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1. On the provenance of GEMS, a quarter century post discovery

Author

Bradley, John P, Ishii, Hope A, Bustillo, Karen, Ciston, James, Ogliore, Ryan, Stephan, Thomas, Brownlee, Donald E, and Joswiak, David J

Subjects
Earth Sciences, Geochemistry, Geology, Physical Geography and Environmental Geoscience, Geochemistry & Geophysics
Abstract

The provenance of GEMS (glass with embedded metal and sulfides) in cometary type interplanetary dust particles is investigated using analytical scanning transmission electron microscopy and secondary ion mass spectrometry. We review the current state of knowledge and closely examine the densities, elemental compositions and distributions, iron oxidation states, and isotopic compositions of a subset of GEMS in chondritic porous interplanetary dust. We find that GEMS are underdense with estimated densities that are 35–65% of compositionally equivalent crystalline aggregates. GEMS low densities result in a lower contribution to the bulk compositions of IDPs than has been assumed based on their volume fraction. We also find that element/Si ratios, assumed to be primary (indigenous), are instead perturbed by contamination and secondary alteration, including pulse heating during atmospheric entry. Fe in pyrrhotite inclusions was oxidized and Mg, S, Ca, and Fe were depleted relative to lithophile Al and Si, resulting in reduction in element/Si ratios. Because they trap outgassing elements, Fe-rich oxide rims that formed on the surface of GEMS are serendipitous “witness plates” to the changes in composition that accompany atmospheric entry. As a result of alteration, GEMS elemental compositions cannot reliably inform about their provenance. Except for highly anomalous oxygen isotope ratios measured in some large GEMS grains that indicate a contribution from circumstellar dust, oxygen isotope compositions are generally poor indicators of provenance. Prior work indicates that most GEMS fall close to the terrestrial oxygen isotope composition, which, however, does not exclude a presolar interstellar origin. Nitrogen isotopic compositions are more diagnostic. Elevated 15N/14N ratios indicate that GEMS accreted in conjunction with formation of organic matter by ion–molecule reactions in a cold (

Published
2022

3. Oxygen Isotopic Composition of an Enstatite Ribbon of Probable Cometary Origin

Author

Ogliore, Ryan C., Brownlee, Donald E., Nagashima, Kazuhide, Joswiak, Dave J., Lewis, Josiah B., Krot, Alexander N., Ut, Kainen L., and Huss, Gary R.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Filamentary enstatite crystals are found in interplanetary dust particles of likely cometary origin but are very rare or absent in meteorites. Crystallographic characteristics of filamentary enstatites indicate that they condensed directly from vapor. We measured the O isotopic composition of an enstatite ribbon from a giant cluster interplanetary dust particle to be $\delta^{18}\rm{O}{=25{\pm}55}$, $\delta^{17}\rm{O}{=-19{\pm}129}$, $\Delta^{17}\rm{O}{=-32{\pm}134}$ (2$\sigma$ errors), which is inconsistent at the 2$\sigma$ level with the composition of the Sun inferred from the Genesis solar wind measurements. The particle's O isotopic composition, consistent with the terrestrial composition, implies that it condensed from a gas of non-solar O isotopic composition, possibly as a result of vaporization of disk region enriched in $^{16}$O-depleted solids. The relative scarcity of filamentary enstatite in asteroids compared to comets implies either that this crystal condensed from dust vaporized \textit{in-situ} in the outer Solar System where comets formed, or it condensed in the inner Solar System and was subsequently transported outward to the comet-forming region.

Published
2019
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5. Fine-grained Material Associated with a Large Sulfide returned from Comet 81P/Wild 2

Author

Gainsforth, Zack, Westphal, Andrew J., Butterworth, Anna L., Jilly-Rehak, Christine E., Brownlee, Donald E., Joswiak, Dave, Ogliore, Ryan C., Zolensky, Michael E., Bechtel, Hans A., Ebel, Denton S., Huss, Gary R., Sandford, Scott A., and White, Amanda J.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

In a consortium analysis of a large particle captured from the coma of comet 81P/Wild 2 by the Stardust spacecraft, we report the discovery of a field of fine-grained material (FGM) in contact with a large sulfide particle. The FGM was partially located in an embayment in the sulfide, so appears to have been largely protected from damage during hypervelocity capture in aerogel. Some of the FGM particles are indistinguishable in their characteristics from common components of chondritic-porous interplanetary dust particles (CP-IDPs), including glass with embedded metals and sulfides (GEMS) and equilibrated aggregates (EAs). The sulfide exhibits surprising Ni-rich lamellae, which may indicate that this particle experienced a long-duration heating event after its formation but before incorporation into Wild 2. We discuss the relationship of the FGM to the sulfide, to other Wild 2 particles and to the history of the Solar nebula.

Published
2018
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7. Atmospheric collection of extraterrestrial dust at the Earth's surface in the mid‐Pacific.

Author

Wozniakiewicz, Penelope J., Alesbrook, Luke S., Bradley, John P., Ishii, Hope A., Price, Mark C., Zolensky, Michael. E., Brownlee, Donald E., van Ginneken, Matthias, and Genge, Matthew J.

Subjects
SPHERULES (Geology), SURFACE of the earth, COAL-fired power plants, COAL ash, NATURAL numbers
Abstract

The Kwajalein micrometeorite collection utilized high volume air samplers fitted with polycarbonate membrane filters to capture particles directly from the atmosphere at the Earth's surface. This initial study focused on identifying cosmic spherule‐like particles, conservatively categorizing them into four groups based on bulk compositional data: Group I exhibit a range of compositions designated terrestrial in origin; group II are Fe‐rich and contain only additional O, S, and/or Ni; group III are silicate spherules with Mg‐to‐Si At% ratios less than 0.4; group IV are silicate spherules with Mg‐to‐Si At% ratios greater than 0.4. Spherules in groups I, II, and III have compositions that are also consistent with particles that are produced in great numbers by natural and/or anthropogenic terrestrial activities (e.g., volcanic microspherules, fly ash from coal fired power plants, etc.) and thus are assumed terrestrial in origin. Group IV spherules exhibit compositions closest to those of cosmic spherules identified in other collections and are, therefore, designated cosmic spherule candidates. Detailed analysis of seven group IV spherules found that whilst five exhibited morphology and compositions consistent with S‐type cosmic spherules, two appear unique to this collection and could not be matched to either terrestrial or extraterrestrial spherules studied to date. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Multiple generations of grain aggregation in different environments preceded solar system body formation

