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1. Brecciation of CM Chondrites: Cold Bokkeveld

Author

Zolensky, M, Velbel, M, and Le, L

Subjects
Space Sciences (General)
Abstract

C-complex asteroids frequently exhibit reflectance spectra consistent with thermally metamor-phosed or shocked carbonaceous chondrites, and brecciation, including Ryugu, and Bennu. Petrographic evidence of brecciation has been presented for CM, and here we reexamine Cold Bokkeveld, one of the most diverse CM breccias, as a preview of the samples to be returned from Ryugu and Bennu.

Published
2020

2. The Relationship Between Cosmic-Ray Exposure Ages And Mixing Of CM Chondrite Lithologies

Author

Zolensky, M. E, Takenouchi, A, Gregory, T, Nishiizumi, K, Caffee, M, Velbel, M. A, Ross, K, Zolensky, A, Le, L, Imae, N, Yamaguchi, A, and Mikouchi, T

Subjects
Lunar And Planetary Science And Exploration
Abstract

Carbonaceous (C) chondrites are primitive materials probably deriving from C, P and D asteroids, and as such potentially include samples and analogues of the target asteroids of the Dawn, Hayabusa2 and OSIRIS-Rex missions. Foremost among the C chondrites are the CM chondrites, the most common type, and which have experienced the widest range of early solar system processes including oxidation, hydration, metamorphism, and impact shock deformation, often repeatedly or cyclically [1]. To track the activity of these processes in the early solar system, it is critical to learn how many separate bodies are represented by the CMs. Nishiizumi and Caffee [2] have reported that the CMs are unique in displaying several distinct peaks for cosmic-ray exposure (CRE) age groups, and that excavation from significant depth and exposure as small entities in space is the best explanation for the observed radionuclide data. There are either 3 or 4 CRE groups for CMs (Fig.1). We decided to systematically characterize the petrography in each of the CRE age groups to determine whether the groups have significant petrographic differences with these reflecting different parent asteroid geological processing or multiple original bodies. We previously re-ported preliminary results of our work [3], however we have now reexamined these meteorites from the perspective of brecciation, with interesting new results.

Published
2017

3. Unraveling the Diversity of Early Aqueous Environments and Climate on Mars Through the Phyllosilicate Record

Author

Bishop, J. L, Baker, L. L, Fairén, A. G, Gross, C, Velbel, M. A, Rampe, E. B, and Michalski, J. R

Subjects
Lunar And Planetary Science And Exploration, Geophysics
Abstract

Were Martian phyllosilicates formed on the surface or subsurface? Was early Mars warm or cold? How long was liquid water present on the surface of Mars? These are some of the many open questions about our neighboring planet. We propose that the mineralogy of the clay-bearing outcrops on Mars can help address these questions. Abundant phyllosilicates and aqueous minerals are observed nearly everywhere we can see the ancient rocks on Mars. Most bountiful among these is Fe/Mg-smectite. In this study we evaluate the nature and stratigraphy of clay outcrops observed on Mars and the presence of mixtures of other clays or other minerals with the ubiquitous Fe/Mg-smectite.

Published
2017

4. On the Relationship between Cosmic Ray Exposure Ages and Petrography of CM Chondrites

Author

Takenouchi, A, Zolensky, M. E, Nishiizumi, K, Caffee, M, Velbel, M. A, Ross, K, Zolensky, A, Lee, L, Imae, N, Yamaguchi, A, and Mikouchi, T

Subjects
Geophysics
Abstract

Carbonaceous (C) chondrites are potentially the most primitive among chondrites because they mostly escaped thermal metamorphism that affected the other chondrite groups. C chondrites are chemically distinguished from other chondrites by their high Mg/Si ratios and refractory elements, and have experienced various degrees of aqueous alteration. They are subdivided into eight subgroups (CI, CM, CO, CV, CK, CR, CB and CH) based on major element and oxygen isotopic ratios. Their elemental ratios vary over a wide range, in contrast to those of ordinary and enstatite chondrites which are relatively uniform. It is critical to know how many separate bodies are represented by the C chondrites. In this study we defined 4 distinct cosmic-ray exposure (CRE) age groups of CMs and systematically characterized the petrography in each of the 4 CRE age groups to determine whether the groups have significant petrographic differences with such differences probably reflecting different parent body (asteroid) geological processing, or multiple original bodies. We have reported the results of a preliminary grouping at the NIPR Symp. in 2013 [3], however, we revised the grouping and here report our new results.

Published
2014

5. What Are Space Exposure Histories Telling Us about CM Carbonaceous Chondrites?

Author

Takenouchi, A, Zolensky, Michael E, Nishiizumi, K, Caffee, M, Velbel, M. A, Ross, K, Zolensky, P, Le, L, Imae, N, Yamaguchi, A, and Mikouchi, T

Subjects
Lunar And Planetary Science And Exploration
Abstract

Chondrites are chemically primitive and carbonaceous (C) chondrites are potentially the most primitive among them because they mostly escaped thermal metamor-phism that affected the other chondrite groups and ratios of their major, non-volatile and most of the volatile elements are similar to those of the Sun. Therefore, C chondrites are ex-pected to retain a good record of the origin and early history of the solar system. Carbonaceous chondrites are chemically differentiated from other chondrites by their high Mg/Si ratios and refractory elements, and have experienced various degrees of aqueous alteration. They are subdivided into eight subgroups (CI, CM, CO, CV, CK, CR, CB and CH) based on major element and oxygen isotopic ratios. Their elemental ratios spread over a wide range though those of ordinary and enstatite chondrites are relatively uniform. It is critical to know how many sepa-rate bodies are represented by the C chondrites. In this study, CM chondrites, the most abundant carbona-ceous chondrites, are examined. They are water-rich, chon-drule- and CAI-bearing meteorites and most of them are brec-cias. High-temperature components such as chondrules, iso-lated olivine and CAIs in CMs are frequently altered and some of them are replaced by clay minerals and surrounded by sul-fides whose Fe was derived from mafic silicates. On the basis of degrees of aqueous alteration, CMs have been classified into subtypes from 1 to 2, although Rubin et al. [1] assigned subtype 1 to subtype 2 and subtype 2 to subtype 2.6 using various petrologic properties. The classification is based on petrographic and mineralogic properties. For example, though tochilinite (2[(Fe, Mg, Cu, Ni[])S] 1.57-1.85 [(Mg, Fe, Ni, Al, Ca)(HH)2]) clumps are produced during aqueous alteration, they disappear and sulfide appears with increasing degrees of aqueous alteration. Cosmic-ray exposure (CRE) age measurements of CM chondrites reveal an unusual feature. Though CRE ages of other chondrite groups range from several Myr to tens of Myr, CMs exposure ages are not longer than 7 Myr with one-third of the CM having less than 1 Myr CRE age. For those CM chondrites that have CRE ages <1 Myr, there are two discern-able CRE peaks. Because a CRE age reflects how long a me-teorite is present as a separate body in space, the peaks pre-sumably represent collisional events on the parent body (ies) [2]. In this study we defined 4 distinct CRE age groups of CMs and systematically characterized the petrography in each of the 4 CRE age groups to determine whether the groups have significant petrographic differences, with such differences probably reflecting different parent body (asteroid) geological processing, or multiple original bodies.

