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1. In-situ Optimized Substrate Witness Plates: Ground Truth for Key Processes on the Moon and Other Planets

Author

Saxena, Prabal, Morrissey, Liam S., Killen, Rosemary M., McLain, Jason L., Yeo, Li Hsia, Curran, Natalie M., Abraham, Nithin S., Graham, Heather V., Tucker, Orenthal J., Sarantos, Menelaos, Regberg, Aaron B., Pugel, Diane E., Needham, Andrew W., Hasegawa, Mark, and Wong, Alfred J.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

Future exploration efforts of the Moon, Mars and other bodies are poised to focus heavily on persistent and sustainable survey and research efforts, especially given the recent interest in a long-term sustainable human presence at the Moon. Key to these efforts is understanding a number of important processes on the lunar surface for both scientific and operational purposes. We discuss the potential value of in-situ artificial substrate witness plates, powerful tools that can supplement familiar remote sensing and sample acquisition techniques and provide a sustainable way of monitoring processes in key locations on planetary surfaces while maintaining a low environmental footprint. These tools, which we call Biscuits, can use customized materials as wide ranging as zircon-based spray coatings to metals potentially usable for surface structures, to target specific processes/questions as part of a small, passive witness plate that can be flexibly placed with respect to location and total time duration. We examine and discuss unique case studies to show how processes such as water presence/transport, presence and contamination of biologically relevant molecules, solar activity related effects, and other processes can be measured using Biscuits. Biscuits can yield key location sensitive, time integrated measurements on these processes to inform scientific understanding of the Moon and enable operational goals in lunar exploration. While we specifically demonstrate this on a simulated traverse and for selected examples, we stress all groups interested in planetary surfaces should consider these adaptable, low footprint and highly informative tools for future exploration., Comment: Accepted to Earth and Space Science, Will be updated upon publication

Published
2023
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3. In Situ Optimized Substrate Witness Plates: Ground Truth for Key Processes on the Moon and Other Planets

Author

Saxena, Prabal, primary, Morrissey, Liam S., additional, Killen, Rosemary M., additional, McLain, Jason L., additional, Yeo, Li Hsia, additional, Curran, Natalie M., additional, Abraham, Nithin S., additional, Graham, Heather V., additional, Tucker, Orenthal J., additional, Sarantos, Menelaos, additional, Regberg, Aaron B., additional, Pugel, Diane E., additional, Needham, Andrew W., additional, Hasegawa, Mark, additional, and Wong, Alfred J., additional

Published
2023
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6. Fungal Exposure to Meteorite Thin Sections: Developing an Experimental to Observe Biogeochemical Changes

Author

Barbre, K. S. R, Davis, R. E, and Regberg, A. B

Subjects
Space Sciences (General)
Abstract

The Astromaterials Acquisition & Curation Office maintains collections of meteorite samples collected as part of the Antarctic Search for Meteorites (ANSMET) program. The chief goal of the curation department is to maintain these meteorites in pristine condition. The Astromaterials Research and Exploration Science (ARES) Directorate has implemented a microbial monitoring program for the meteorite collections that has resulted in the isolation of >100 fungal isolates [1], however it is currently unknown if these isolates could present danger to the collections through bioweathering or secretion of organic compounds. We grew a strain of Fusarium oxysporium isolated from nitrogen gas filters feeding the Meteorite Lab nitrogen gas in the presence of a H5 meteorite thin section to determine if this fungus has the capability of altering the mineral structure of this common meteorite. This first trial was to determine and understand the effects of Fusarium oxysporum growth on the iron content within H5 chondrites and evaluate what additional components are needed in the development of future trial runs. This experiment determined new considerations for handling samples, the nature of microscopic scans before and after the incubation period, and the quality of the samples utilized for the experiment. The results of this experiment were promising and warrant further investigation with a more refined process and timeline.

Published
2020

7. Subsampling of the Hamburg Meteorite: A Study in Cold Curation Techniques

Author

Mitchell, J. L, Fries, M. D, Herd, C. D. K, Harrington, A. D, Regberg, A. B, McCubbin, F. M, Hill, P. J. A, and Tunney, L. D

Subjects
Space Sciences (General)
Abstract

The Hamburg meteorite is an H4 chondrite which was collected from the surface of a frozen lake in Michigan shortly after its observed fall on 16 Jan 2018 [1]. During and after collection, the meteorite was stored under clean, cold conditions, thereby minimizing any alteration to the sample. The meteorite was transported to the Johnson Space Center (JSC) where it was stored in a freezer until it was subsampled at the University of Alberta’s Sub-zero Facility for the Curation of Astromaterials (Fig. 1) [2]. Subsampling divided the meteorite into predefined target masses for preliminary examination and display purposes. This abstract summarizes the transport and subsampling process, which occurred in October 2019.

Published
2020

8. Advanced Curation of Astromaterials for Planetary Science

Author

McCubbin, Francis M., Herd, Christopher D. K., Yada, Toru, Hutzler, Aurore, Calaway, Michael J., Allton, Judith H., Corrigan, Cari M., Fries, Marc D., Harrington, Andrea D., McCoy, Timothy J., Mitchell, Julie L., Regberg, Aaron B., Righter, Kevin, Snead, Christopher J., Tait, Kimberly T., Zolensky, Michael E., and Zeigler, Ryan A.

Published
2019
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9. 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

10. Microbial Monitoring of Astromaterials Curation Labs Reveals Inter-Lab Diversity

Author

Regberg, A. B, Burton, A. S, Castro, C. L, Davis, R. E, McCubbin, F. M, and Wallace, S. L

Subjects
Space Sciences (General)
Abstract

The Astromaterials Curation Division at NASA’s Johnson Space Center houses seven sample collections stored in separate clean rooms to avoid cross-contamination. Prior to receiving new sample collections from carbon rich asteroids, we instituted a monitoring program to characterize the microbial ecology of these labs and to understand how organisms could interact with and potentially contaminate current and future collections. Methods: Beginning in Oct. 2017 we sampled the Meteorite (ISO 7 equivalent) and Pristine Lunar (ISO 5 equivalent) labs on a monthly basis. Surface samples were collected using dry swabs. Air samples were collected using an impactor style air sampler. Cultivable organisms were identified and characterized. Aliquots of each sample were also preserved for DNA sequencing. For each sampling event recovery rate was calculated as the percentage of samples showing microbial growth1. Fungal colonies were selected for amino acid extraction and analysis via Ultra- Performance Liquid Chromatography with Fluorescence Detection and Mass Spectrometry.