Author

Ishii, Hope A, Bradley, John P, Bechtel, Hans A, Brownlee, Donald E, Bustillo, Karen C, Ciston, James, Cuzzi, Jeffrey N, Floss, Christine, and Joswiak, David J

Subjects
Earth Sciences, Physical Sciences, Space Sciences, Geology, dust accretion, solar system origin, interstellar dust, cosmic dust
Abstract

The solar system formed from interstellar dust and gas in a molecular cloud. Astronomical observations show that typical interstellar dust consists of amorphous (a-) silicate and organic carbon. Bona fide physical samples for laboratory studies would yield unprecedented insight about solar system formation, but they were largely destroyed. The most likely repositories of surviving presolar dust are the least altered extraterrestrial materials, interplanetary dust particles (IDPs) with probable cometary origins. Cometary IDPs contain abundant submicron a-silicate grains called GEMS (glass with embedded metal and sulfides), believed to be carbon-free. Some have detectable isotopically anomalous a-silicate components from other stars, proving they are preserved dust inherited from the interstellar medium. However, it is debated whether the majority of GEMS predate the solar system or formed in the solar nebula by condensation of high-temperature (>1,300 K) gas. Here, we map IDP compositions with single nanometer-scale resolution and find that GEMS contain organic carbon. Mapping reveals two generations of grain aggregation, the key process in growth from dust grains to planetesimals, mediated by carbon. GEMS grains, some with a-silicate subgrains mantled by organic carbon, comprise the earliest generation of aggregates. These aggregates (and other grains) are encapsulated in lower-density organic carbon matrix, indicating a second generation of aggregation. Since this organic carbon thermally decomposes above ∼450 K, GEMS cannot have accreted in the hot solar nebula, and formed, instead, in the cold presolar molecular cloud and/or outer protoplanetary disk. We suggest that GEMS are consistent with surviving interstellar dust, condensed in situ, and cycled through multiple molecular clouds.

Published
2018

11. Contributors

Author

Abe, Masanao, primary, Aléon, Jérôme, additional, Aléon-Toppani, Alice, additional, Bennett, Allan, additional, Berthoud, Lucy, additional, Borg, Janet, additional, Bridges, John C., additional, Brownlee, Donald E., additional, Brunetto, Rosario, additional, Burnett, Don, additional, Brucato, John Robert, additional, Corte, Vincenzo Della, additional, Debaille, Vinciane, additional, Dirri, Fabrizio, additional, Djouadi, Zahia, additional, Enos, Heather L., additional, Ferrière, Ludovic, additional, Folco, Luigi, additional, Foucher, Frédéric, additional, Franchi, Ian A., additional, Fujiwara, Akira, additional, Gounelle, Matthieu, additional, Grady, Monica M., additional, Holt, John, additional, Hutzler, Aurore, additional, Jerde, Eric A., additional, Jurewicz, Amy, additional, Kawaguchi, Junichiro, additional, Lauretta, Dante S., additional, Leuko, Stefano, additional, Longobardo, Andrea, additional, Lunine, Jonathan I., additional, Marrocchi, Yves, additional, Meneghin, Andrea, additional, Palomba, Ernesto, additional, Polit, Anjani T., additional, Pottage, Thomas, additional, Qian, Yuqi, additional, Reisenfeld, Dan, additional, Rettberg, Petra, additional, Roper, Heather L., additional, Rotundi, Alessandra, additional, Russell, Sara S., additional, Sandford, Scott A., additional, Smith, Caroline L., additional, Slyuta, Evgeny, additional, Tachibana, Shogo, additional, Tasker, Elizabeth J., additional, Tsuchiyama, Akira, additional, Vrublevskis, John, additional, Wang, Qian, additional, Wang, Qiong, additional, Westall, Frances, additional, Wiens, Roger C., additional, Wolner, Catherine W.V., additional, Xiao, Long, additional, Yoshikawa, Makoto, additional, Zipfel, Jutta, additional, and Zolensky, Michael E., additional

Published
2021
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12. Micrometeorite collections: a review and their current status.

Author

van Ginneken, Matthias, Wozniakiewicz, Penelope J., Brownlee, Donald E., Debaille, Vinciane, Della Corte, Vincenzo, Delauche, Lucie, Duprat, Jean, Engrand, Cecile, Folco, Luigi, Fries, Marc, Gattacceca, Jérôme, Genge, Matthew J., Goderis, Steven, Gounelle, Matthieu, Harvey, Ralph P., Jonker, Guido, Krämer Ruggiu, Lisa, Larsen, Jon, Lever, James H., and Noguchi, Takaaki

Subjects
SPHERULES (Geology), GLACIAL drift, SURFACE of the earth, COSMIC dust, INTERPLANETARY medium
Abstract

Micrometeorites are estimated to represent the main part of the present flux of extraterrestrial matter found on the Earth's surface and provide valuable samples to probe the interplanetary medium. Here, we describe large and representative collections of micrometeorites currently available to the scientific community. These include Antarctic collections from surface ice and snow, as well as glacial sediments from the eroded top of nunataks—summits outcropping from the icesheet—and moraines. Collections extracted from deep-sea sediments (DSS) produced a large number of micrometeorites, in particular, iron-rich cosmic spherules that are rarer in other collections. Collections from the old and stable surface of the Atacama Desert show that finding large numbers of micrometeorites is not restricted to polar regions or DSS. The advent of rooftop collections marks an important step into involving citizen science in the study of micrometeorites, as well as providing potential sampling locations over all latitudes to explore the modern flux. We explore their strengths of the collections to address specific scientific questions and their potential weaknesses. The future of micrometeorite research will involve the finding of large fossil micrometeorite collections and benefit from recent advances in sampling cosmic dust directly from the air. This article is part of the theme issue 'Dust in the Solar System and beyond'. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Evidence for interstellar origin of seven dust particles collected by the Stardust spacecraft