Published
2013

7. Compositions of Partly Altered Olivine and Replacement Serpentine in the CM2 Chondrite QUE93005

Author

Velbel, M. A, Tonui, E. K, and Zolensky, M. E

Subjects
Lunar And Planetary Science And Exploration
Abstract

Some phyllosilicates in CM carbonaceous chondrites formed by aqueous alteration of anhydrous precursor phases. Although broad trends in the compositions of hydrous phyllosilicates are recognized and believed to be related to trends in degree of aqueous alteration, details of the reactions that formed specific secondary minerals remain obscure. This paper reports compositional relationships between remnants of partially pseudomorphically (or alteromorphically) replaced silicates and their alteration products (serpentine) in the CM2 chondrite QUE93005 and compares it with previously published results for ALH81002. Reactants and products were characterized by optical petrography, backscattered scanning electron microscopy (BSEM), and electron microprobe. By focusing on serpentine formed from known reactants (olivines), and on only those instances in which some of the reactant silicate remains, direct compositional relationships between reactants and products, and the elemental mobility required by the reactions, can be established. Additional information is included in the original extended abstract.

Published
2005

8. Compositions of Partly Altered Olivine and Replacement Serpentine in the CM2 Chondrites QUE93005 and Nogoya: Implications for Scales of Elemental Redistribution During Aqueous Alteration

Author

Velbel, M. A, Tonui, E. K, and Zolensky, M. E

Subjects
Lunar And Planetary Science And Exploration
Abstract

Some phyllosilicates in CM carbonaceous chondrites formed by aqueous alteration of anhydrous precursor phases. Although broad trends in the compositions of hydrous phyllosilicates are recognized and believed to be related to trends in degree of aqueous alteration, details of the reactions that formed specific secondary minerals remain obscure. This paper reports compositional relationships between remnants of partially pseudomorphically replaced silicates and their alteration products (serpentine) in the CM2 chondrites QUE93005 and Nogoya and compares both with previously published results for Allan Hills 81002. By focusing on serpentine formed from known reactants (olivines), and on only those instances in which some of the reactant silicate remains, direct compositional relationships between reactants and products, and the elemental mobility required by the reactions, can be established.

Published
2003

9. Weathering of Martian Evaporites

Author

Wentworth, S. J, Velbel, M. A, Thomas-Keprta, K. L, Longazo, T. G, and McKay, D. S

Subjects
Lunar And Planetary Science And Exploration
Abstract

Evaporites in martian meteorites contain weathering or alteration features that may provide clues about the martian near-surface environment over time. Additional information is contained in the original extended abstract.

Published
2001

10. Weathering and Soil-Forming Processes

Author

Velbel, M. A., Billings, W. D., editor, Golley, F., editor, Lange, O. L., editor, Olson, J. S., editor, Remmert, H., editor, Swank, Wayne T., editor, and Crossley, D. A., Jr., editor

Published
1988
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12. Mineralogy and petrology of Comet Wild-2 nucleus samples - Final results of the preliminary examination team

Author

Zolensky, M, Bland, P, Bradley, J, Brearley, A, Brennan, S, Bridges, J, Brownlee, D, Butterworth, A, Dai, ZR, Ebel, D, Genge, M, Gounelle, M, Graham, G, Grossman, J, Grossman, L, Harvey, R, Ishii, H, Kearsley, A, Keller, L, Krot, A, Langenhorst, F, Lanzirotti, A, Leroux, H, Matrajt, G, Messenger, K, Mikouchi, T, Nakamura, T, Ohsumi, K, Okudaira, K, Perronnet, M, Rietmeijer, F, Simon, S, Stephan, T, Stroud, R, Taheri, M, Tomeoka, K, Toppani, A, Tsou, P, Tsuchiyama, A, Velbel, M, Weber, I, Weisberg, M, Westphal, A, Yano, H, Zega, T, and Stardust Mineralogy Petrology