Published
2019

11. Isolation and Monitoring of Cleanroom-Associated Microbial Contaminates From Geological Collections

Author

Davis, Richard E, Castro, C. L, Castro-Wallace, S. L, McCubbin, Francis M, and Regberg, Aaron B

Subjects
Lunar And Planetary Science And Exploration
Abstract

Microbial contamination is of particular interest to geological curation as many microorganisms can change mineral composition and produce compounds used as biosignatures used for the detection of life. Microbial cells can change the mineral composition of rocks through organic acid production and direct enzymatic oxidation/reduction of transition metals. Enzymatic oxidation of iron and manganese can occur at a rate several orders of magnitude faster than under abiotic conditions and produce highly reactive nanoparticle- sized oxides that can react and sorb other metals and organic compounds. Many fungi can also produce organic acids that dissolve and chelate mineral matrices chemically reducing and dissolving rock surfaces. Finally, several common soil-associated bacteria and fungi produce secondary metabolites that contain unusual amino acid analogs and non-ribosomal peptides containing both L- and D- chirality used in characterizing carbonaceous chondrites and the detection of extraterrestrial life.

Published
2019

12. Field Camp for Astronauts: NASA's Geoscience Training Program for Planetary Exploration

Author

Evans, Cynthia A, Bleacher, Jacob E, Graff, Trevor G, Young, Kelsey E, Helper, Mark, Tewksbury, Barb, Hurtado, Jose, Edgar, Lauren, Regberg, Aaron B, Stefanov, William, Osinski, Gordon, Thompson, Ren, Ziegler, Ryan, Wilkinson, Justin, Bauer, Paul, and Timmons, Mike

Subjects
Lunar And Planetary Science And Exploration
Abstract

Fifty years ago Apollo astronauts walked on the Moon to explore the geology and collect samples for Earth return. Several authors have discussed the strategic planning and training that enabled the Apollo successes, and assembled recommendations regarding today’s lunar science objectives and astronaut training required to achieve those science goals. Since the 1980s, geoscience training for astronauts focused on observing the Earth from orbit. Today, we are building a geoscience training program to support informed Earth observations as well as the exploration culture for future human missions to the Moon and Mars. Our team partnered with JSC’s crew training and astronaut offices to develop our 4-week geoscience program for the 2017 astronaut class. Because the astronauts have a variety of professional backgrounds, we provide a broad introduction to Earth and planetary sciences. But our prime focus is 2 weeks of intensive field work, a methodology introduced with the 2013 astronaut class. We completed the first half of the training – a field trip to observe hurricane deposits along Galveston Bay; keynotes by Apollo colleagues highlighting Apollo experiences; a tightly-integrated week of introductory geology in the classroom followed by a week of fieldwork in the Rio Grande del Norte National Monument. The classroom included interactive map exercises that allowed the students to progressively build a base map of the field area that they used as a starting point for their week-long mapping exercise. We divided the class into small mapping groups to conduct their observations, mapping and interpretation of the geology. In addition to learning geological field work, our field training provided the platform for practicing expeditionary leadership, a key skill set valued by NASA for astronaut crews. Next summer the capstone fieldwork for the 2017 astronauts will include both mapping and rock sampling. Throughout the mapping, the class will collect additional data to help inform field and sampling decisions using diagnostic field instruments that are being tested in analog settings for their operational efficacy for future planetary exploration.

Published
2018

13. Integrated Data Visualization for Human Missions

Author

Regberg, Aaron B

Subjects
Documentation And Information Science, Lunar And Planetary Science And Exploration
Abstract

Interplanetary missions produce exceptionally large and complex volumes of data that can be extremely difficult to navigate. This is especially true for human missions. This project seeks to develop an integrated data visualization environment that builds on the success of Apollo17.org allowing for integration of operational, engineering and scientific data while also preserving the context under which it was collected during the mission. We will build a product that integrates existing data from the Neutral Buoyancy Lab (NBL) to improve data visualization for extra vehicular activity and interplanetary missions.

Published
2018

14. Organic Biomarker-Based Assays to Evaluate Total Bioburden and Organic Compounds on Space Flight Hardware

Author

Locke, Darren R, Burton, Aaron S, Regberg, Aaron B, Harrington, Andrea D, and Mitchell, Julie L

Subjects
Exobiology
Abstract

Meeting planetary protection (PP) requirements for space flight hardware may involve bioburden reduction by dry heat microbial reduction (DHMR). The NASA standard assay to demonstrate the reduction of organisms involves the swabbing of surfaces, heat shock of the extracted samples, plating of the samples on Trypticase Soy Agar (TSA), and counting colony forming units after an incubation period. The standard assay uses enumeration of heat tolerant spore-formers as a proxy for total bioburden and is generally expected to provide a lower limit. We suggest that a better estimate of the total bioburden could be obtained through sampling and analysis of organic biomarkers. As biological organisms are fundamentally organic in chemistry (i.e. carbon containing materials) it is important to characterize the biomarker compounds that are released from organisms that 1) exist on flight hardware before microbial reduction and 2) left behind from the killed organisms following microbial reduction.

Published
2018

15. The Importance of Contamination Knowledge - Insights into Mars Sample Return

Author

Harrington, A. D, Calaway, M. J, Regberg, A. B, Mitchell, J. L, Fries, M. D, Zeigler, R. A, and McCubbin, F. M