Author

Westphal, Andrew J., Stroud, Rhonda M., Bechtel, Hans A., Brenker, Frank E., Butterworth, Anna L., Flynn, George J., Frank, David R., Gainsforth, Zack, Hillier, Jon K., Postberg, Frank, Simionovici, Alexandre S., Sterken, Veerle J., Nittler, Larry R., Allen, Carlton, Anderson, David, Ansari, Asna, Bajt, Saša, Bastien, Ron K., Bassim, Nabil, Bridges, John, Brownlee, Donald E., Burchell, Mark, Burghammer, Manfred, Changela, Hitesh, Cloetens, Peter, Davis, Andrew M., Doll, Ryan, Floss, Christine, Grün, Eberhard, Heck, Philipp R., Hoppe, Peter, Hudson, Bruce, Huth, Joachim, Kearsley, Anton, King, Ashley J., Lai, Barry, Leitner, Jan, Lemelle, Laurence, Leonard, Ariel, Leroux, Hugues, Lettieri, Robert, Marchant, William, Ogliore, Ryan, Ong, Wei Jia, Price, Mark C., Sandford, Scott A., Tresseras, Juan-Angel Sans, Schmitz, Sylvia, Schoonjans, Tom, Schreiber, Kate, Silversmit, Geert, Solé, Vicente A., Srama, Ralf, Stadermann, Frank, Stephan, Thomas, Stodolna, Julien, Sutton, Stephen, Trieloff, Mario, Tsou, Peter, Tyliszczak, Tolek, Vekemans, Bart, Vincze, Laszlo, Von Korff, Joshua, Wordsworth, Naomi, Zevin, Daniel, and Zolensky, Michael E.

Published
2014

19. Impact Features on Stardust: Implications for Comet 81p/Wild 2 Dust

Author

Hörz, Friedrich, Bastien, Ron, Borg, Janet, Bradley, John P., Bridges, John C., Brownlee, Donald E., Burchell, Mark J., Chi, Miaofang, Cintala, Mark J., Dai, Zu Rong, Djouadi, Zahia, Dominguez, Gerardo, Economou, Thanasis E., Fairey, Sam A. J., Floss, Christine, Franchi, Ian A., Graham, Giles A., Green, Simon F., Heck, Philipp, Hoppe, Peter, Huth, Joachim, Ishii, Hope, Kearsley, Anton T., Kissel, Jochen, Leitner, Jan, Leroux, Hugues, Marhas, Kuljeet, Messenger, Keiko, Schwandt, Craig S., See, Thomas H., Snead, Christopher, Stadermann, Frank J., Stephan, Thomas, Stroud, Rhonda, Teslich, Nick, Trigo-Rodríguez, Josep M., Tuzzolino, A. J., Troadec, David, Tsou, Peter, Warren, Jack, Westphal, Andrew, Wozniakiewicz, Penelope, Wright, Ian, and Zinner, Ernst

Published
2006
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20. Mineralogy and Petrology of Comet 81p/Wild 2 Nucleus Samples

Author

Zolensky, Michael E., Zega, Thomas J., Yano, Hajime, Wirick, Sue, Westphal, Andrew J., Weisberg, Mike K., Weber, Iris, Warren, Jack L., Velbel, Michael A., Tsuchiyama, Akira, Tsou, Peter, Toppani, Alice, Tomioka, Naotaka, Tomeoka, Kazushige, Teslich, Nick, Taheri, Mitra, Susini, Jean, Stroud, Rhonda, Stephan, Thomas, Stadermann, Frank J., Snead, Christopher J., Simon, Steven B., Simionovici, Alexandre, See, Thomas H., Robert, François, Rietmeijer, Frans J. M., Rao, William, Perronnet, Murielle C., Papanastassiou, Dimitri A., Okudaira, Kyoko, Ohsumi, Kazumasa, Ohnishi, Ichiro, Nakamura-Messenger, Keiko, Nakamura, Tomoki, Mostefaoui, Smail, Mikouchi, Takashi, Meibom, Anders, Matrajt, Graciela, Marcus, Matthew A., Leroux, Hugues, Lemelle, Laurence, Le, Loan, Lanzirotti, Antonio, Langenhorst, Falko, Krot, Alexander N., Keller, Lindsay P., Kearsley, Anton T., Joswiak, David, Jacob, Damien, Ishii, Hope, Harvey, Ralph, Hagiya, Kenji, Grossman, Lawrence, Grossman, Jeffrey N., Graham, Giles A., Gounelle, Matthieu, Gillet, Philippe, Genge, Matthew J., Flynn, George, Ferroir, Tristan, Fallon, Stewart, Ebel, Denton S., Dai, Zu Rong, Cordier, Patrick, Clark, Benton, Chi, Miaofang, Butterworth, Anna L., Brownlee, Donald E., Bridges, John C., Brennan, Sean, Brearley, Adrian, Bradley, John P., Bleuet, Pierre, Bland, Phil A., and Bastien, Ron

Published
2006
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21. Organics Captured from Comet 81p/Wild 2 by the Stardust Spacecraft

Author

Sandford, Scott A., Aléon, Jérôme, Alexander, Conel M. O'D., Araki, Tohru, Bajt, Saša, Baratta, Giuseppe A., Borg, Janet, Bradley, John P., Brownlee, Donald E., Brucato, John R., Burchell, Mark J., Busemann, Henner, Butterworth, Anna, Clemett, Simon J., Cody, George, Colangeli, Luigi, Cooper, George, D'Hendecourt, Louis, Djouadi, Zahia, Dworkin, Jason P., Ferrini, Gianluca, Fleckenstein, Holger, Flynn, George J., Franchi, Ian A., Fries, Marc, Gilles, Mary K., Glavin, Daniel P., Gounelle, Matthieu, Grossemy, Faustine, Jacobsen, Chris, Keller, Lindsay P., Kilcoyne, A. L. David, Leitner, Jan, Matrajt, Graciela, Meibom, Anders, Mennella, Vito, Mostefaoui, Smail, Nittler, Larry R., Palumbo, Maria E., Papanastassiou, Dimitri A., Robert, François, Rotundi, Alessandra, Snead, Christopher J., Spencer, Maegan K., Stadermann, Frank J., Steele, Andrew, Stephan, Thomas, Tsou, Peter, Tyliszczak, Tolek, Westphal, Andrew J., Wirick, Sue, Wopenka, Brigitte, Yabuta, Hikaru, Zare, Richard N., and Zolensky, Michael E.