Abstract

Accepted version

Published
2006

14. Mineralogy and petrology of comet 81P/wild 2 nucleus samples

Author

Zolensky, M., Zega, T., Yano, H., Wirick, S., Westphal, A., Weisberg, M., Weber, I., Warren, J., Velbel, M., Tsuchiyama, A., Tsou, P., Toppani, A., Tomioka, N., Tomeoka, K., Teslich, N., Taheri, M., Susini, J., Stroud, R., Stephan, T., Stadermann, F., Snead, C., Simon, S., Simionovici, A., See, T., Robert, F., Rietmeijer, F., Rao, W., Perronnet, M., Papanastassiou, D., Okudaira, K., Ohsumi, K., Ohnishi, I., Nakamura-Messenger, K., Nakamura, T., Mostefaoui, S., Mikouchi, T., Meibom, A., Matrajt, G., Marcus, M., Leroux, H., Lemelle, L., Le, L., Lanzirotti, A., Langenhorst, F., Krot, A., Keller, L., Kearsley, A., Joswiak, D., Jacob, D., Ishii, H., Harvey, R., Hagiya, K., Grossman, L., Grossman, J., Graham, G., Gounelle, M., Gillet, P., Genge, M., Flynn, G., Ferroir, T., Fallon, S., Ebel, D., Dai, Z., Cordier, P., Clark, B., Chi, M., Butterworth, A., Brownlee, D., Bridges, J., Brennan, S., Brearley, A., Bradley, J., Bleuet, P., Bland, Phil, Bastien, R., Zolensky, M., Zega, T., Yano, H., Wirick, S., Westphal, A., Weisberg, M., Weber, I., Warren, J., Velbel, M., Tsuchiyama, A., Tsou, P., Toppani, A., Tomioka, N., Tomeoka, K., Teslich, N., Taheri, M., Susini, J., Stroud, R., Stephan, T., Stadermann, F., Snead, C., Simon, S., Simionovici, A., See, T., Robert, F., Rietmeijer, F., Rao, W., Perronnet, M., Papanastassiou, D., Okudaira, K., Ohsumi, K., Ohnishi, I., Nakamura-Messenger, K., Nakamura, T., Mostefaoui, S., Mikouchi, T., Meibom, A., Matrajt, G., Marcus, M., Leroux, H., Lemelle, L., Le, L., Lanzirotti, A., Langenhorst, F., Krot, A., Keller, L., Kearsley, A., Joswiak, D., Jacob, D., Ishii, H., Harvey, R., Hagiya, K., Grossman, L., Grossman, J., Graham, G., Gounelle, M., Gillet, P., Genge, M., Flynn, G., Ferroir, T., Fallon, S., Ebel, D., Dai, Z., Cordier, P., Clark, B., Chi, M., Butterworth, A., Brownlee, D., Bridges, J., Brennan, S., Brearley, A., Bradley, J., Bleuet, P., Bland, Phil, and Bastien, R.

Published
2006

15. Comet 81P/Wild 2 Under a Microscope

Author

Brownlee, D., Tsou, P., Aléon, J., Alexander, C., Araki, T., Bajt, S., Baratta, G., Bastien, R., Bland, Phil, Bleuet, P., Borg, J., Bradley, J., Brearley, A., Brenker, F., Brennan, S., Bridges, J., Browning, N., Brucato, J., Bullock, E., Burchell, M., Busemann, H., Butterworth, A., Chaussidon, M., Cheuvront, A., Chi, M., Cintala, M., Clark, B., Clemett, S., Cody, G., Colangeli, L., Cooper, G., Cordier, P., Daghlian, C., Dai, Z., D’Hendecourt, L., Djouadi, Z., Dominguez, G., Duxbury, T., Dworkin, J., Ebel, D., Economou, T., Fakra, S., Fairey, S., Fallon, S., Ferrini, G., Ferroir, T., Fleckenstein, H., Floss, C., Flynn, G., Franchi, I., Fries, M., Gainsforth, Z., Gallien, J., Genge, M., Gilles, M., Gillet, P., Gilmour, J., Glavin, D., Gounelle, M., Grady, M., Graham, G., Grant, P., Green, S., Grossemy, F., Grossman, L., Grossman, J., Guan, Y., Hagiya, K., Harvey, R., Heck, P., Herzog, G., Hoppe, P., Hörz, F., Huth, J., Hutcheon, I., Ignatyev, K., Ishii, H., Ito, M., Jacob, D., Jacobsen, C., Jacobsen, S., Jones, S., Joswiak, D., Jurewicz, A., Kearsley, A., Keller, L., Khodja, H., Kilcoyne, A., Kissel, J., Krot, A., Langenhorst, F., Lanzirotti, A., Le, L., Leshin, L., Leitner, J., Lemelle, L., Leroux, H., Liu, M., Luening, K., Lyon, I., MacPherson, G., Marcus, M., Marhas, K., Marty, B., Matrajt, G., McKeegan, K., Meibom, A., Mennella, V., Messenger, K., Messenger, S., Mikouchi, T., Mostefaoui, S., Nakamura, T., Newville, M., Nittler, L., Ohnishi, I., Ohsumi, K., Okudaira, K., Papanastassiou, D., Palma, R., Palumbo, M., Pepin, R., Perkins, D., Perronnet, M., Pianetta, P., Rao, W., Rietmeijer, F., Robert, F., Rost, D., Rotundi, A., Ryan, R., Sandford, S., Schwandt, C., See, T., Schlutter, D., Sheffield-Parker, J., Simionovici, A., Simon, S., Sitnitsky, I., Snead, C., Stephan, T., Stadermann, F., Steele, A., Stroud, R., Susini, J., Sutton, S., Suzuki, Y., Taheri, M., Taylor, S., Teslich, N., Tomeoka, K., Tomioka, N., Toppani, A., Trigo-Rodríguez, J., Troadec, D., Tsuchiyama, A., Tuzzolino, A., Tyliszczak, T., Uesugi, K., Velbel, M., Vellenga, J., Vicenzi, E., Vincze, L., Warren, J., Weber, I., Weisberg, M., Westphal, A., Wirick, S., Wooden, D., Wopenka, B., Wozniakiewicz, P., Wright, I., Yabuta, H., Yano, H., Young, E., Zare, R., Zega, T., Ziegler, K., Zimmerman, L., Zinner, E., Zolensky, M., Brownlee, D., Tsou, P., Aléon, J., Alexander, C., Araki, T., Bajt, S., Baratta, G., Bastien, R., Bland, Phil, Bleuet, P., Borg, J., Bradley, J., Brearley, A., Brenker, F., Brennan, S., Bridges, J., Browning, N., Brucato, J., Bullock, E., Burchell, M., Busemann, H., Butterworth, A., Chaussidon, M., Cheuvront, A., Chi, M., Cintala, M., Clark, B., Clemett, S., Cody, G., Colangeli, L., Cooper, G., Cordier, P., Daghlian, C., Dai, Z., D’Hendecourt, L., Djouadi, Z., Dominguez, G., Duxbury, T., Dworkin, J., Ebel, D., Economou, T., Fakra, S., Fairey, S., Fallon, S., Ferrini, G., Ferroir, T., Fleckenstein, H., Floss, C., Flynn, G., Franchi, I., Fries, M., Gainsforth, Z., Gallien, J., Genge, M., Gilles, M., Gillet, P., Gilmour, J., Glavin, D., Gounelle, M., Grady, M., Graham, G., Grant, P., Green, S., Grossemy, F., Grossman, L., Grossman, J., Guan, Y., Hagiya, K., Harvey, R., Heck, P., Herzog, G., Hoppe, P., Hörz, F., Huth, J., Hutcheon, I., Ignatyev, K., Ishii, H., Ito, M., Jacob, D., Jacobsen, C., Jacobsen, S., Jones, S., Joswiak, D., Jurewicz, A., Kearsley, A., Keller, L., Khodja, H., Kilcoyne, A., Kissel, J., Krot, A., Langenhorst, F., Lanzirotti, A., Le, L., Leshin, L., Leitner, J., Lemelle, L., Leroux, H., Liu, M., Luening, K., Lyon, I., MacPherson, G., Marcus, M., Marhas, K., Marty, B., Matrajt, G., McKeegan, K., Meibom, A., Mennella, V., Messenger, K., Messenger, S., Mikouchi, T., Mostefaoui, S., Nakamura, T., Newville, M., Nittler, L., Ohnishi, I., Ohsumi, K., Okudaira, K., Papanastassiou, D., Palma, R., Palumbo, M., Pepin, R., Perkins, D., Perronnet, M., Pianetta, P., Rao, W., Rietmeijer, F., Robert, F., Rost, D., Rotundi, A., Ryan, R., Sandford, S., Schwandt, C., See, T., Schlutter, D., Sheffield-Parker, J., Simionovici, A., Simon, S., Sitnitsky, I., Snead, C., Stephan, T., Stadermann, F., Steele, A., Stroud, R., Susini, J., Sutton, S., Suzuki, Y., Taheri, M., Taylor, S., Teslich, N., Tomeoka, K., Tomioka, N., Toppani, A., Trigo-Rodríguez, J., Troadec, D., Tsuchiyama, A., Tuzzolino, A., Tyliszczak, T., Uesugi, K., Velbel, M., Vellenga, J., Vicenzi, E., Vincze, L., Warren, J., Weber, I., Weisberg, M., Westphal, A., Wirick, S., Wooden, D., Wopenka, B., Wozniakiewicz, P., Wright, I., Yabuta, H., Yano, H., Young, E., Zare, R., Zega, T., Ziegler, K., Zimmerman, L., Zinner, E., and Zolensky, M.