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Astromaterials Acquisition and Curation Office at NASA Johnson Space Center (JSC), in Houston, TX (henceforth Curation Office) manages the curation of all past, present, and future extraterrestrial samples returned by NASA missions and shared collections from international partners, preserving their integrity for future scientific study while providing the samples to the international community in a fair and unbiased way. The Curation Office also curates all reference and witness materials for each mission (e.g., flight and non-flight hardware coupons; lubricants; non-flight, flight-like, and flown witness plates). These reference and witness materials provide the scientific community with the fundamental ability to reconstruct the contamination/alteration history of the sample collection through the course of the mission, with the overall goal of strengthening the scientific conclusions drawn from the study of returned materials. The information gained from characterizing the physical, biological, inorganic, and organic chemical properties of reference and witness materials is defined as the Contamination Knowledge (CK) of the sample collection. Unlike the data collected for Contamination Control (CC) and Planetary Protection (PP), CK is exclusively concerned with preserving reference and witness materials for study by future scientists upon sample return. Although CC and PP data collected for sample integrity and forward contamination purposes can be complementary to CK, they are two separate data sets with distinct objectives. A robust collection of samples for CK is necessary to allow the extraterrestrial material in a returned sample to be distinguished from terrestrial contamination. Traditionally CK is utilized by sample scientists in order to accomplish the mission’s scientific objectives, however this information can also be utilized by the Office of Planetary Protection to help evaluate the presence of any back contamination. Mars 2020, the first phase of a potential multipart Mars Sample Return (MSR) campaign, is expected to contribute to NASA’s Mars Exploration Program Science Goals by filling in knowledge gaps concerning: 1) the existence of past or present life on Mars, 2) the past and present climate of Mars, 3) the geology of Mars, and 4) hazards associated with human exploration of Mars. Although there is debate concerning which samples will best answer these questions, the necessity for proper sample blanks is well-understood. The CC and PP requirements, driven by the restricted Class V mission designation, are the most stringent of any sample return mission in recent history. The extremely low levels of allowable terrestrial contamination on the spacecraft and rover can complicate these analyses given the detection limits of current analytical instrumentation, especially in the case of biological contamination. By collecting and curating unanalyzed samples specifically for CK, future sample scientists will not be relegated to: 1) relying on data collected using possibly obsolete tools and techniques for return sample blanks, or 2) using remnants of extracted and/or cultured samples from ATLO (Assembly, Test, and Launch Operations), which could be incompatible with the desired experimental endpoints or state-of-the-art techniques available at the time of sample return.The addition of biological experimental endpoints to a sample return campaign’s objectives broadens the requisite range in preservation environments (e.g. inert ultra-pure nitrogen gaseous environment at 18 degrees Centigrade versus less than or equal to minus 80 degrees Centigrade) and types of CK samples. As a result, the Curation Office will also curate the following CK samples at less than or equal to minus 80 degrees Centigrade for the Mars 2020 mission: 1) unanalyzed swabs and wipes in sterile containers, 2) all recirculation filters from the clean rooms used for sample and caching subsystem assembly and all filters from the laminar flow benches used to assemble sample intimate hardware, and 3) witness plates collecting airborne contamination within the assembly clean rooms. It has been Curation Office policy since the Apollo missions to preserve as many pristine samples as possible for future scientific research. Although CK is required to be collected for all stages of the MSR campaign, the CK for the Mars 2020 mission is the most critical for understanding contamination in the returned samples given the intimacy between the Martian samples and the Mars 2020 flight hardware. This presentation highlights the importance of CK for sample return missions as well as the traditional and novel types of CK samples required for a successful MSR campaign.

Published
2018

16. A Prototype Tool for Assessing Forward Contamination from Space Suits

Author

Rucker, M, Bell, M. S, Castro, C. L, Hood, A, Mohan, G.B. Malli, Mason, C, Regberg, A. B, Stahl, S. E, Venkateswaran, K, Wallace, S. L, and Walker, M

Subjects
Man/System Technology And Life Support
Abstract

Crewed exploration missions dramatically increase the capability for large-scale sample collection and return activities, but they also increase the possibility and likelihood of forward contamination. Systematic research on forward contamination from uncrewed spacecraft has steadily progressed since the Viking missions, but parallel research on contamination from space suits has not. Current space suits have leakage rates as high as 100 cc gas/min., but it is unclear how many or what types of microbes are exiting the suits along with this gas. The Human Forward Contamination Assessment team at NASA's Johnson Space Center (JSC) has developed a prototype swab tool that is capable of maintaining sterility during pressure changes associated with entering and exiting vacuum. The primary objective of recent Extravehicular Activity (EVA) Swab Kit testing is to characterize the type of microorganisms typically found on spacesuit external surfaces under suit differential pressure conditions. Most human-associated microorganisms can fit through a 0.5 to 1.0 μm gap. Understanding potential leak paths will inform future hardware design decisions. Knowing which types of microorganisms may leak from EVA suits provides a basis for subsequent studies to characterize the viability of those organisms under destination conditions, as well as how far they might spread through natural or human-influenced processes. The results of EVA suit molecular microbial community analyses will inform NASA exploration mission operations and hardware design, and help close Strategic Knowledge Gap B5, Forward Contamination to Mars.

Published
2018

17. Mobile/Modular BSL-4 Containment Facilities Integrated into a Curation Receiving Laboratory for Restricted Earth Return Missions

Author

Calaway, Michael J, Mccubbin, Francis M, Harrington, Andrea D, Regberg, Aaron B, Allton, Judith H, and Zeigler, Ryan A

Subjects
Lunar And Planetary Science And Exploration, Economics And Cost Analysis
Abstract

NASA robotic sample return missions designated Category V Restricted Earth Return by the NASA Planetary Protection (PP) Office require sample containment and biohazard testing upon return to Earth. Since the 1960s, sample containment from an unknown extraterrestrial biohazard have been related to the highest containment standards and protocols known to modern science. Today, this is Biosafety Level (BSL) 4 containment. In the U.S., the Biosafety in Microbiological and Biomedical Laboratories publication authored by the U.S. Department of Health and Human Services (HHS): Public Health Service, Centers for Disease Control and Prevention, and the National Institutes of Health houses the primary recommendations, standards, and design requirements for all BSL labs. Past mission concept studies for constructing a NASA Curation Receiving Laboratory with an integrated BSL-4 quarantine and biohazard testing facility have been estimated in the hundreds of millions of dollars (USD). As an alternative option, we have conducted a trade study for constructing a mobile and/or modular sample containment laboratory that would meet all BSL-4 and planetary protection standards and protocols at a fraction of the cost. Mobile and modular BSL-2 and 3 facilities have been successfully constructed and deployed world-wide for government testing of pathogens and pharmaceutical production. Our study showed that a modular BSL-4 construction could result in ~ 90% cost reduction when compared to traditional BSL-4 construction methods without compromising the preservation of the samples or Earth. For the design/construction requirements of a mobile/modular BSL-4 containment, we used the established HHS document standards and protocols for manipulation of agents in Class III Biosafety Cabinets (BSC; i.e., negative pressure gloveboxes) that are currently followed in operational BSL-4 facilities in the U.S.

Published
2018

18. Curating Nasa's Future Extraterrestrial Sample Collections: the Role of Advanced Curation

Author

McCubbin, Francis M, Evans, Cindy A, Fries, Marc D, Harrington, Andrea D, Locke, Darren R, Mitchell, Julie L, Regberg, Aaron B, Zeigler, Ryan A, and Stansbery, Eileen K

Subjects
Administration And Management
Abstract

The Astromaterials Acquisition and Curation Office at NASA Johnson Space Center (JSC) (henceforth referred to herein as NASA Curation Office) is responsible for curating all of NASA's extraterrestrial samples. Under the governing document, NASA Policy Directive (NPD) 7100.10F "Curation of Extraterrestrial Materials," JSC is charged with "The curation of all extraterrestrial material under NASA control, including future NASA missions." The Directive goes on to define Curation as including "...documentation, preservation, preparation, and distribution of samples for re-search, education, and public outreach." Here we describe some of the ongoing efforts to ensure that the future activities of the NASA Curation Office are working towards a state of maximum proficiency.