Published
2006
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24. INTERSTELLAR DUST: Evidence for interstellar origin of seven dust particles collected by the Stardust spacecraft

Author

Westphal, Andrew J., Stroud, Rhonda M., Bechtel, Hans A., Brenker, Frank E., Butterworth, Anna L., Flynn, George J., Frank, David R., Gainsforth, Zack, Hillier, Jon K., Postberg, Frank, Simionovici, Alexandre S., Sterken, Veerle J., Nittler, Larry R., Allen, Carlton, Anderson, David, Ansari, Asna, Bajt, Saša, Bastien, Ron K., Bassim, Nabil, Bridges, John, Brownlee, Donald E., Burchell, Mark, Burghammer, Manfred, Changela, Hitesh, Cloetens, Peter, Davis, Andrew M., Doll, Ryan, Floss, Christine, Grün, Eberhard, Heck, Philipp R., Hoppe, Peter, Hudson, Bruce, Huth, Joachim, Kearsley, Anton, King, Ashley J., Lai, Barry, Leitner, Jan, Lemelle, Laurence, Leonard, Ariel, Leroux, Hugues, Lettieri, Robert, Marchant, William, Ogliore, Ryan, Jia Ong, Wei, Price, Mark C., Sandford, Scott A., Sans Tresseras, Juan-Angel, Schmitz, Sylvia, Schoonjans, Tom, Schreiber, Kate, Silversmit, Geert, Solé, Vicente A., Srama, Ralf, Stadermann, Frank, Stephan, Thomas, Stodolna, Julien, Sutton, Stephen, Trieloff, Mario, Tsou, Peter, Tyliszczak, Tolek, Vekemans, Bart, Vincze, Laszlo, Von Korff, Joshua, Wordsworth, Naomi, Zevin, Daniel, and Zolensky, Michael E.

Published
2014
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25. Coordinated Microanalyses of Seven Particles of Probable Interstellar Origin from the Stardust Mission

Author

Westphal, Andrew J, Stroud, Rhonda M, Bechtel, Hans A, Brenker, Frank E, Butterworth, Anna L, Flynn, George J, Frank, David R, Gainsforth, Zack, Hillier, Jon K, Postberg, Frank, Simionovici, Alexandre S, Sterken, Veerle J, Allen, Carlton, Anderson, David, Ansari, Asna, Bajt, Sasa, Bastien, Ron K, Bassim, Nabil, Bridges, John, Brownlee, Donald E, Burchell, Mark, Burghammer, Manfred, Changela, Hitesh, Sandford, Scott A, and Zolensky, Michael

Subjects
Lunar And Planetary Science And Exploration
Abstract

Stardust, a NASA Discovery-class mission, was the first sample-return mission to return solid samples from beyond the Moon. Stardust was effectively two missions in one spacecraft: it returned the first materials from a known primitive solar system body, the Jupiter-family comet Wild 2; Stardust also returned a collector that was exposed to the contemporary interstellar dust stream for 200 days during the interplanetary cruise. Both collections present severe technical challenges in sample preparation and in analysis. By far the largest collection is the cometary one: approximately 300 micro g of material was returned from Wild 2, mostly consisting of approx. 1 ng particles embedded in aerogel or captured as residues in craters on aluminum foils. Because of their relatively large size, identification of the impacts of cometary particles in the collection media is straightforward. Reliable techniques have been developed for the extraction of these particles from aerogel. Coordinated analyses are also relatively straightforward, often beginning with synchrotron-based x-ray fluorescence (S-XRF), X-ray Absorption Near-Edge Spectoscopy (XANES) and x-ray diffraction (S-XRD) analyses of particles while still embedded in small extracted wedges of aerogel called ``keystones'', followed by ultramicrotomy and TEM, Scanning Transmission X-ray Microscopy (STXM) and ion microprobe analyses (e.g., Ogliore et al., 2010). Impacts in foils can be readily analyzed by SEM-EDX, and TEM analysis after FIB liftout sample preparation. In contrast, the interstellar dust collection is vastly more challenging. The sample size is approximately six orders of magnitude smaller in total mass. The largest particles are only a few pg in mass, of which there may be only approx.10 in the entire collection. The technical challenges, however, are matched by the scientific importance of the collection. We formed a consortium carry out the Stardust Interstellar Preliminary Examination (ISPE) to carry out an assessment of this collection, partly in order to characterize the collection in sufficient detail so that future investigators could make well-informed sample requests. The ISPE is the sixth PE on extraterrestrial collections carried out with NASA support. Some of the basic questions that we asked were: how many impacts are there in the collector, and what fraction of them have characteristics consistent with extraterrestrial materials? What is the elemental composition of the rock-forming elements? Is there crystalline material? Are there organics? Here we present coordinated microanalyses of particles captured in aerogel, using S-FTIR, S-XRF, STXM, S-XRD; and coordinated microanalyses of residues in aluminum foil, using SEMEDX, Auger spectroscopy, STEM, and ion microprobe. We discuss a novel approach that we employed for identification of tracks in aerogel, and new sample preparation techniques developed during the ISPE. We have identified seven particles - three in aerogel and four in foils - that are most consistent with an interstellar origin. The seven particles exhibit a large diversity in elemental composition. Dynamical evidence, supported supported by laboratory simulations of interstellar dust impacts in aerogel and foils, and numerical modeling of interstellar dust propagation in the heliosphere, suggests that at least some of the particles have high optical cross-section, perhaps due to an aggregate structure. However, the observations are most consistent with a variety of morphologies

Published
2014

26. Final Reports of the Stardust ISPE: Seven Probable Interstellar Dust Particles

Author

Allen, Carlton, Sans Tresseras, Juan-Angel, Westphal, Andrew J, Stroud, Rhonda M, Bechtel, Hans A, Brenker, Frank E, Butterworth, Anna L, Flynn, George J, Frank, David R, Gainsforth, Zack, Hillier, Jon K, Postberg, Frank, Simionovici, Alexandre S, Sterken, Veerle J, Anderson, David, Ansari, Asna, Bajt, Sasa, Bastien, Ron K, Bassim, Nabil, Bridges, John, Brownlee, Donald E, Burchell, Mark, Burghammer, Manfred, Changela, Hitesh, Cloetens, Peter, Davis, Andrew M, Doll, Ryan, Floss, Christine, Gruen, Eberhard, Heck, Philipp R, Hoppe, Peter, Hudson, (Bruce), Huth, Joachim, Kearsley, Anton, and King, Ashley J

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Stardust spacecraft carried the first spaceborne collector specifically designed to capture and return a sample of contemporary interstellar dust to terrestrial laboratories for analysis [1]. The collector was exposed to the interstellar dust stream in two periods in 2000 and 2002 with a total exposure of approximately 1.8 10(exp 6) square meters sec. Approximately 85% of the collector consisted of aerogel, and the remainder consisted of Al foils. The Stardust Interstellar Preliminary Examination (ISPE) was a consortiumbased effort to characterize the collection in sufficient detail to enable future investigators to make informed sample requests. Among the questions to be answered were these: How many impacts are consistent in their characteristics with interstellar dust, with interplanetary dust, and with secondary ejecta from impacts on the spacecraft? Are the materials amorphous or crystalline? Are organics detectable? An additional goal of the ISPE was to develop or refine the techniques for preparation, analysis, and curation of these tiny samples, expected to be approximately 1 picogram or smaller, roughly three orders of magnitude smaller in mass than the samples in other small particle collections in NASA's collections - the cometary samples returned by Stardust, and the collection of Interplanetary Dust Particles collected in the stratosphere.