Published
2006

27. GRAIN-SURFACE TEXTURAL INDICATORS OF VOLATILES IN TERRESTRIAL MARS-REGOLITH ANALOGS: IMPLICATIONS FOR INTERPRETING SAND AND SILT IMAGED BY THE PHOENIX OP-TICAL MICROSCOPE AT THE PHOENIX MARS LANDER LANDING SITE - II.

Author

Velbel, M. A., Slajus, L. S., Wade, B. D., Conrad, P. R., Costello, Q. J., Harju, M. G., Hunnewell, K. A., Jackson, L. S., Kurtz, P. R., Marcero, J. R., Mason, A. M., Muethel, A.C., Mukhtar, J., O'Connor, M. P., Peterson, L. D., Quinn, J. A., Shehi, L. J., and Walker, I. C.

Subjects
REGOLITH, MARS (Planet)
Published
2017

31. A dissolution-reprecipitation mechanism for the pseudomorphous replacement of plagioclase feldspar by clay minerals during weathering

Author

Velbel, M. A.

Abstract

Plagioclase replacement during weathering of high-grade gneisses and schists in the southern Appalachians begins with the formation of three kinds of dissolution voids ; prismatic etch pits, vacuoles, and irregular vermiform voids. Etch pits, vacuoles, and embayment of grain margins by overlapping of voids, often display a distinct preference for one of the two sets of albite twin-lamellae. Later precipitation of clays in the dissolution voids results in partial or complete pseudomorphous replacement. Differential susceptibility of twin-lamellae to attack is controlled by differential response of the twin-lamellae to geologic stresses. Differential attack and replacement explain a wide variety of plagioclase alteration and replacement textures., Au cours de l'altération supergène, le remplacement du plagioclase débute par la formation de trois sortes de vides de dissolution : les puits de corrosion prismatiques, les vacuoles et les vides irréguliers en forme de vermicules. Les puits de corrosion, les vacuoles et les golfes sur les bordures des grains, formés par imbrication des vides, montrent une nette préférence pour l'une, des deux séries de lamelles de la macle de l'albite. La précipitation tardive des minéraux argileux dans les vides de dissolution conduit à un remplacement partiel ou total du plagioclase par pseudomorphose. La susceptibilité différentielle à l'altération des lamelles de la macle est contrôlée par la réactivité différente de ces lamelles aux contraintes géologiques. L'attaque et le remplacement différentiels permettent d'expliquer une grande variété des figures d'altération et de remplacement des plagioclases ., Velbel M. A. A dissolution-reprecipitation mechanism for the pseudomorphous replacement of plagioclase feldspar by clay minerals during weathering. In: Pétrologie des altérations et des sols. Vol. I : Pétrologie expérimentale. Colloque international du CNRS, Paris 4-7 juillet 1983. Strasbourg : Institut de Géologie – Université Louis-Pasteur, 1983. pp. 139-147. (Sciences Géologiques. Mémoire, 71)

Published
1983

34. Report of the Science Community Workshop on the proposed First Sample Depot for the Mars Sample Return Campaign

Author

Czaja, A. D., Zorzano, M.‐P., Kminek, G., Meyer, M. A., Beaty, D. W., Sefton‐Nash, E., Carrier, B. L., Thiessen, F., Haltigin, T., Bouvier, A., Dauphas, N., French, K. L., Hallis, L. J., Harris, R. L., Hauber, E., Rodriguez, L. E., Schwenzer, S., Steele, A., Tait, K. T., Thorpe, M. T., Usui, T., Vanhomwegen, J., Velbel, M. A., Edwin, S., Farley, K. A., Glavin, D. P., Harrington, A. D., Hays, L. E., Hutzler, A., Wadhwa, M., Czaja, A. D., Zorzano, M.‐P., Kminek, G., Meyer, M. A., Beaty, D. W., Sefton‐Nash, E., Carrier, B. L., Thiessen, F., Haltigin, T., Bouvier, A., Dauphas, N., French, K. L., Hallis, L. J., Harris, R. L., Hauber, E., Rodriguez, L. E., Schwenzer, S., Steele, A., Tait, K. T., Thorpe, M. T., Usui, T., Vanhomwegen, J., Velbel, M. A., Edwin, S., Farley, K. A., Glavin, D. P., Harrington, A. D., Hays, L. E., Hutzler, A., and Wadhwa, M.