Published
2018

19. Microbial Ecology of NASA Curation Clean Rooms

Author

Regberg, A. B, Burton, A. S, Castro, C. L, Stahl, S. E, Wallace, S. L, and McCubbin, F. M

Subjects
Space Sciences (General)
Abstract

Clean room standards like ISO 14644 used for facilities that construct spacecraft and store returned samples do not explicitly account for microbial contamination. While there are associated ISO standards for monitoring and controlling bio-contamination in clean rooms it is not always standard practice to do so. The NASA Astromaterials Acquisition and Curation Office maintains seven separate clean labs for storing extraterrestrial samples from the Moon, meteorites, cosmic dust, asteroids, comets, solar wind particles, and microparticle impact samples. These labs are routinely monitored for particulate and trace metal contamination. However, the sample collections are either non-sterile at the time of collection (e.g., meteorites) or are no longer being used to address scientific questions that could be affected by non-sterile conditions (e.g., Lunar samples). Outside of isolated studies there has not been a systematic, longitudinal characterization of the microbial ecology of NASA curation clean rooms. In accordance with the advanced curation initiative, and to prepare for future sample return missions, we have initiated a routine microbiological monitoring program in the Antarctic Meteorite Lab. This monitoring program will be used to determine what microbes are capable of surviving in these oligotrophic environments and whether or not they are capable of altering the sample collections in any significant manner. Repeat sampling will allow us to understand how routine use of these labs affects the microbial ecology over time.

Published
2018

20. Perserving Samples and Their Scientific Integrity - Insights into MSR from the Astromaterials Acquisition and Curation Office at NASA Johnson Space Center

Author

Harrington, A. D, Calaway, M. J, Regberg, A. B, Mitchell, J. L, Fries, M. D, Zeigler, R. A, and McCubbin, F. M

Subjects
Documentation And Information Science, Space Sciences (General)
Abstract

The Astromaterials Acquisition and Curation Office at NASA Johnson Space Center (JSC), in Houston, TX (henceforth Curation Office) manages the curation of all past, present, and future extraterrestrial samples returned by NASA missions and shared collections from international partners, preserving their integrity for future scientific study while providing the samples to the international community in a fair and unbiased way. The Curation Office also curates flight and non-flight reference materials and other materials from spacecraft assembly of sample return missions that would have the potential to cross-contaminate a present or future NASA astromaterials collection. These materials are primarily collected during the assembly, test, and launch operations (ATLO) phase and after flight during the recovery and curation phase. In addition, the Curation Office curates non-flight, flight-like, and flown witness plates for sample return missions. These reference materials and witness plates provide the scientific community with the fundamental ability to reconstruct the contamination/alteration history of the sample collection through the course of the mission, with the overall goal of strengthening the scientific conclusions drawn from the study of returned materials.

Published
2018

21. The Importance of Contamination Knowledge in Curation - Insights into Mars Sample Return

Author

Harrington, A. D, Calaway, M. J, Regberg, A. B, Mitchell, J. L, Fries, M. D, Zeigler, R. A, and McCubbin, F. M

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Astromaterials Acquisition and Curation Office at NASA Johnson Space Center (JSC), in Houston, TX (henceforth Curation Office) manages the curation of extraterrestrial samples returned by NASA missions and shared collections from international partners, preserving their integrity for future scientific study while providing the samples to the international community in a fair and unbiased way. The Curation Office also curates flight and non-flight reference materials and other materials from spacecraft assembly (e.g., lubricants, paints and gases) of sample return missions that would have the potential to cross-contaminate a present or future NASA astromaterials collection.

Published
2018

22. Planning Implications Related to Sterilization-Sensitive Science Investigations Associated with Mars Sample Return (MSR)

Author

Velbel, Michael A., primary, Cockell, Charles S., additional, Glavin, Daniel P., additional, Marty, Bernard, additional, Regberg, Aaron B., additional, Smith, Alvin L., additional, Tosca, Nicholas J., additional, Wadhwa, Meenakshi, additional, Kminek, Gerhard, additional, Meyer, Michael A., additional, Beaty, David W., additional, Carrier, Brandi Lee, additional, Haltigin, Timothy, additional, Hays, Lindsay E., additional, Agee, Carl B., additional, Busemann, Henner, additional, Cavalazzi, Barbara, additional, Debaille, Vinciane, additional, Grady, Monica M., additional, Hauber, Ernst, additional, Hutzler, Aurore, additional, McCubbin, Francis M., additional, Pratt, Lisa M., additional, Smith, Caroline L., additional, Summons, Roger E., additional, Swindle, Timothy D., additional, Tait, Kimberly T., additional, Udry, Arya, additional, Usui, Tomohiro, additional, Westall, Frances, additional, and Zorzano, Maria-Paz, additional

Published
2022
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23. Preliminary Planning for Mars Sample Return (MSR) Curation Activities in a Sample Receiving Facility (SRF)

Author

Tait, Kimberly T., primary, McCubbin, Francis M., additional, Smith, Caroline L., additional, Agee, Carl B., additional, Busemann, Henner, additional, Cavalazzi, Barbara, additional, Debaille, Vinciane, additional, Hutzler, Aurore, additional, Usui, Tomohiro, additional, Kminek, Gerhard, additional, Meyer, Michael A., additional, Beaty, David W., additional, Carrier, Brandi L., additional, Haltigin, Timothy, additional, Hays, Lindsay E., additional, Cockell, Charles S., additional, Glavin, Daniel P., additional, Grady, Monica M., additional, Hauber, Ernst, additional, Marty, Bernard, additional, Pratt, Lisa M., additional, Regberg, Aaron B., additional, Smith, Alvin L., additional, Summons, Roger E., additional, Swindle, Timothy D., additional, Tosca, Nicholas J., additional, Udry, Arya, additional, Velbel, Michael A., additional, Wadhwa, Meenakshi, additional, Westall, Frances, additional, and Zorzano, Maria-Paz, additional

Published
2022
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24. The Scientific Importance of Returning Airfall Dust as a Part of Mars Sample Return (MSR)

Author

Grady, Monica M., primary, Summons, Roger E., additional, Swindle, Timothy D., additional, Westall, Frances, additional, Kminek, Gerhard, additional, Meyer, Michael A., additional, Beaty, David W., additional, Carrier, Brandi L., additional, Haltigin, Timothy, additional, Hays, Lindsay E., additional, Agee, Carl B., additional, Busemann, Henner, additional, Cavalazzi, Barbara, additional, Cockell, Charles S., additional, Debaille, Vinciane, additional, Glavin, Daniel P., additional, Hauber, Ernst, additional, Hutzler, Aurore, additional, Marty, Bernard, additional, McCubbin, Francis M., additional, Pratt, Lisa M., additional, Regberg, Aaron B., additional, Smith, Alvin L., additional, Smith, Caroline L., additional, Tait, Kimberly T., additional, Tosca, Nicholas J., additional, Udry, Arya, additional, Usui, Tomohiro, additional, Velbel, Michael A., additional, Wadhwa, Meenakshi, additional, and Zorzano, Maria-Paz, additional