Published
2014

27. Surface of young Jupiter family Comet 81 P/Wild 2: view from the Stardust spacecraft

Author

Brownlee, Donald E., Horz, Friedrich, Newburn, Ray L., Zolensky, Michael, Duxbury, Thomas C., Sandford, Scott, Sekanina, Zdenek, Tsou, Peter, Hanner, Martha S., Clark, Benton C., Green, Simon F., and Kissel, Jochen

Subjects
Stardust (Space probe) -- Equipment and supplies, Comets -- Research -- Measurement -- Properties -- Equipment and supplies, Science and technology, Research, Measurement, Properties, Equipment and supplies
Abstract

Images taken by the Stardust mission during its flyby of 81P/Wild 2 show the comet to be a 5-kilometer oblate body covered with remarkable topographic features, including unusual circular features that appear to be impact craters. The presence of high-angle slopes shows that the surface is cohesive and self-supporting. The comet does not appear to be a rubble pile, and its rounded shape is not directly consistent with the comet being a fragment of a larger body. The surface is active and yet it retains ancient terrain. Wild 2 appears to be in the early stages of its degradation phase as a small volatile-rich body in the inner solar system., Jupiter family comets (JFCs) such as 81 P/Wild 2 typically range from the orbit of Jupiter to inner regions of the solar system. These subliming-disintegrating bodies have inner solar system [...]

Published
2004

28. Modeling the nucleus and jets of comet 81 P/Wild 2 based on the Stardust encounter data

Author

Sekanina, Zdenek, Brownlee, Donald E., Economou, Thanasis E., Tuzzolino, Anthony J., and Green, Simon F.

Subjects
Stardust (Space probe) -- Equipment and supplies, Comets -- Measurement -- Research -- Properties -- Equipment and supplies, Science and technology, Measurement, Research, Properties, Equipment and supplies
Abstract

We interpret the nucleus properties and jet activity from the Stardust spacecraft imaging and the onboard dust monitoring system data. Triangulation of 20 jets shows that 2 emanate from the nucleus dark side and 16 emanate from sources that are on slopes where the Sun's elevation is greater than predicted from the fitted triaxial ellipsoid. Seven sources, including five in the Mayo depression, coincide with relatively bright surface spots. Fitting the imaged jets, the spikelike temporal distribution of dust impacts indicates that the spacecraft crossed thin, densely populated sheets of particulate ejecta extending from small sources on the rotating nucleus, consistent with an emission cone model., Cometary activity is characterized by solar energy-driven sublimation of water ice and other volatile substances from the nucleus into the coma, while refractory material (dust particles of various sizes) is [...]

Published
2004

30. Stardust Interstellar Preliminary Examination III: Infrared Spectroscopic Analysis of Interstellar Dust Candidates

Author

Bechtel, Hans A, Flynn, George J, Allen, Carlton, Anderson, David, Ansari, Asna, Bajt, Sasa, Bastien, Ron K, Bassim, Nabil, Borg, Janet, Brenker, Frank E, Bridges, John, Brownlee, Donald E, Burchell, Mark, Burghammer, Manfred, Butterworth, Anna L, Changela, Hitesh, Cloetens, Peter, Davis, Andrew M, Doll, Ryan, Floss, Christine, Frank, David R, Gainsforth, Zack, Grun, Eberhard, Heck, Philipp R, Hillier, Jon K, Hoppe, Peter, Hudson, Bruce, Huth, Joachim, Hvide, Brit, Kearsley, Anton, King, Ashley J, Lai, Barry, Leitner, Jan, Lemelle, Laurence, Leroux, Hugues, Leonard, Ariel, Lettieri, Robert, Marchant, William, Nittler, Larry, Ogliore, Ryan, Ong, Wei Ja, Postberg, Frank, Price, Mark C, Sandford, Scott A, Tresseras, Juan-Angel Sans, Schmitz, Sylvia, Schoonjans, Tom, Silversmit, Geert, Simionovici, Alexandre S, Sole, Vicente A, Srama, Ralf, Stadermann, Frank J, Stephan, Thomas, Sterken, Veerle J, Stodolna, Julien, Stroud, Rhonda M, Sutton, Steven, Trieloff, Mario, Tsou, Peter, Tsuchiyama, Akira, Tyliszczak, Tolek, Vekemans, Bart, Vincze, Laszlo, Von Korff, Joshua, Westphal, Andrew J, Wordsworth, Naomi, Zevin, Daniel, and Zolensky, Michael E

Subjects
Astrophysics
Abstract

Under the auspices of the Stardust Interstellar Preliminary Examination, picokeystones extracted from the Stardust Interstellar Dust Collector were examined with synchrotron Fourier transform infrared (FTIR) microscopy to establish whether they contained extraterrestrial organic material. The picokeystones were found to be contaminated with varying concentrations and speciation of organics in the native aerogel, which hindered the search for organics in the interstellar dust candidates. Furthermore, examination of the picokeystones prior to and post X-ray microprobe analyses yielded evidence of beam damage in the form of organic deposition or modification, particularly with hard X-ray synchrotron X-ray fluorescence. From these results, it is clear that considerable care must be taken to interpret any organics that might be in interstellar dust particles. For the interstellar candidates examined thus far, however, there is no clear evidence of extraterrestrial organics associated with the track and/or terminal particles. However, we detected organic matter associated with the terminal particle in Track 37, likely a secondary impact from the Al-deck of the sample return capsule, demonstrating the ability of synchrotron FTIR to detect organic matter in small particles within picokeystones from the Stardust interstellar dust collector.