Abstract

The Mars 2020/Mars Sample Return (MSR) Sample Depot Science Community Workshop was held on September 28 and 30, 2022, to assess the Scientifically‐Return Worthy (SRW) value of the full collection of samples acquired by the rover Perseverance at Jezero Crater, and of a proposed subset of samples to be left as a First Depot at a location within Jezero Crater called Three Forks. The primary outcome of the workshop was that the community is in consensus on the following statement: The proposed set of ten sample tubes that includes seven rock samples, one regolith sample, one atmospheric sample, and one witness tube constitutes a SRW collection that: (1) represents the diversity of the explored region around the landing site, (2) covers partially or fully, in a balanced way, all of the International MSR Objectives and Samples Team scientific objectives that are applicable to Jezero Crater, and (3) the analyses of samples in this First Depot on Earth would be of fundamental importance, providing a substantial improvement in our understanding of Mars. At the conclusion of the meeting, there was overall community support for forming the First Depot as described at the workshop and placing it at the Three Forks site. The community also recognized that the diversity of the Rover Cache (the sample collection that remains on the rover after placing the First Depot) will significantly improve with the samples that are planned to be obtained in the future by the Perseverance rover and that the Rover Cache is the primary target for MSR to return to Earth.

40. Time-Sensitive Aspects of Mars Sample Return (MSR) Science

Author

Tosca, N. J., Agee, Carl, Cockell, C., Glavin, D P, Hutzler, Aurore, Marty, B., McCubbin, F. M., Regberg, Aaron, Velbel, Michael, Kminek, G., Meyer, M., Beaty, D.W., Carrier, B. L., Haltigin, T., Hays, Lindsay, Busemann, H., Cavalazzi, Barbara, Debaille, V, Grady, M., Hauber, Ernst, Pratt, Lisa, Smith, Alvin, Smith, C., Summons, R E, Swindle, T. D., Tait, Kimberly, Udry, Arya, Usui, Tomohiro, Wadhwa, M., Westall, F., Zorzano, M.-P., Tosca N. J., Beaty D. W., Carrier B. L., Agee C. B., Cockell C. S., Glavin D. P., Hutzler A., Marty B., McCubbin F. M., Regberg A. B., Velbel M. A., Kminek G., Meyer M. A., Haltigin T., Busemann H., Cavalazzi B., Debaille V., Grady M. M., Hauber E., Hays L. E., Pratt L. M., Smith A. L., Smith C. L., Summons R. E., Swindle T. D., Tait K. T., Udry A., Usui T., Wadhwa M., Westall F., Zorzano M. -P., University of Cambridge [UK] (CAM), The University of New Mexico [Albuquerque], University of Edinburgh, NASA Goddard Space Flight Center (GSFC), European Space Agency (ESA), Centre de Recherches Pétrographiques et Géochimiques (CRPG), Institut national des sciences de l'Univers (INSU - CNRS)-Université de Lorraine (UL)-Centre National de la Recherche Scientifique (CNRS), NASA Johnson Space Center (JSC), NASA, Michigan State University [East Lansing], Michigan State University System, Smithsonian Institution, NASA Headquarters, California Institute of Technology (CALTECH), Canadian Space Agency (CSA), Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), University of Bologna, Université libre de Bruxelles (ULB), The Open University [Milton Keynes] (OU), German Aerospace Center (DLR), Indiana University [Bloomington], Indiana University System, The Natural History Museum [London] (NHM), University of Glasgow, Massachusetts Institute of Technology (MIT), University of Arizona, Royal Ontario Museum, University of Nevada [Las Vegas] (WGU Nevada), Japan Aerospace Exploration Agency [Sagamihara] (JAXA), Arizona State University [Tempe] (ASU), Centre de biophysique moléculaire (CBM), Université d'Orléans (UO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC), University of Aberdeen, Tosca, Nicholas [0000-0003-4415-4231], and Apollo - University of Cambridge Repository

Subjects
Minerals, geology, Extraterrestrial Environment, laboratory experiments, Sulfates, [SDV]Life Sciences [q-bio], astrobiology, Mars, Space Flight, Mars Sample Return (MSR) Science, sample return, Agricultural and Biological Sciences (miscellaneous), Space and Planetary Science, Exobiology, Clay, Gases
Abstract