Published
2022
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25. Rationale and Proposed Design for a Mars Sample Return (MSR) Science Program

Author

Haltigin, Timothy, primary, Hauber, Ernst, additional, Kminek, Gerhard, additional, Meyer, Michael A., additional, Agee, Carl B., additional, Busemann, Henner, additional, Carrier, Brandi L., additional, Glavin, Daniel P., additional, Hays, Lindsay E., additional, Marty, Bernard, additional, Pratt, Lisa M., additional, Udry, Arya, additional, Zorzano, Maria-Paz, additional, Beaty, David W., additional, Cavalazzi, Barbara, additional, Cockell, Charles S., additional, Debaille, Vinciane, additional, Grady, Monica M., additional, Hutzler, Aurore, additional, McCubbin, Francis M., additional, Regberg, Aaron B., additional, Smith, Alvin L., additional, Smith, Caroline L., additional, Summons, Roger E., additional, Swindle, Timothy D., additional, Tait, Kimberly T., additional, Tosca, Nicholas J., additional, Usui, Tomohiro, additional, Velbel, Michael A., additional, Wadhwa, Meenakshi, additional, and Westall, Frances, additional

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

Author

Carrier, Brandi L., primary, Beaty, David W., additional, Hutzler, Aurore, additional, Smith, Alvin L., additional, Kminek, Gerhard, additional, Meyer, Michael A., additional, Haltigin, Timothy, additional, Hays, Lindsay E., additional, Agee, Carl B., additional, Busemann, Henner, additional, Cavalazzi, Barbara, additional, Cockell, Charles S., additional, Debaille, Vinciane, additional, Glavin, Daniel P., additional, Grady, Monica M., additional, Hauber, Ernst, additional, Marty, Bernard, additional, McCubbin, Francis M., additional, Pratt, Lisa M., additional, Regberg, Aaron B., additional, Smith, Caroline L., additional, Summons, Roger E., additional, Swindle, Timothy D., additional, Tait, Kimberly T., additional, Tosca, Nicholas J., additional, Udry, Arya, additional, Usui, Tomohiro, additional, Velbel, Michael A., additional, Wadhwa, Meenakshi, additional, Westall, Frances, additional, and Zorzano, Maria-Paz, additional

Published
2022
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27. Final Report of the Mars Sample Return Science Planning Group 2 (MSPG2)

Author

Meyer, Michael A., primary, Kminek, Gerhard, additional, Beaty, David W., additional, Carrier, Brandi L., additional, Haltigin, Timothy, additional, Hays, Lindsay E., additional, Agree, Carl B., additional, Busemann, Henner, additional, Cavalazzi, Barbara, additional, Cockell, Charles S., additional, Debaille, Vinciane, additional, Glavin, Daniel P., additional, Grady, Monica M., additional, Hauber, Ernst, additional, Hutzler, Aurore, additional, Marty, Bernard, additional, McCubbin, Francis M., additional, Pratt, Lisa M., additional, Regberg, Aaron B., additional, Smith, Alvin L., additional, Smith, Caroline L., additional, Summons, Roger E., additional, Swindle, Timothy D., additional, Tait, Kimberly T., additional, Tosca, Nicholas J., additional, Udry, Arya, additional, Usui, Tomohiro, additional, Velbel, Michael A., additional, Wadhwa, Meenakshi, additional, Westall, Frances, additional, and Zorzano, Maria-Paz, additional

Published
2022
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28. Advanced Curation Activities at NASA: Preparation for Upcoming Missions

Author

Fries, M. D, Evans, C. A, Mccubbin, F. M, Harrington, A. D, Regberg, A. B, Snead, C. J, and Zeigler, R. A

Subjects
Lunar And Planetary Science And Exploration, Documentation And Information Science
Abstract

The responsibility for curating NASA's astromaterials collections falls to the NASA Curation Office at Johnson Space Center. Under the governing document, NASA Policy Directive (NPD) 7100.10F and derivative requirements documents, JSC is charged with curation of all extraterrestrial material under NASA control, including future NASA missions to include material returned in Mars Sample Return (MSR) efforts, OSIRIS-REx, NASA's subset of Hayabusa-2 samples, and any other sample return missions. The Directive defines Curation as activities including documentation, preservation, sample preparation, distribution, and tracking of samples for research, education, and public outreach. In this abstract we will describe Curation's research and development efforts to improve the care of existing collections and prepare for future NASA sample return missions. These efforts are collectively referred to as Advanced Curation, a term first coined in 2002.

Published
2017

29. Advanced Curation Activities at NASA: Implications for Astrobiological Studies of Future Sample Collections

Author

McCubbin, F. M, Evans, C. A, Fries, M. D, Harrington, A. D, Regberg, A. B, Snead, C. J, and Zeigler, R. A

Subjects
Lunar And Planetary Science And Exploration, Documentation And Information Science, Exobiology
Abstract

The Astromaterials Acquisition and Curation Office (henceforth referred to herein as NASA Curation Office) at NASA Johnson Space Center (JSC) is responsible for curating all of NASA's extraterrestrial samples. Under the governing document, NASA Policy Directive (NPD) 7100.10F JSC is charged with curation of all extraterrestrial material under NASA control, including future NASA missions. The Directive goes on to define Curation as including documentation, preservation, preparation, and distribution of samples for re-search, education, and public outreach. Here we briefly describe NASA's astromaterials collections and our ongoing efforts related to enhancing the utility of our current collections as well as our efforts to prepare for future sample return missions. We collectively refer to these efforts as advanced curation.

Published
2017

30. Advanced Curation Preparation for Mars Sample Return and Cold Curation

Author

Fries, M. D, Harrington, A. D, McCubbin, F. M, Mitchell, J, Regberg, A. B, and Snead, C

Subjects
Documentation And Information Science, Lunar And Planetary Science And Exploration
Abstract

NASA Curation is tasked with the care and distribution of NASA's sample collections, such as the Apollo lunar samples and cometary material collected by the Stardust spacecraft. Curation is also mandated to perform Advanced Curation research and development, which includes improving the curation of existing collections as well as preparing for future sample return missions. Advanced Curation has identified a suite of technologies and techniques that will require attention ahead of Mars sample return (MSR) and missions with cold curation (CCur) requirements, perhaps including comet sample return missions.

Published
2017

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

Author

Tosca, Nicholas J., Agee, Carl B., Cockell, Charles S., Glavin, Daniel P., Hutzler, Aurore, Marty, Bernard, McCubbin, Francis M., Regberg, Aaron B., Velbel, Michael A., Kminek, Gerhard, Meyer, Michael A., Beaty, David W., Carrier, Brandi L., Haltigin, Timothy, Hays, Lindsay E., Busemann, Henner, Cavalazzi, Barbara, Debaille, Vinciane, Grady, Monica M., Hauber, Ernst, and Pratt, Lisa M.