Published
2013
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31. Identification of Crystalline Material in Two Interstellar Dust Candidates from the Stardust Mission

Author

Gainsforth, Zack, Simionovici, Alexandra, Brenker, Frank E, Schmitz, Sylvia, Burghammer, Manfred, Cloetens, Peter, Lemelle, Laurence, San Tresseras, Juan-Angel, Schoonjans, Tom, Silversmit, Geert, Sole, Vicente A, Vekemans, Bart, Vincze, Laszlo, Achilles, Cheri, Allen, Carlton, Ansari, Asna, Bajt, Sasa, Bassim, Nabil, Bastien, Ron S, Bechtel, H. A, Borg, Janet, Bridges, John, Brownlee, Donald E, Sandford, S. A, and Zolensky, Michael E

Subjects
Astrophysics
Abstract

NASA's interstellar collector from the Stardust mission captured several particles that are now thought to be of interstellar origin. We analyzed two of these via nanodiffraction at the European Synchrotron Radiation Facility (ESRF) and found them to contain crystalline components. The unit cell of the crystalline material is determined from the diffraction patterns and the most likely mineral components are identified as olivine and spinel.

Published
2012

32. Constraining the Origin of Impact Craters on Al Foils from the Stardust Interstellar Dust Collector

Author

Stroud, Rhonda M, Achilles, Cheri, Allen, Carlton, Ansari, Asna, Bajt, Sasa, Bassim, Nabil, Bastien, Ron S, Bechtel, H. A, Borg, Janet, Brenker, Frank E, Bridges, John, Brownlee, Donald E, Burchell, Mark, Burghammer, Manfred, Butterworth, Anna L, Changela, Hitesh, Cloetens, Peter, Davis, Andrew M, Doll, Ryan, Floss, Christine, Flynn, George, Fougeray, Patrick, Frank, David, Sandford, Scott A, and Zolensky, Michael E

Subjects
Geophysics
Abstract

Preliminary examination (PE) of the aerogel tiles and Al foils from the Stardust Interstellar Dust Collector has revealed multiple impact features. Some are most likely due to primary impacts of interstellar dust (ISD) grains, and others are associated with secondary impacts of spacecraft debris, and possibly primary impacts of interplanetary dust particles (IDPs) [1, 2]. The current focus of the PE effort is on constraining the origin of the individual impact features so that definitive results from the first direct laboratory analysis of contemporary ISD can be reported. Because crater morphology depends on impacting particle shape and composition, in addition to the angle and direction of impact, unique particle trajectories are not easily determined. However, elemental analysis of the crater residues can distinguish real cosmic dust from the spacecraft debris, due to the low cosmic abundance of many of the elements in the spacecraft materials. We present here results from the elemental analysis of 24 craters and discuss the possible origins of 4 that are identified as candidate ISD impacts

Published
2012

33. Microanalysis of Hypervelocity Impact Residues of Possible Interstellar Origin

Author

Stroud, Rhonda M, Achilles, Cheri, Allen, Carlton, Anasari, Asna, Bajt, Sasa, Bassim, Nabil, Bastien, Ron S, Bechtel, H. A, Borg, Janet, Brenker, Frank E, Bridges, John, Brownlee, Donald E, Burchell, Mark, Burghammer, Manfred, Butterworth, Anna L, Changela, Hitesh, Cloetens, Peter, Davis, Andrew M, Doll, Ryan, Floss, Christine, Flynn, George, Fougeray, Patrick, Frank, David, Sandford, Scott A, and Zolensky, Michael E

Subjects
Space Sciences (General)
Abstract

The NASA Stardust spacecraft deployed two collector trays, one dedicated to the collection of dust from Comet Wild 2, and the other for the capture of interstellar dust (ISD). The samples were returned successfully to Earth in 2006, and now provide an unprecedented opportunity for laboratory-based microanalysis of materials from the outer solar system and beyond. Results from the cometary sample studies have demonstrated that Wild 2 contains much more refractory condensate material and much less pristine extra-solar material than expected, which further indicates that there was significant transport of inner solar system materials to the Kuiper Belt in the early solar system [1]. The analysis of the interstellar samples is still in the preliminary examination (PE) phase, due to the level of difficulty in the definitive identification of the ISD features, the overall low abundance, and its irreplaceable nature, which necessitates minimally invasive measurements [2]. We present here coordinated microanalysis of the impact features on the Al foils, which have led to the identification of four impacts that are possibly attributable to interstellar dust. Results from the study of four ISD candidates captured in aerogel are presented elsewhere [2].

Published
2012

35. Discovery of Non-random Spatial Distribution of Impacts in the Stardust Cometary Collector

Author

Horz, Friedrich, Westphal, Andrew J, Gainsforth, Zack, Borg, Janet, Djouadi, Zahia, Bridges, John, Franchi, Ian, Brownlee, Donald E, Cheng. Andrew F, Clark, Benton C, and Floss, Christine

Subjects
Astrophysics
Abstract

We report the discovery that impacts in the Stardust cometary collector are not distributed randomly in the collecting media, but appear to be clustered on scales smaller than 10 cm. We also report the discovery of at least two populations of oblique tracks. We evaluated several hypotheses that could explain the observations. No hypothesis was consistent with all the observations, but the preponderance of evidence points toward at least one impact on the central Whipple shield of the spacecraft as the origin of both clustering and low-angle oblique tracks. High-angle oblique tracks unambiguously originate from a non-cometary impact on the spacecraft bus just forward of the collector.

Published
2007

36. Non-Random Spatial Distribution of Impacts in the Stardust Cometary Collector

Author

Westphal, Andrew J, Bastien, Ronald K, Borg, Janet, Bridges, John, Brownlee, Donald E, Burchell, Mark J, Cheng, Andrew F, Clark, Benton C, Djouadi, Zahia, and Floss, Christine

Subjects
Geophysics
Abstract

In January 2004, the Stardust spacecraft flew through the coma of comet P81/Wild2 at a relative speed of 6.1 km/sec. Cometary dust was collected at in a 0.1 sq m collector consisting of aerogel tiles and aluminum foils. Two years later, the samples successfully returned to earth and were recovered. We report the discovery that impacts in the Stardust cometary collector are not distributed randomly in the collecting media, but appear to be clustered on scales smaller than approx.10 cm. We also report the discovery of at least two populations of oblique tracks. We evaluated several hypotheses that could explain the observations. No hypothesis was consistent with all the observations, but the preponderance of evidence points toward at least one impact on the central Whipple shield of the spacecraft as the origin of both clustering and low-angle oblique tracks. High-angle oblique tracks unambiguously originate from a noncometary impact on the spacecraft bus just forward of the collector. Here we summarize the observations, and review the evidence for and against three scenarios that we have considered for explaining the impact clustering found on the Stardust aerogel and foil collectors.