Samples returned from Mars would be placed under quarantine at a Sample Receiving Facility (SRF) until they are considered safe to release to other laboratories for further study. The process of determining whether samples are safe for release, which may involve detailed analysis and/or sterilization, is expected to take several months. However, the process of breaking the sample tube seal and extracting the headspace gas will perturb local equilibrium conditions between gas and rock and set in motion irreversible processes that proceed as a function of time. Unless these time-sensitive processes are understood, planned for, and/or monitored during the quarantine period, scientific information expected from further analysis may be lost forever. At least four processes underpin the time-sensitivity of Mars returned sample science: (1) degradation of organic material of potential biological origin, (2) modification of sample headspace gas composition, (3) mineral-volatile exchange, and (4) oxidation/reduction of redox-sensitive materials. Available constraints on the timescales associated with these processes supports the conclusion that an SRF must have the capability to characterize attributes such as sample tube headspace gas composition, organic material of potential biological origin, as well as volatiles and their solid-phase hosts. Because most time-sensitive investigations are also sensitive to sterilization, these must be completed inside the SRF and on timescales of several months or less. To that end, we detail recommendations for how sample preparation and analysis could complete these investigations as efficiently as possible within an SRF. Finally, because constraints on characteristic timescales that define time-sensitivity for some processes are uncertain, future work should focus on: (1) quantifying the timescales of volatile exchange for core material physically and mineralogically similar to samples expected to be returned from Mars, and (2) identifying and developing stabilization or temporary storage strategies that mitigate volatile exchange until analysis can be completed. Executive Summary Any samples returned from Mars would be placed under quarantine at a Sample Receiving Facility (SRF) until it can be determined that they are safe to release to other laboratories for further study. The process of determining whether samples are safe for release, which may involve detailed analysis and/or sterilization, is expected to take several months. However, the process of breaking the sample tube seal and extracting the headspace gas would perturb local equilibrium conditions between gas and rock and set in motion irreversible processes that proceed as a function of time. Unless these processes are understood, planned for, and/or monitored during the quarantine period, scientific information expected from further analysis may be lost forever. Specialist members of the Mars Sample Return Planning Group Phase 2 (MSPG-2), referred to here as the Time-Sensitive Focus Group, have identified four processes that underpin the time-sensitivity of Mars returned sample science: (1) degradation of organic material of potential biological origin, (2) modification of sample headspace gas composition, (3) mineral-volatile exchange, and (4) oxidation/reduction of redox-sensitive materials (Figure 2). Consideration of the timescales and the degree to which these processes jeopardize scientific investigations of returned samples supports the conclusion that an SRF must have the capability to characterize: (1) sample tube headspace gas composition, (2) organic material of potential biological origin, (3) volatiles bound to or within minerals, and (4) minerals or other solids that host volatiles (Table 4). Most of the investigations classified as time-sensitive in this report are also sensitive to sterilization by either heat treatment and/or gamma irradiation (Velbel et al., 2022). Therefore, these investigations must be completed inside biocontainment and on timescales that minimize the irrecoverable loss of scientific information (i.e., several months or less; Section 5). To that end, the Time-Sensitive Focus Group has outlined a number of specific recommendations for sample preparation and instrumentation in order to complete these investigations as efficiently as possible within an SRF (Table 5). Constraints on the characteristic timescales that define time-sensitivity for different processes can range from relatively coarse to uncertain (Section 4). Thus, future work should focus on: (1) quantifying the timescales of volatile exchange for variably lithified core material physically and mineralogically similar to samples expected to be returned from Mars, and (2) identifying and developing stabilization strategies or temporary storage strategies that mitigate volatile exchange until analysis can be completed. List of Findings FINDING T-1: Aqueous phases, and oxidants liberated by exposure of the sample to aqueous phases, mediate and accelerate the degradation of critically important but sensitive organic compounds such as DNA. FINDING T-2: Warming samples increases reaction rates and destroys compounds making biological studies much more time-sensitive. MAJOR FINDING T-3: Given the potential for rapid degradation of biomolecules, (especially in the presence of aqueous phases and/or reactive O-containing compounds) Sample Safety Assessment Protocol (SSAP) and parallel biological analysis are time sensitive and must be carried out as soon as possible. FINDING T-4: If molecules or whole cells from either extant or extinct organisms have persisted under present-day martian conditions in the samples, then it follows that preserving sample aliquots under those same conditions (i.e., 6 mbar total pressure in a dominantly CO2 atmosphere and at an average temperature of -80°C) in a small isolation chamber is likely to allow for their continued persistence. FINDING T-5: Volatile compounds (e.g., HCN and formaldehyde) have been lost from Solar System materials stored under standard curation conditions. FINDING T-6: Reactive O-containing species have been identified in situ at the martian surface and so may be present in rock or regolith samples returned from Mars. These species rapidly degrade organic molecules and react more rapidly as temperature and humidity increase. FINDING T-7: Because the sample tubes would not be closed with perfect seals and because, after arrival on Earth, there will be a large pressure gradient across that seal such that the probability of contamination of the tube interiors by terrestrial gases increases with time, the as-received sample tubes are considered a poor choice for long-term gas sample storage. This is an important element of time sensitivity. MAJOR FINDING T-8: To determine how volatiles may have been exchanged with headspace gas during transit to Earth, the composition of martian atmosphere (in a separately sealed reservoir and/or extracted from the witness tubes), sample headspace gas composition, temperature/time history of the samples, and mineral composition (including mineral-bound volatiles) must all be quantified. When the sample tube seal is breached, mineral-bound volatile loss to the curation atmosphere jeopardizes robust determination of volatile exchange history between mineral and headspace. FINDING T-9: Previous experiments with mineral powders show that sulfate minerals are susceptible to H2O loss over timescales of hours to days. In addition to volatile loss, these processes are accompanied by mineralogical transformation. Thus, investigations targeting these minerals should be considered time-sensitive. FINDING T-10: Sulfate minerals may be stabilized by storage under fixed relative-humidity conditions, but only if the identity of the sulfate phase(s) is known a priori. In addition, other methods such as freezing may also stabilize these minerals against volatile loss. FINDING T-11: Hydrous perchlorate salts are likely to undergo phase transitions and volatile exchange with ambient surroundings in hours to days under temperature and relative humidity ranges typical of laboratory environments. However, the exact timescale over which these processes occur is likely a function of grain size, lithification, and/or cementation. FINDING T-12: Nanocrystalline or X-ray amorphous materials are typically stabilized by high proportions of surface adsorbed H2O. Because this surface adsorbed H2O is weakly bound compared to bulk materials, nanocrystalline materials are likely to undergo irreversible ripening reactions in response to volatile loss, which in turn results in decreases in specific surface area and increases in crystallinity. These reactions are expected to occur over the timescale of weeks to months under curation conditions. Therefore, the crystallinity and specific surface area of nanocrystalline materials should be characterized and monitored within a few months of opening the sample tubes. These are considered time-sensitive measurements that must be made as soon as possible. FINDING T-13: Volcanic and impact glasses, as well as opal-CT, are metastable in air and susceptible to alteration and volatile exchange with other solid phases and ambient headspace. However, available constraints indicate that these reactions are expected to proceed slowly under typical laboratory conditions (i.e., several years) and so analyses targeting these materials are not considered time sensitive. FINDING T-14: Surface adsorbed and interlayer-bound H2O in clay minerals is susceptible to exchange with ambient surroundings at timescales of hours to days, although the timescale may be modified depending on the degree of lithification or cementation. Even though structural properties of clay minerals remain unaffected during this process (with the exception of the interlayer spacing), investigations targeting H2O or other volatiles bound on or within clay minerals should be considered time sensitive upon opening the sample tube. FINDING T-15: Hydrated Mg-carbonates are susceptible to volatile loss and recrystallization and transformation over timespans of months or longer, though this timescale may be modified by the degree of lithification and cementation. Investigations targeting hydrated carbonate minerals (either the volatiles they host or their bulk mineralogical properties) should be considered time sensitive upon opening the sample tube. MAJOR FINDING T-16: Current understanding of mineral-volatile exchange rates and processes is largely derived from monomineralic experiments and systems with high surface area; lithified sedimentary rocks (accounting for some, but not all, of the samples in the cache) will behave differently in this regard and are likely to be associated with longer time constants controlled in part by grain boundary diffusion. Although insufficient information is available to quantify this at the present time, the timescale of mineral-volatile exchange in lithified samples is likely to overlap with the sample processing and curation workflow (i.e., 1-10 months; Table 4). This underscores the need to prioritize measurements targeting mineral-hosted volatiles within biocontainment. FINDING T-17: The liberation of reactive O-species through sample treatment or processing involving H2O (e.g., rinsing, solvent extraction, particle size separation in aqueous solution, or other chemical extraction or preparation protocols) is likely to result in oxidation of some component of redox-sensitive materials in a matter of hours. The presence of reactive O-species should be examined before sample processing steps that seek to preserve or target redox-sensitive minerals. Electron paramagnetic resonance spectroscopy (EPR) is one example of an effective analytical method capable of detecting and characterizing the presence of reactive O-species. FINDING T-18: Environments that maintain anoxia under inert gas containing <