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., Astrobiology, 22 (S1), ISSN:1531-1074, ISSN:1557-8070

Published
2022
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32. Time-Sensitive Aspects of Mars Sample Return (MSR) Science

Author

Tosca, Nicholas J., primary, Agee, Carl B., additional, Cockell, Charles S., additional, Glavin, Daniel P., additional, Hutzler, Aurore, additional, Marty, Bernard, additional, McCubbin, Francis M., additional, Regberg, Aaron B., additional, Velbel, Michael A., additional, Kminek, Gerhard, additional, Meyer, Michael A, additional, Beaty, David W, additional, Carrier, Brandi Lee, additional, Haltigin, Timothy, additional, Hays, Lindsay E, additional, Busemann, Henner, additional, Cavalazzi, Barbara, additional, Debaille, Vinciane, additional, Grady, Monica M., additional, Hauber, Ernst, additional, Pratt, Lisa M, additional, Smith, Alvin L, additional, Smith, Caroline L, additional, Summons, Roger E., additional, Swindle, Timothy D, additional, Tait, Kimberly T, additional, Udry, Arya, additional, Usui, Tomohiro, additional, Wadhwa, Meenakshi, additional, Westall, Frances, additional, and Zorzano, Maria-Paz, additional

Published
2021
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33. Characterization of Spacesuit Associated Microbial Communities and Their Implications for NASA Missions

Author

Danko, David, primary, Malli Mohan, Ganesh Babu, additional, Sierra, Maria A., additional, Rucker, Michelle, additional, Singh, Nitin K., additional, Regberg, Aaron B., additional, Bell, Mary S., additional, O’Hara, Niamh B., additional, Ounit, Rachid, additional, Mason, Christopher E., additional, and Venkateswaran, Kasthuri, additional

Published
2021
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34. Advanced Curation of Astromaterials for Planetary Science Over the Next Decade

Author

McCubbin, Francis, primary, Allton, Judith H., additional, Barnes, Jessica J., additional, Calaway, Michael J., additional, Corrigan, Catherine M., additional, Filiberto, Justin, additional, Fries, Marc D., additional, Gross, Juliane, additional, Harrington, Andrea D., additional, Herd, Christopher D. K., additional, Hutzler, Aurore, additional, Ishii, Hope A., additional, McCoy, Timothy J., additional, McKeegan, Kevin, additional, Mitchell, Julie L., additional, Nittler, Larry R., additional, Regberg, Aaron B., additional, Righter, Kevin, additional, Snead, Christopher J., additional, Stroud, Rhonda, additional, Tait, Kimberly T., additional, Yada, Toru, additional, Zeigler, Ryan A., additional, Zolensky, Michael E., additional, and Stansbery, Eileen K., additional

Published
2021
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35. Prokaryotic and Fungal Characterization of the Facilities Used to Assemble, Test, and Launch the OSIRIS-REx Spacecraft

Author

Regberg, Aaron B., primary, Castro, Christian L., additional, Connolly, Harold C., additional, Davis, Richard E., additional, Dworkin, Jason P., additional, Lauretta, Dante S., additional, Messenger, Scott R., additional, Mclain, Hannah L., additional, McCubbin, Francis M., additional, Moore, Jamie L., additional, Righter, Kevin, additional, Stahl-Rommel, Sarah, additional, and Castro-Wallace, Sarah L., additional

Published
2020
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38. RECOVERY AND CONTAMINATION MITIGATION OF METEORITES: IMPLICATIONS FOR ADVANCED CURATION METHODS.

Author

Tunney, L. D., Hill, P. J. A., Herd, C. D. K., Hilts, R. W., and Regberg, A. B.

Subjects
METEORITES, TRICLOCARBAN, DNA, SURFACE of the earth, VOLATILE organic compounds, ORIGIN of life
Abstract

Introduction: The intrinsic properties of meteorites can provide valuable information about the solar system and potentially the origin of life [1]. However, these intrinsic characteristics are at risk of biological or geologic alteration or destruction once a meteorite falls to the surface of the Earth [2]. Due to the potential for rapid contamination of meteoritic material, distinguishing possible contaminants from intrinsic properties becomes critical. Here, we summarize the best practices for preserving meteorites in their most pristine states possible, based on recent studies of freshly fallen meteorites, and laboratory materials and components. Methods: Work used to infer best practices can be found in publications [3-6]. These studies included eighteen Buzzard Coulee specimens [3], five Aguas Zarcas samples [4], two Tarda specimens and a sand sample from the Tarda strewn field [5], three Bruderheim samples, three Peace River samples, and one Redwater sample. Organic contamination was documented using GC-MS of dichloromethane and hot water extractions, whereas the biological contamination study used two different DNA extraction kits: PowerSoil and QIAamp. In addition, a study of the potential for detecting freshly fallen meteorites on a snow-covered field using drone-based thermal imagery was conducted [6]. Results: The soluble organic compound and microbial studies yield ten key contamination trends: (1) Colder temperatures hinder the accumulation of organic contaminants. (2) Soluble organic contamination is best detected immediately following collection [3]. (3) The properties of the meteorite itself may impact the degree of contamination; for example, the fusion crust appears to protect against the transfer of contamination to the interior; conversely, the abrasive texture of an exposed interior surface may aid in the transfer of contaminants. (4) The derivatizing agent chosen greatly impacts the types of organics detected [4,5]. (5) Inter-specimen heterogeneity is the primary control on the intrinsic compounds detectable [4,5]. (6) Terrestrial organic contaminants fall within one of four categories: agricultural products, fuels, pharmaceuticals, and polymers [3,4,5]. (7) Microbial communities that contaminate meteorites and laboratory surfaces are typically either sourced from soils or human contact. (8) Microbial communities detected on meteorites may produce or destroy organic compounds of interest. (9) A combination of thermal and visible imagery, up to 40 m altitude, can be used to aid in the rapid collection of meteorite falls on snow-covered terrain [6]. Conclusions: A standardized procedure is necessary to mitigate the rapid contamination that meteorites experience on the surface of the Earth. From our studies we have derived six key recommendations when recovering, handling, and curating meteorites, in particular, freshly fallen meteorites: (1) Meteorites should be collected as rapidly as possible to minimize the damage or contamination it may experience. This could include utilizing the a meteorite camera network and/or thermal imagery. (2) Characteristics of the strewn field and meteorite specimens should be carefully recorded. (3) Terrestrial samples from the strewn field and surrounding areas should be taken to characterize contamination sources. (4) Baseline contamination from materials and laboratory environments should be thoroughly documented prior to introducing meteorite specimens. (5) Records of how the meteorite specimens are handled after collection should be kept, including: processing, materials used, and the temperature of storage. Cold curation (-15 to -20 ?) is highly recommended for specimens that have the potential to contain volatile organic compounds. Acknowledgements: Funding was provided by the Canadian Space Agency FAST Grant 18FAALBB20 and NSERC Grant RGPIN-2018-04902 to CDKH. [ABSTRACT FROM AUTHOR]

Published
2022

40. FIELD STUDY OF AN EUROPA ANALOG ENVIRONMENT IN ICELAND.

Author

ANixon, C., Hewagama, T., MBower, D., CStern, J., Cousins, C. R., Eigenbrode, J. L., Regberg, A. B., and Wasser, M.

