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Items: 1 to 20 of 98

1.

Radar-enabled recovery of the Sutter's Mill meteorite, a carbonaceous chondrite regolith breccia.

Jenniskens P, Fries MD, Yin QZ, Zolensky M, Krot AN, Sandford SA, Sears D, Beauford R, Ebel DS, Friedrich JM, Nagashima K, Wimpenny J, Yamakawa A, Nishiizumi K, Hamajima Y, Caffee MW, Welten KC, Laubenstein M, Davis AM, Simon SB, Heck PR, Young ED, Kohl IE, Thiemens MH, Nunn MH, Mikouchi T, Hagiya K, Ohsumi K, Cahill TA, Lawton JA, Barnes D, Steele A, Rochette P, Verosub KL, Gattacceca J, Cooper G, Glavin DP, Burton AS, Dworkin JP, Elsila JE, Pizzarello S, Ogliore R, Schmitt-Kopplin P, Harir M, Hertkorn N, Verchovsky A, Grady M, Nagao K, Okazaki R, Takechi H, Hiroi T, Smith K, Silber EA, Brown PG, Albers J, Klotz D, Hankey M, Matson R, Fries JA, Walker RJ, Puchtel I, Lee CT, Erdman ME, Eppich GR, Roeske S, Gabelica Z, Lerche M, Nuevo M, Girten B, Worden SP; Sutter’s Mill Meteorite Consortium..

Science. 2012 Dec 21;338(6114):1583-7. doi: 10.1126/science.1227163.

PMID:
23258889
2.

The fall, recovery, orbit, and composition of the Tagish Lake meteorite: a new type of carbonaceous chondrite.

Brown PG, Hildebrand AR, Zolensky ME, Grady M, Clayton RN, Mayeda TK, Tagliaferri E, Spalding R, MacRae ND, Hoffman EL, Mittlefehldt DW, Wacker JF, Bird JA, Campbell MD, Carpenter R, Gingerich H, Glatiotis M, Greiner E, Mazur MJ, McCausland PJ, Plotkin H, Rubak Mazur T.

Science. 2000 Oct 13;290(5490):320-5.

3.

Processing of meteoritic organic materials as a possible analog of early molecular evolution in planetary environments.

Pizzarello S, Davidowski SK, Holland GP, Williams LB.

Proc Natl Acad Sci U S A. 2013 Sep 24;110(39):15614-9. doi: 10.1073/pnas.1309113110. Epub 2013 Sep 9.

4.

Spectral Properties of Near-Earth Asteroids: Evidence for Sources of Ordinary Chondrite Meteorites

Binzel RP, Bus SJ, Burbine TH, Sunshine JM.

Science. 1996 Aug 16;273(5277):946-8.

PMID:
8688076
5.

Meteoritics. Sutter's Mill meteorite produces mother lode of research.

Underwood E.

Science. 2012 Dec 21;338(6114):1521. doi: 10.1126/science.338.6114.1521. No abstract available.

PMID:
23258859
6.

The Tagish Lake meteorite: a possible sample from a D-type asteroid.

Hiroi T, Zolensky ME, Pieters CM.

Science. 2001 Sep 21;293(5538):2234-6. Epub 2001 Aug 23.

7.

Origin and evolution of prebiotic organic matter as inferred from the Tagish Lake meteorite.

Herd CD, Blinova A, Simkus DN, Huang Y, Tarozo R, Alexander CM, Gyngard F, Nittler LR, Cody GD, Fogel ML, Kebukawa Y, Kilcoyne AL, Hilts RW, Slater GF, Glavin DP, Dworkin JP, Callahan MP, Elsila JE, De Gregorio BT, Stroud RM.

Science. 2011 Jun 10;332(6035):1304-7. doi: 10.1126/science.1203290.

8.

Discovery of a main-belt asteroid resembling ordinary chondrite meteorites.

Binzel RP, Xu S, Bus SJ, Skrutskie MF, Meyer MR, Knezek P, Barker ES.

Science. 1993 Dec 3;262(5139):1541-3.

PMID:
17829382
9.

Asteroids: surface composition from reflection spectroscopy.

McCord TB, Gaffey MJ.

Science. 1974 Oct 25;186(4161):352-5.

PMID:
17839866
10.

Petrography, stable isotope compositions, microRaman spectroscopy, and presolar components of Roberts Massif 04133: A reduced CV3 carbonaceous chondrite.

Davidson J, Schrader DL, Alexander CM, Lauretta DS, Busemann H, Franchi IA, Greenwood RC, Connolly HC Jr, Domanik KJ, Verchovsky A.

Meteorit Planet Sci. 2014 Dec;49(12):2133-2151. Epub 2014 Nov 7.

11.

Photographic observations of Neuschwanstein, a second meteorite from the orbit of the Príbram chondrite.

Spurný P, Oberst J, Heinlein D.

Nature. 2003 May 8;423(6936):151-3.

PMID:
12736679
12.

Discovery of a 25-cm asteroid clast in the giant Morokweng impact crater, South Africa.

Maier WD, Andreoli MA, McDonald I, Higgins MD, Boyce AJ, Shukolyukov A, Lugmair GW, Ashwal LD, Gräser P, Ripley EM, Hart RJ.

Nature. 2006 May 11;441(7090):203-6.

PMID:
16688173
13.

Video observations, atmospheric path, orbit and fragmentation record of the fall of the Peekskill meteorite.

Ceplecha Z, Brown P, Hawkes RL, Wetherill G, Beech M, Mossman K.

Earth Moon Planets. 1996 Feb;72(1-3):395-404.

PMID:
11539206
14.

An anomalous basaltic meteorite from the innermost main belt.

Bland PA, Spurny P, Towner MC, Bevan AW, Singleton AT, Bottke WF Jr, Greenwood RC, Chesley SR, Shrbeny L, Borovicka J, Ceplecha Z, McClafferty TP, Vaughan D, Benedix GK, Deacon G, Howard KT, Franchi IA, Hough RM.

Science. 2009 Sep 18;325(5947):1525-7. doi: 10.1126/science.1174787.

15.

Thermal fatigue as the origin of regolith on small asteroids.

Delbo M, Libourel G, Wilkerson J, Murdoch N, Michel P, Ramesh KT, Ganino C, Verati C, Marchi S.

Nature. 2014 Apr 10;508(7495):233-6. doi: 10.1038/nature13153. Epub 2014 Apr 2.

PMID:
24695219
16.

Rhenium-osmium isotope systematics of carbonaceous chondrites.

Walker RJ, Morgan JW.

Science. 1989 Jan 27;243(4890):519-22.

PMID:
17799187
17.

Accretion and differentiation of carbon in the early Earth.

Tingle TN.

Chem Geol. 1998 May 15;147(1-2):3-10.

PMID:
11543125
18.

Carbon isotope composition of individual amino acids in the Murchison meteorite.

Engel MH, Macko SA, Silfer JA.

Nature. 1990 Nov 1;348(6296):47-9.

PMID:
11536470
19.

Evidence of thermal metamorphism on the C, g, B, and f asteroids.

Hiroi T, Pieters CM, Zolensky ME, Lipschutz ME.

Science. 1993 Aug 20;261(5124):1016-8.

PMID:
17739619
20.

The micro-distribution of carbonaceous matter in the Murchison meteorite as investigated by Raman imaging.

El Amri C, Maurel MC, Sagon G, Baron MH.

Spectrochim Acta A Mol Biomol Spectrosc. 2005 Jul;61(9):2049-56.

PMID:
15911391

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