Published
2007

37. Authors

Author

Anderson, Theodore L, primary, Anthony, Sharon E., additional, Benjamin, Mark M., additional, Brook, Edward J., additional, Brownlee, Donald E., additional, Burges, Stephen J., additional, Butcher, Samuel S., additional, Charlson, Robert J., additional, Cuffey, Kurt M., additional, Emerson, Steven, additional, Hallberg, Rolf O., additional, Henshaw, Patricia C., additional, Holmén, Kim, additional, Honeyman, Bruce D., additional, Jacobson, Michael C., additional, Jaffe, Daniel A., additional, Jahnke, Richard A., additional, McDuff, Russell E., additional, Montgomery, David R., additional, Murray, James W., additional, Orians, Gordon H., additional, Rodhe, Henning, additional, Spaltenstein, Henri, additional, Staley, James T., additional, Stallard, Robert F., additional, Ugolini, Fiorenzo C., additional, Wolfe, Gordon V., additional, and Zabowski, Darlene, additional

Published
2000
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38. Stardust@home: A Massively Distributed Public Search for Interstellar Dust in the Stardust Interstellar Dust Collector

Author

Westphal, Andrew J, Butterworth, Anna L, Snead, Christopher J, Craig, Nahide, Anderson, David, Jones, Steven M, Brownlee, Donald E, Farnsworth, Richard, and Zolensky, Michael E

Subjects
Astronomy
Abstract

In January 2006, the Stardust mission will return the first samples from a solid solar system body beyond the Moon. Stardust was in the news in January 2004, when it encountered comet Wild2 and captured a sample of cometary dust. But Stardust carries an equally important payload: the first samples of contemporary interstellar dust ever collected. Although it is known that interstellar (IS) dust penetrates into the inner solar system [2, 3], to date not even a single contemporary interstellar dust particle has been captured and analyzed in the laboratory. Stardust uses aerogel collectors to capture dust samples. Identification of interstellar dust impacts in the Stardust Interstellar Dust Collector probably cannot be automated, but will require the expertise of the human eye. However, the labor required for visual scanning of the entire collector would exceed the resources of any reasonably-sized research group. We are developing a project to recruit the public in the search for interstellar dust, based in part on the wildly popular SETI@home project, which has five million subscribers. We call the project Stardust@home. Using sophisticated chemical separation techniques, certain types of refractory ancient IS particles (so-called presolar grains) have been isolated from primitive meteorites (e.g., [4] ). Recently, presolar grains have been identified in Interplanetary Dust Particles[6]. Because these grains are not isolated chemically, but are recognized only by their unusual isotopic compositions, they are probably less biased than presolar grains isolated from meteorites. However, it is entirely possible that the typical interstellar dust particle is isotopically solar in composition. The Stardust collection of interstellar dust will be the first truly unbiased one.

Published
2005

39. Densities of stratospheric micrometeorites

Author

Love, Stanley G., Joswiak, David J., and Brownlee, Donald E.

Subjects
Stratosphere -- Research, Cosmic dust -- Observations, Astronomy, Earth sciences
Abstract

Interplanetary dust particles obtained from the earth's stratosphere are investigated to determine the density of these particles. The size of the interplanetary dust particles varies from 5 to 15 micrometers and the density ranges from 0.3 to 6.2 grams per cubic centimeter. The low density value reveals that the particles exhibit porosity and originate from uncompacted bodies. Most of these particles have sulphide grains and chondritic spherules.

Published
1994

40. Target porosity effects in impact cratering and collisional disruption

Author

Love, Stanley G., Horz, Friedrich, and Brownlee, Donald E.

Subjects
Planets -- Research, Meteorites -- Research, Porosity -- Research, Porous materials -- Analysis, Permeability -- Analysis, Glass -- Fracture, Fracture mechanics -- Research, Brittleness -- Research, Collisions (Physics) -- Research, Craters -- Research, Impact -- Research, Blast effect -- Analysis, Astronomy, Earth sciences
Abstract

Hypervelocity impacts of soda lime glass on porous sintered glass targets is investigated to study the mechanism involved in impacts of small astronomical objects such as meteorites on larger ones such as planets. Strength and density of projectiles and targets are varied. Deep craters are caused when porosity of the target is increased. At lower velocities, the impact damage has a greater localization. Porous targets also have a very low rear-surface spallation. The investigation indicates that threshold of the specific energy required to damage targets of different porosity is propotional to (1 - the porosity value)(super minus 3.6). Melt-bordered agglutinate crater pits are produced during the impacts.

Published
1993

41. Meteoritics and Planetary Science Supplement

Author

Sears, Derek W. G, Binzel, Richard P, Gaffey, Michael J, Kraehenbuehl, Urs, Pieters, Carle M, Shaw, Denis, Wieler, Rainer, Brownlee, Donald E, Goldstein, Joseph I, and Lyon, Ian C

Subjects
Astrophysics
Abstract

This special supplement of the Meteoritics and Planetary Science Society Journal contains the abstracts of 324 technical presentations, and the presentations of awards during the Annual meeting of the Meteoritical Society. The abstracts review current research on meteors and planetary sciences.

Published
2000

44. Capture of Hypervelocity Particles with Low-Density Aerogel

Author

Hoerz, Friedrich, Cintala, Mark J, Zolensky, Michael E, Bernhard, Ronald B, Haynes, Gerald, See, Thomas H, Tsou, Peter, and Brownlee, Donald E

Subjects
Space Sciences (General)
Abstract

Recent impact experiments conducted at Johnson Space Center supported a space-exposed flight instrument called the orbital debris collector (ODC) to see whether SiO2 acrogel performed adequately as a collector to capture cosmic dust particles and/or manmade debris, or whether additional development is needed. The first ODC was flown aboard the Mir for 18 months, while the second will be flown aboard a spacecraft (Stardust, to be launched in 1999) that will encounter the comet Wild 2 and return to Earth. Aerogels are highly porous materials that decelerate high-velocity particles without substantial melting or modifications to the particles' components; in other denser materials, these particles would melt or vaporize upon impact. The experimental data in this report must be considered somewhat qualitative because they are characterized by substantial, if not intolerable, scatter, possibly due to experimental difficulties in duplicating given sets of initial impact conditions. Therefore, this report is a chronological guide of the experimenters' attempts, difficulties, progress, and evaluations for future tests.