Subjects
SCIENTIFIC apparatus & instruments, FIELD research, DNA fingerprinting, BIOLOGICAL pigments, REFLECTANCE spectroscopy, PLANT pigments
Published
2019

42. Planetary Protection Knowledge Gap Closure Enabling Crewed Missions to Mars

Author

Spry, James A., Siegel, Bette, Bakermans, Corien, Beaty, David W., Bell, Mary-Sue, Benardini, James N., Bonaccorsi, Rosalba, Castro-Wallace, Sarah L., Coil, David A., Coustenis, Athena, Doran, Peter T., Fenton, Lori, Fidler, David P., Glass, Brian, Hoffman, Stephen J., Karouia, Fathi, Levine, Joel S., Lupisella, Mark L., Martin-Torres, Javier, Mogul, Rakesh, Olsson-Francis, Karen, Ortega-Ugalde, Sandra, Patel, Manish R., Pearce, David A., Race, Margaret S., Regberg, Aaron B., Rettberg, Petra, Rummel, John D., Sato, Kevin Y., Schuerger, Andrew C., Sefton-Nash, Elliot, Sharkey, Matthew, Singh, Nitin K., Sinibaldi, Silvio, Stabekis, Perry, Stoker, Carol R., Venkateswaran, Kasthuri J., Zimmerman, Robert R., Zorzano-Mier, Maria-Paz, Spry, James A., Siegel, Bette, Bakermans, Corien, Beaty, David W., Bell, Mary-Sue, Benardini, James N., Bonaccorsi, Rosalba, Castro-Wallace, Sarah L., Coil, David A., Coustenis, Athena, Doran, Peter T., Fenton, Lori, Fidler, David P., Glass, Brian, Hoffman, Stephen J., Karouia, Fathi, Levine, Joel S., Lupisella, Mark L., Martin-Torres, Javier, Mogul, Rakesh, Olsson-Francis, Karen, Ortega-Ugalde, Sandra, Patel, Manish R., Pearce, David A., Race, Margaret S., Regberg, Aaron B., Rettberg, Petra, Rummel, John D., Sato, Kevin Y., Schuerger, Andrew C., Sefton-Nash, Elliot, Sharkey, Matthew, Singh, Nitin K., Sinibaldi, Silvio, Stabekis, Perry, Stoker, Carol R., Venkateswaran, Kasthuri J., Zimmerman, Robert R., and Zorzano-Mier, Maria-Paz

Abstract

As focus for exploration of Mars transitions from current robotic explorers to development of crewed missions, it remains important to protect the integrity of scientific investigations at Mars, as well as protect the Earth's biosphere from any potential harmful effects from returned martian material. This is the discipline of planetary protection, and the Committee on Space Research (COSPAR) maintains the consensus international policy and guidelines on how this is implemented. Based on National Aeronautics and Space Administration (NASA) and European Space Agency (ESA) studies that began in 2001, COSPAR adopted principles and guidelines for human missions to Mars in 2008. At that point, it was clear that to move from those qualitative provisions, a great deal of work and interaction with spacecraft designers would be necessary to generate meaningful quantitative recommendations that could embody the intent of the Outer Space Treaty (Article IX) in the design of such missions. Beginning in 2016, COSPAR then sponsored a multiyear interdisciplinary meeting series to address planetary protection “knowledge gaps” (KGs) with the intent of adapting and extending the current robotic mission-focused Planetary Protection Policy to support the design and implementation of crewed and hybrid exploration missions. This article describes the outcome of the interdisciplinary COSPAR meeting series, to describe and address these KGs, as well as identify potential paths to gap closure. It includes the background scientific basis for each topic area and knowledge updates since the meeting series ended. In particular, credible solutions for KG closure are described for the three topic areas of (1) microbial monitoring of spacecraft and crew health; (2) natural transport (and survival) of terrestrial microbial contamination at Mars, and (3) the technology and operation of spacecraft systems for contamination control. The article includes a KG data table on these topic areas, which is i

43. Preliminary Planning for Mars Sample Return (MSR) Curation Activities in a Sample Receiving Facility

Author

Tait, Kimberly T, McCubbin, Francis M., Smith, Caroline L, Agee, Carl B., Busemann, Henner, Cavalazzi, Barbara, Debaille, Vinciane, Hutzler, Aurore, Usui, Tomohiro, Kminek, Gerhard, Meyer, Michael A, Beaty, David W, Carrier, Brandi Lee, Haltigin, Timothy, Hays, Lindsay E, Cockell, Charles S., Glavin, Daniel P., Grady, Monica M., Hauber, Ernst, Marty, Bernard, Pratt, Lisa M, Regberg, Aaron B., Smith, Alvin L, Summons, Roger E., Swindle, Timothy D, Tosca, Nicholas J., Udry, Arya, Velbel, Michael A., Wadhwa, Meenakshi, Westall, Frances, Zorzano, Maria-Paz, Tait, Kimberly T, McCubbin, Francis M., Smith, Caroline L, Agee, Carl B., Busemann, Henner, Cavalazzi, Barbara, Debaille, Vinciane, Hutzler, Aurore, Usui, Tomohiro, Kminek, Gerhard, Meyer, Michael A, Beaty, David W, Carrier, Brandi Lee, Haltigin, Timothy, Hays, Lindsay E, Cockell, Charles S., Glavin, Daniel P., Grady, Monica M., Hauber, Ernst, Marty, Bernard, Pratt, Lisa M, Regberg, Aaron B., Smith, Alvin L, Summons, Roger E., Swindle, Timothy D, Tosca, Nicholas J., Udry, Arya, Velbel, Michael A., Wadhwa, Meenakshi, Westall, Frances, and Zorzano, Maria-Paz

Abstract

The Mars Sample Return Planning Group 2 (MSPG2) was tasked with identifying the steps that encompass all the curation activities that would happen within the MSR Sample Receiving Facility (SRF) and any anticipated curation-related requirements. An area of specific interest is the necessary analytical instrumentation. The SRF would be a Biosafety Level-4 facility where the returned MSR flight hardware would be opened, the sample tubes accessed, and the martian sample material extracted from the tubes. Characterization of the essential attributes of each sample would be required to provide enough information to prepare a sample catalog used in guiding the preparation of sample-related proposals by the world’s research community and informing decisions by the sample allocation committee. The sample catalog would be populated with data and information generated during all phases of activity, including data derived concurrent with Mars 2020 sample-collecting rover activity, sample transport to Earth, and initial sample characterization within the SRF. We conclude that initial sample characterization can best be planned as a set of three sequential phases, which we have called Pre-Basic Characterization (Pre-BC), Basic Characterization (BC), and Preliminary Examination (PE), each of which requires a certain amount of instrumentation. Data on specific samples and subsamples obtained during sample safety assessments and time-sensitive scientific investigations would also be added to the catalog. There are several areas where future work would be beneficial to prepare for the receipt of samples, which would include the design of a sample tube isolation chamber and a strategy for opening the sample tubes and removing dust from the tube exteriors.