Published
2022
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41. Final report of the MSR Science Planning Group 2 (MSPG2)

Author

Meyer, Michael A, Kminek, Gerhard, Beaty, David W, Carrier, Brandi Lee, Haltigin, Timothy, Hays, Lindsay E, Agee, Carl B., Busemann, Henner, Cavalazzi, Barbara, Cockell, Charles S., Debaille, Vinciane, Glavin, Daniel P., Grady, Monica M., Hauber, Ernst, Hutzler, Aurore, Marty, Bernard, McCubbin, Francis M., Pratt, Lisa M, Regberg, Aaron B., Smith, Alvin L, Smith, Caroline L, Summons, Roger E., Swindle, Timothy D, Tait, Kimberly T, Tosca, Nicholas J., Udry, Arya, Usui, Tomohiro, Velbel, Michael A., Wadhwa, Meenakshi, Westall, Frances, Zorzano, Maria-Paz, NASA Headquarters, European Space Agency (ESA), California Institute of Technology (CALTECH), Canadian Space Agency (CSA), The University of New Mexico [Albuquerque], Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), University of Bologna, University of Edinburgh, Université libre de Bruxelles (ULB), NASA Goddard Space Flight Center (GSFC), The Open University [Milton Keynes] (OU), German Aerospace Center (DLR), Centre de Recherches Pétrographiques et Géochimiques (CRPG), Institut national des sciences de l'Univers (INSU - CNRS)-Université de Lorraine (UL)-Centre National de la Recherche Scientifique (CNRS), Astromaterials Research and Exploration Science (ARES), NASA Johnson Space Center (JSC), NASA-NASA, Indiana University [Bloomington], Indiana University System, NASA, The Natural History Museum [London] (NHM), University of Glasgow, Massachusetts Institute of Technology (MIT), University of Arizona, Royal Ontario Museum, University of Cambridge [UK] (CAM), University of Nevada [Las Vegas] (WGU Nevada), Japan Aerospace Exploration Agency [Sagamihara] (JAXA), Michigan State University [East Lansing], Michigan State University System, Smithsonian Institution, Arizona State University [Tempe] (ASU), Centre de biophysique moléculaire (CBM), Université d'Orléans (UO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC), University of Aberdeen, Meyer M. A., Kminek G., Beaty D. W., Carrier B. L., Haltigin T., Hays L. E., Agee C. B., Busemann H., Cavalazzi B., Cockell C. S., Debaille V., Glavin D. P., Grady M. M., Hauber E., Hutzler A., Marty B., McCubbin F. M., Pratt L. M., Regberg A. B., Smith A. L., Smith C. L., Summons R. E., Swindle T. D., Tait K. T., Tosca N. J., Udry A., Usui T., Velbel M. A., Wadhwa M., Westall F., and Zorzano M. -P.

Subjects
[SDU]Sciences of the Universe [physics], Mars Sample Return (MSR) Campaign
Abstract

International audience; The Mars Sample Return (MSR) Campaign must meet a series of scientific and technical achievements to be successful. While the respective engineering responsibilities to retrieve the samples have been formalized through a Memorandum of Understanding between ESA and NASA, the roles and responsibilities of the scientific elements have yet to be fully defined. In April 2020, ESA and NASA jointly chartered the MSR Science Planning Group 2 (MSPG2) to build upon previous planning efforts in defining 1) an end-to-end MSR Science Program and 2) needed functionalities and design requirements for an MSR Sample Receiving Facility (SRF). The challenges for the first samples brought from another planet include not only maintaining and providing samples in pristine condition for study, but also maintaining biological containment until the samples meet sample safety criteria for distribution outside of biocontainment. The MSPG2 produced six reports outlining 66 findings. Abbreviated versions of the five additional high-level MSPG2 summary findings are: Summary-1. A long-term NASA/ESA MSR Science Program, along with the necessary funding and human resources, will be required to accomplish the end-to-end scientific objectives of MSR. Summary-2. MSR curation will need to be done concurrently with Biosafety Level-4 containment. This would lead to complex first-of-a-kind curation implementations and require further technology development. Summary-3. Most aspects of MSR sample science can, and should, be performed on samples deemed safe in laboratories outside of the SRF. However, other aspects of MSR sample science are both time-sensitive and sterilization-sensitive and would need to be carried out in the SRF. Summary-4. To meet the unique science, curation, and planetary protection needs of MSR, substantial analytical and sample management capabilities would be required in an SRF. Summary-5. Because of the long lead-time for SRF design, construction, and certification, it is important that preparations begin immediately, even if there is delay in the return of samples.