Published
1998

46. Natural and orbital debris particles on LDEF's trailing and forward-facing surfaces

Author

Hoerz, Friedrich, See, Thomas H, Bernhard, Ronald P, and Brownlee, Donald E

Subjects
Astrophysics
Abstract

Approximately 1000 impact craters on the Chemistry of Meteoroid Experiment (CME) have been analyzed by means of Scanning Electron Microscopy (SEM) and Energy Dispersive X-ray Analysis (EDXA) to determine the compositional make-up of projectile residues. This report completes our systematic survey of gold and aluminum surfaces exposed at the trailing-edge (A03) and forward-facing (A11) LDEF sites, respectively. The major categories for the projectile residues were (1) natural, with diverse subgroups such as chondritic, monomineralic silicates, and sulfides, and (2) man made, that were classified into aluminum (metallic or oxide) and miscellaneous materials (such as stainless steel, paint flakes, etc). On CME gold collectors on LDEF's trailing edge approximately 11 percent of all craters greater than 100 micron in diameter were due to man-made debris, the majority (8.6 percent) caused by pure aluminum, approximately 31.4 percent were due to cosmic dust, while the remaining 58 percent were indeterminate via the analytical techniques utilized in this study. The aluminum surfaces located at the A11 forward-facing site did not permit analysis of aluminum impactors, but approximately 9.4 percent of all craters were demonstratably caused by miscellaneous debris materials and approximately 39.2 percent were the result of natural particles, leaving approximately 50 percent which were indeterminate. Model considerations and calculations are presented that focus on the crater-production rates for features greater than 100 micron in diameter, and on assigning the intermediate crater population to man-made or natural particles. An enhancement factor of 6 in the crater-production rate of natural impactors for the 'forward-facing' versus the 'trailing-edge' CME collectors was found to best explain all observations (i.e., total crater number(s), as well as their computational characteristics). Enhancement factors of 10 and 4 are either too high or too low. It is also suggested that approximately 45 percent of all craters greater than 100 micron in diameter are caused by man-made impactors on the A11 surfaces. This makes the production rate for craters greater than 100 micron in diameter, resulting from orbital debris, a factor of 40 higher on the forward-facing sides as opposed to the trailing-edge direction.

Published
1995

47. Iron and nickel isotopic mass fractionation in deep-sea spherules

Author

Davis, Andrew M and Brownlee, Donald E

Subjects
Geophysics
Abstract

Magnetite-wuestite spherules collected from deep-sea sediments are thought to have originally been Fe-Ni metal particles at the top of the atmosphere that were oxidized and melted during entry into the earth's atmosphere. Some likely sources for the metal particles are Fe-Ni interplanetary dust particles (IDP's) and metal or sulfide from stony IDP's that separated after melting. Davis et al. reported that four of these spherules are enriched in the heavy isotopes of iron, with enrichments of 8-23%/amu. We have developed a technique for analysis of both iron and nickel isotopes on the same ion microprobe spot and have applied this technique to a number of deep-sea spherules in order to better understand the processes leading to isotopic mass fractionation. Eight spherules show iron and nickel isotopic mass fractionation, with iron and nickel enriched in the heavy isotopes by 10-19%/amu and 4-32%/amu, respectively. If the mass fractionations are due to Rayleigh fractionation during evaporation, these spherules lost 76-94% of their original mass. We have analyzed the four magnetite-wuestite spherules for which iron isotopic data were reported by Davis et al. as well as four new spherules.

Published
1993

48. Cosmic dust

Author

Brownlee, Donald E and Sandford, Scott A

Subjects
Astrophysics
Abstract

Dust is a ubiquitous component of our galaxy and the solar system. The collection and analysis of extraterrestrial dust particles is important to exobiology because it provides information about the sources of biogenically significant elements and compounds that accumulated in distant regions of the solar nebula and that were later accreted on the planets. The topics discussed include the following: general properties of interplanetary dust; the carbonaceous component of interplanetary dust particles; and the presence of an interstellar component.

Published
1992

49. Preliminary analysis of LDEF instrument A0187-1: Chemistry of Micrometeoroids Experiment

Author

Hoerz, Friedrich, Bernhard, Ronald P, Warren, Jack, See, Thomas H, Brownlee, Donald E, Laurance, Mark R, Messenger, Scott, and Peterson, Robert B

Subjects
Astrophysics
Abstract

The Chemistry of Micrometeoroids Experiment (CME) exposed approximately 0.8 sq. m of gold on the Long Duration Exposure Facility's (LDEF's) trailing edge (location A03) and approximately 1.1 sq. m of aluminum in the forward-facing A11 location. The most significant results to date relate to the discovery of unmelted pyroxene and olivine fragments associated with natural cosmic dust impacts. The latter are sufficiently large for detailed phase studies, and they serve to demonstrate that recovery of unmelted dust fragments is a realistic prospect for further dust experiments that will employ more advanced collector media. We also discovered that man-made debris impacts occur on the LDEF's trailing edge with substantially higher frequency than expected, suggesting that orbital debris in highly elliptical orbits may have been somewhat underestimated.

Published
1992

50. Oxygen isotopic composition of an enstatite ribbon of probable cometary origin.

Author

Ogliore, Ryan C., Brownlee, Donald E., Nagashima, Kazuhide, Joswiak, David J., Lewis, Josiah B., Krot, Alexander N., Utt, Kainen L., and Huss, Gary R.

Subjects
*ENSTATITE, *INTERPLANETARY dust, *CRYSTAL whiskers, *COMETS, *SOLAR system, *SOLAR wind, *SOLAR chromosphere
Abstract

Filamentary enstatite crystals are found in interplanetary dust particles (IDPs) of likely cometary origin but are very rare or absent in meteorites. Crystallographic characteristics of filamentary enstatites indicate that they condensed directly from vapor. We measured the O isotopic composition of an enstatite ribbon from a giant cluster IDP to be δ18O = 25 ± 55, δ17O = −19 ± 129, ∆17O = −32 ± 134 (2σ errors), which is inconsistent at the 2σ level with the composition of the Sun inferred from the Genesis solar wind measurements. The particle's O isotopic composition, consistent with the terrestrial composition, implies that it condensed from a gas of nonsolar O isotopic composition, possibly as a result of vaporization of disk region enriched in 16O‐depleted solids. The relative scarcity of filamentary enstatite in asteroids compared to comets implies either that this crystal condensed from dust vaporized in situ in the outer solar system where comets formed or it condensed in the inner solar system and was subsequently transported outward to the comet‐forming region. [ABSTRACT FROM AUTHOR]

Published
2020
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