite. Meteoritics 29:2640.
  • Engrand C. and Maurette M. 1998. Carbonaceous micrometeorites from Antarctica. Meteoritics & Planetary Science 33:565580.
  • Engrand C., Deloule E., Robert F., Murette M., and Kurat G. 1999. Extraterrestrial water in micrometeorites and cosmic spherules from Antarctica: An ion microprobe study. Meteoritics & Planetary Science 34:773786.
  • Flynn G. J., Durda D. D., Sandel L. E., Kreft J. W., and Strait M. M. 2009. Dust production from the hypervelocity impact disruption of the Murchison hydrous CM2 meteorite: Implications for the disruption of hydrous asteroids and the production of interplanetary dust. Planetary and Space Science 57:119126.
  • Gandolfi G. 1967. Discussion upon methods to obtain X-ray powder patterns from a single crystal. Mineralogica et Petrographica Acta 13:6774.
  • Garvie L. A. J. and Buseck P. R. 2004. Nanosized carbon-rich grains in carbonaceous chondrite meteorites. Earth and Planetary Science Letters 224:431439.
  • Genge M. J. 2006. Igneous rims on micrometeorites. Geochimica et Cosmochimica Acta 70:26032621.
  • Genge M. J. 2008. Micrometeorites and their implications for meteors. Earth, Moon, and Planets 102:525535.
  • Genge M. J., Grady M. M., and Hutchison R. 1997. The textures and compositions of fine-grained Antarctic micrometeorites: Implications for comparisons with meteorites. Geochimica et Cosmochimica Acta 61:51495162.
  • Genge M. J., Engrand C., Gounelle M., and Taylor S. 2008. The classification of micrometeorites. Meteoritics & Planetary Science 43:497515.
  • Grün E., Zook H. A., Fechitig H., and Giese R. H. 1985. Collisional balanace of the meteoritic complex. Icarus 62:244272.
  • Hanowski N. P. and Brearley A. J. 2000. Iron-rich aureoles in the CM carbonaceous chondrites Murray, Murchison, and Allan Hills 81002: Evidence for in situ aqueous alteration. Meteoritics & Planetary Science 35:12911308.
  • Hutchison R., Alexander C. M. O., and Barber D. J. 1987. The Semarkona meteorite: First recorded occurrence of smectite in an ordinary chondrite, and its implications. Geochimica et Cosmochimica Acta 51:18751882.
  • Jessberger E. K., Bohsung J., Chakaveh S., and Traxel K. 1992. The volatile element enrichment of chondritic interplanetary dust particles. Earth and Planetary Science Letters 112:9199.
  • Keller L. P. and Messenger S. 2004. On the origin of GEMS (abstract #1985). 35th Lunar and Planetary Science Conference. CD-ROM.
  • Keller L. P., Thomas L., and McKay D. S. 1992. An interplanetary dust particle with links to CI chondrites. Geochimica et Cosmochimica Acta 56:14091412.
  • Krot A. N., Meibom A., Weisberg M. K., and Keil K. 2002. The CR chondrite clan: Implications for early solar system processes. Meteoritics & Planetary Science 37:14511490.
  • Kurat G., Presper T., and Brandstätter F. 1992. CI-like micrometeorites from Cap Prudhomme, Antarctica (abstract). 23rd Lunar and Planetary Science Conference. pp. 747748.
  • Kurat G., Koeberl C., Presper T., Brandstätter F., and Maurette M. 1994. Petrology and geochemistry of Antarctic micrometeorites. Geochimica et Cosmochimica Acta 58:38793904.
  • Levison H. F., Bottke W. F., Gounelle M., Morbidelli A., Nesvorný D., and Tsiganis K. 2009. Contamination of the asteroid belt by primordial trans-Neptunian objects. Nature 460:364366.
  • Love S. G. and Brownlee D. E. 1993. A direct measurement of the terrestrial mass accretion rate of cosmic dust. Science 262:550553.
  • Matsunami S. 1984. Chemical compositions and textures of matrices and chondrule rims of eight unequilibrated ordinary chondrites: A preliminary report. Memoirs of National Institute of Polar Research (Special issue) 24:126148.
  • Maurette M., Olinger C., Michel-Levy M. C., Kurat G., Pourchet M., Brandstätter F., and Bourot-Denise M. 1991. A collection of diverse micrometeorites recovered from 100 tonnes of Antarctic blue ice. Nature 351:4447.
  • Messenger S., Nakamura-Messenger K., and Keller L. P. 2008. 15N-rich organic globules in a cluster IDP and the Bells CM2 chondrite (abstract #2391). 39th Lunar and Planetary Science Conference. CD-ROM.
  • Nakamura K., Zolensky M. E., Thomas S., and Tomeoka K. 2001a. In situ observation of carbonaceous globule in the Tagish Lake chondrites (abstract). Meteoritics & Planetary Science 36:A145.
  • Nakamura K., Messenger S., and Keller L. P. 2005. Experimental hydrothermal alteration of anhydrous IDPs (abstract). Meteoritics & Planetary Science 40:A5235.
  • Nakamura T. and Noguchi T. 2004. Characteristics of phyllosilicates in micrometeorites derived from synchrotron X-ray diffraction analysis (abstract). Meteoritics & Planetary Science 39:A76.
  • Nakamura T., Noguchi T., Yada T., Nakamuta Y., and Takaoka N. 2001b. Bulk mineralogy of individual micrometeorites determined by X-ray diffraction analysis and transmission electron microscopy. Geochimica et Cosmochimica Acta 23:43854397.