Published
2022
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42. Science and Curation Considerations for the Design of a Mars Sample Return (MSR) Sample Receiving Facility

Author

Carrier, B. L., Beaty, D., Hutzler, Aurore, Smith, Alvin, Kminek, G., Meyer, M., Haltigin, T., Hays, Lindsay, Agee, Carl, Busemann, H., Cavalazzi, B., Cockell, C., Debaille, V, Glavin, D P, Grady, M., Hauber, Ernst, Marty, B., McCubbin, F. M., Pratt, Lisa, Regberg, Aaron, Smith, C., Summons, R E, Swindle, T. D., Tait, Kimberly, Tosca, N. J., Udry, Arya, Usui, Tomohiro, Velbel, Michael, Wadhwa, M., Westall, F., Zorzano, M.-P., California Institute of Technology (CALTECH), European Space Agency (ESA), NASA Headquarters, Canadian Space Agency (CSA), The University of New Mexico [Albuquerque], Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), University of Bologna, University of Edinburgh, Université libre de Bruxelles (ULB), NASA Goddard Space Flight Center (GSFC), The Open University [Milton Keynes] (OU), German Aerospace Center (DLR), Centre de Recherches Pétrographiques et Géochimiques (CRPG), Institut national des sciences de l'Univers (INSU - CNRS)-Université de Lorraine (UL)-Centre National de la Recherche Scientifique (CNRS), NASA Johnson Space Center (JSC), NASA, Indiana University [Bloomington], Indiana University System, The Natural History Museum [London] (NHM), University of Glasgow, Massachusetts Institute of Technology (MIT), University of Arizona, Royal Ontario Museum, University of Cambridge [UK] (CAM), University of Nevada [Las Vegas] (WGU Nevada), Japan Aerospace Exploration Agency [Tokyo] (JAXA), Michigan State University [East Lansing], Michigan State University System, Smithsonian Institution, Arizona State University [Tempe] (ASU), Centre de biophysique moléculaire (CBM), Université d'Orléans (UO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC), University of Aberdeen, Agence Spatiale Européenne = European Space Agency (ESA), University of Bologna/Università di Bologna, Université d'Orléans (UO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Frapart, Isabelle, Carrier B. L., Beaty D. W., Hutzler A., Smith A. L., Kminek G., Meyer M. A., Haltigin T., Hays L. E., Agee C. B., Busemann H., Cavalazzi B., Cockell C. S., Debaille V., Glavin D. P., Grady M. M., and Hauber E., Marty B., McCubbin F. M., Pratt L. M., Regberg A. B., Smith C. L., Summons R. E., Swindle T. D., Tait K. T., Tosca N. J., Udry A., Usui T., Velbel M. A., Wadhwa M., Westall F., Zorzano M. -P.

Subjects
geology, Extraterrestrial Environment, laboratory experiments, Sample Safety Assessment Protocol (SSAP), Plant Extracts, astrobiology, Reproducibility of Results, Mars, intrumentation, Space Flight, sample return, Agricultural and Biological Sciences (miscellaneous), [SDU] Sciences of the Universe [physics], containment, contamination, Space and Planetary Science, [SDU]Sciences of the Universe [physics], Sample Receiving Facility (SRF), Mars Sample Return (MSR) Campaign, Spacecraft
Abstract

The most important single element of the "ground system" portion of a Mars Sample Return (MSR) Campaign is a facility referred to as the Sample Receiving Facility (SRF), which would need to be designed and equipped to receive the returned spacecraft, extract and open the sealed sample container, extract the samples from the sample tubes, and implement a set of evaluations and analyses of the samples. One of the main findings of the first MSR Sample Planning Group (MSPG, 2019a) states that "The scientific community, for reasons of scientific quality, cost, and timeliness, strongly prefers that as many sample-related investigations as possible be performed in PI-led laboratories outside containment." There are many scientific and technical reasons for this preference, including the ability to utilize advanced and customized instrumentation that may be difficult to reproduce inside in a biocontained facility, and the ability to allow multiple science investigators in different labs to perform similar or complementary analyses to confirm the reproducibility and accuracy of results. It is also reasonable to assume that there will be a desire for the SRF to be as efficient and economical as possible, while still enabling the objectives of MSR to be achieved. For these reasons, MSPG concluded, and MSPG2 agrees, that the SRF should be designed to accommodate only those analytical activities that could not reasonably be done in outside laboratories because they are time- or sterilization-sensitive, are necessary for the Sample Safety Assessment Protocol (SSAP), or are necessary parts of the initial sample characterization process that would allow subsamples to be effectively allocated for investigation. All of this must be accommodated in an SRF, while preserving the scientific value of the samples through maintenance of strict environmental and contamination control standards. Executive Summary The most important single element of the "ground system" portion of a Mars Sample Return (MSR) Campaign is a facility referred to as the Sample Receiving Facility (SRF), which would need to be designed and equipped to enable receipt of the returned spacecraft, extraction and opening of the sealed sample container, extraction of the samples from the sample tubes, and a set of evaluations and analyses of the samples-all under strict protocols of biocontainment and contamination control. Some of the important constraints in the areas of cost and required performance have not yet been set by the necessary governmental sponsors, but it is reasonable to assume there will be a desire for the SRF to be as efficient and economical as is possible, while still enabling the objectives of MSR science to be achieved. Additionally, one of the main findings of MSR Sample Planning Group (MSPG, 2019a) states "The scientific community, for reasons of scientific quality, cost, and timeliness, strongly prefers that as many sample-related investigations as possible be performed in PI-led laboratories outside containment." There are many scientific and technical reasons for this preference, including the ability to utilize advanced and customized instrumentation that may be difficult to reproduce inside a biocontained facility. Another benefit is the ability to enable similar or complementary analyses by multiple science investigators in different laboratories, which would confirm the reproducibility and accuracy of results. For these reasons, the MSPG concluded-and the MSR Science Planning Group Phase 2 (MSPG2) agrees-that the SRF should be designed to accommodate only those analytical activities inside biocontainment that could

Published
2021
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45. Dissolution of pyroxenes and amphiboles during weathering.

Author

Berner RA, Sjöberg EL, Velbel MA, and Krom MD

Abstract

Augite, hypersthene, diopside, and hornblende all undergo dissolution during weathering by means of the formation, growth, and coalescence of distinctive, parallel, lens-shaped etch pits. Similar etch features can be produced if these minerals are treated in the laboratory with concentrated hydrofluoric acid plus hydrochloric acid. These pits most likely form at dislocation outcrops, and their shape and orientation are controlled primarily by the crystallography of the underlying mineral. The results are similar to those found for soil feldspars and suggest that silicate weathering, in general, takes place by selective etching and not by general attack of the surface with consequent rounding as necessiated by bulk diffusion-type weathering theories.

Published
1980
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