  • Nakamura T., Noguchi T., Zolensky M. E., and Tanaka M. 2003. Mineralogy and noble-gas signatures of the carbonate-rich lithology of the Tagish Lake carbonaceous chondrite: Evidence for an accretionary breccia. Earth and Planetary Science Letters 207:83101.
  • Nakamura T., Noguchi T., Tsuchiyama A., Ushikubo T., Kita N. T., Valley J. W., Zolensky M. E., Kakazu Y., Sakamoto K., Mashio E., Uesugi K., and Nakano T. 2008. Chondrulelike objects in short-period comet 81P/Wild 2. Science 321:16641667.
  • Nakamura-Messenger K., Messenger S., Keller L. P., Cleett S. J., and Zolensky M. E. 2006. Organic globules in the Tagish Lake meteorite: Remnants of the protosolar disk. Science 314:13491442.
  • Noguchi T., Nakamura T., and Nozaki W. 2002. Mineralogy of phyllosilicate-rich micrometeorites and comparison with Tagish Lake and Sayama meteorites. Earth and Planetary Science Letters 202:229246.
  • Noguchi T., Nakazawa A., Okunishi E., Naraoka H., Nakamura T., and Nakamura K. 2005. Carbonaceous nanoparticles in Tagish Lake and Ivuna: Why do they in Tagish Lake have nitrogen-enriched rims? (abstract). Meteoritics & Planetary Science 40:A115.
  • Noguchi T., Osonoi M., Nakamura T., Tsuchiyama A., and Imae N. 2006. Micrometeorites discovered from a surface snow near the Dome Fuji station, Antarctica (abstract). 30th Symposium on Antarctic Meteorites. pp. 8788.
  • Nozaki W., Nakamura T., and Noguchi T. 2006. Bulk mineralogical changes of hydrous micrometeorites during heating in the upper atmosphere at temperatures below 1000°C. Meteoritics & Planetary Science 41:10951114.
  • Rai V. K., Murty S. V. S., and Ott U. 2003. Nitrogen components in ureilites. Geochimica et Cosmochimica Acta 67:22132237.
  • Rietmeijer F. J. M. 1991. Aqueous alteration in five chondritic porous interplanetary dust particles. Earth and Planetary Science Letters 102:148157.
  • Rietmeijer F. J. M. and Mackinnon I. D. R. 1985. Layer silicates in a chondritic porous interplanetary dust particle. Proceedings, 16th Lunar and Planetary Science Conference, Part 1. Journal of Geophysical Research 90:D149D155.
  • Taylor S., Lever J. H., and Harvey R. P. 1998. Accretion rate of cosmic spherules measured at the South Pole. Nature 392:899903.
  • Thomas K. L., Zolensky M. E., Klöck W., and McKay D. S. 1990a. Mineralogical descriptions of eight hydrated interplanetary dust particles and their relationship to chondrite matrix (abstract #1250). 21st Lunar and Planetary Science Conference. CD-ROM.
  • Thomas K. L., Keller L. P., Zolensky M. E., Klöck W., and McKay D. S. 1990b. Compositions of smectite and seroentine phyllosilicates in hydrated interplanetary dust particled and their relationships to UOC and C3 chondrite matrices (abstract). Meteoritics & Planetary Science 25:A414.
  • Tomeoka K. 1991. Aqueous alteration in hydrated interplanetary dust particles (invited review). Astrophysics and Space Science Library 173:71.
  • Tomeoka K. and Buseck P. J. 1984. Transmission electron microscopy of the “LOW-CA” hydrated interplanetary dust particle. Earth and Planetary Science Letters 69:243254.
  • Tomeoka K. and Buseck P. R. 1986. A carbonate-rich, hydrated, interplanetary dust particle: Possible residue from protostellar clouds. Science 231:15441546.
  • Tomeoka K. and Buseck P. J. 1988. Matrix mineralogy of the Orgueil CI carbonaceous chondrite. Geochimica et Cosmochimica Acta 52:16271640.
  • Tomeoka K., Kiriyama K., Nakamura K., Yamahana Y., and Sekine T. 2003. Interplanetary dust from the explosive dispersal of hydrated asteroids by impacts. Nature 423:6062.
  • Weisberg M. K., Prinz M., Clayton R. N., and Mayeda K. 1993. The CR (Renazzo-type) carbonaceous group and its implications. Geochimica et Cosmochimica Acta 57:15671586.
  • Yada T., Nkamura T., Takaoka N., Noguchi T., Terada K., Yano H., Nakazawa T., and Kojima H. 2004. The global accretion rate of extraterrestrial materials in tha last glacial period estimated from the abundance of micrometeorites in Antarctic glacier ice. Earth, Planets and Space 56:6779.
  • Zolensky M. 1991. Mineralogy and matrix composition of “CR” chondrites Renazzo and EET 87770, and ungrouped chondrites Essebi and MAC 87300 (abstract). Meteoritics 26:414.
  • Zolensky M. and Lindstrom D. 1992. Mineralogy of 12 large “chondritic” interplanetary dust particles. Proceedings, 22nd Lunar and Planetary Science Conference. pp. 161169.
  • Zolensky M. E., Webb S. J., and Thomas K. 1988. The search for refractory interplanetary dust particles from preindustrial aged Antarctic ice. Proceedings, 18th Lunar and Planetary Science Conference. pp. 599605.
  • Zolensky M., Barrett R., and Browning L. 1993. Mineralogy and composition of matrix and chondrule rims in carbonaceous chondrites. Geochimica et Cosmochimica Acta 57:31233148.
  • Zolensky M. E., Nakamura K., Gounelle M., Mikouchi T., Kasama T., Tachikawa O., and Tonui E. 2002. Mineralogy of Tagish Lake: An ungrouped type 2 carbonaceous chondrite. Meteoritics & Planetary Science 37:737761.