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

Author

Carrier, Brandi Lee, Beaty, David W, Hutzler, Aurore, Smith, Alvin L, Kminek, Gerhard, Meyer, Michael A, 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, Marty, Bernard, McCubbin, Francis M., Pratt, Lisa M, Regberg, Aaron B., 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, Carrier, Brandi Lee, Beaty, David W, Hutzler, Aurore, Smith, Alvin L, Kminek, Gerhard, Meyer, Michael A, 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, Marty, Bernard, McCubbin, Francis M., Pratt, Lisa M, Regberg, Aaron B., 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, and Zorzano, Maria-Paz

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.

45. 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, 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, and Zorzano, Maria-Paz

Abstract

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

46. The Scientific Importance of Returning Airfall Dust as a Part of Mars Sample Return (MSR)

Author

Grady, Monica M., Summons, Roger E., Swindle, Timothy D, Westall, Frances, Kminek, Gerhard, Meyer, Michael A, 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., Hauber, Ernst, Hutzler, Aurore, Marty, Bernard, McCubbin, Francis M., Pratt, Lisa M, Regberg, Aaron B., Smith, Alvin L, Smith, Caroline L, Tait, Kimberly T, Tosca, Nicholas J., Udry, Arya, Usui, Tomohiro, Velbel, Michael A., Wadhwa, Meenakshi, Zorzano, Maria-Paz, Grady, Monica M., Summons, Roger E., Swindle, Timothy D, Westall, Frances, Kminek, Gerhard, Meyer, Michael A, 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., Hauber, Ernst, Hutzler, Aurore, Marty, Bernard, McCubbin, Francis M., Pratt, Lisa M, Regberg, Aaron B., Smith, Alvin L, Smith, Caroline L, Tait, Kimberly T, Tosca, Nicholas J., Udry, Arya, Usui, Tomohiro, Velbel, Michael A., Wadhwa, Meenakshi, and Zorzano, Maria-Paz

Abstract

Dust transported in the martian atmosphere is of intrinsic scientific interest and has relevance for the planning of human missions in the future. The MSR Campaign, as currently designed, presents an important opportunity to return serendipitous, airfall dust. The tubes containing samples collected by the Perseverance rover would be placed in cache depots on the martian surface perhaps as early as 2023–24 for recovery by a subsequent mission no earlier than 2028–29, and possibly as late as 2030–31. Thus, the sample tube surfaces could passively collect dust for multiple years. This dust is deemed to be exceptionally valuable as it would inform our knowledge and understanding of Mars’ global mineralogy, surface processes, surface-atmosphere interactions, and atmospheric circulation. Preliminary calculations suggest that the total mass of such dust on a full set of tubes could be as much as 100 mg and, therefore, sufficient for many types of laboratory analyses. Two planning steps would optimize our ability to take advantage of this opportunity: (1) the dust-covered sample tubes should be loaded into the Orbiting Sample container (OS) with minimal cleaning and (2) the capability to recover this dust early in the workflow within an MSR Sample Receiving Facility (SRF) would need to be established. A further opportunity to advance dust/atmospheric science using MSR, depending upon the design of the MSR Campaign elements, may lie with direct sampling and the return of airborne dust.

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

Author

Tosca, Nicholas J., Agee, Carl B., Cockell, Charles S., Glavin, Daniel P., Hutzler, Aurore, Marty, Bernard, McCubbin, Francis M., Regberg, Aaron B., Velbel, Michael A., Kminek, Gerhard, Meyer, Michael A, Beaty, David W, Carrier, Brandi Lee, Haltigin, Timothy, Hays, Lindsay E, Busemann, Henner, Cavalazzi, Barbara, Debaille, Vinciane, Grady, Monica M., Hauber, Ernst, Pratt, Lisa M, Smith, Alvin L, Smith, Caroline L, Summons, Roger E., Swindle, Timothy D, Tait, Kimberly T, Udry, Arya, Usui, Tomohiro, Wadhwa, Meenakshi, Westall, Frances, Zorzano, Maria-Paz, Tosca, Nicholas J., Agee, Carl B., Cockell, Charles S., Glavin, Daniel P., Hutzler, Aurore, Marty, Bernard, McCubbin, Francis M., Regberg, Aaron B., Velbel, Michael A., Kminek, Gerhard, Meyer, Michael A, Beaty, David W, Carrier, Brandi Lee, Haltigin, Timothy, Hays, Lindsay E, Busemann, Henner, Cavalazzi, Barbara, Debaille, Vinciane, Grady, Monica M., Hauber, Ernst, Pratt, Lisa M, Smith, Alvin L, Smith, Caroline L, Summons, Roger E., Swindle, Timothy D, Tait, Kimberly T, Udry, Arya, Usui, Tomohiro, Wadhwa, Meenakshi, Westall, Frances, and Zorzano, Maria-Paz

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) identif

48. Rationale and Proposed Design for a Mars Sample Return (MSR) Science Program

Author

Haltigin, Timothy, Hauber, Ernst, Kminek, Gerhard, Meyer, Michael A., Agee, Carl B., Busemann, Henner, Carrier, Brandi Lee, Glavin, Daniel P., Hays, Lindsay E, Marty, Bernard, Pratt, Lisa M, Udry, Arya, Zorzano, Maria-Paz, Beaty, David W, Cavalazzi, Barbara, Cockell, Charles S., Debaille, Vinciane, Grady, Monica M., Hutzler, Aurore, McCubbin, Francis M., Regberg, Aaron B., Smith, Alvin L., Smith, Caroline L, Summons, Roger E., Swindle, Timothy D., Tait, Kimberly T., Tosca, Nicholas J., Usui, Tomohiro, Velbel, Michael A., Wadhwa, Meenakshi, Westall, Frances, Haltigin, Timothy, Hauber, Ernst, Kminek, Gerhard, Meyer, Michael A., Agee, Carl B., Busemann, Henner, Carrier, Brandi Lee, Glavin, Daniel P., Hays, Lindsay E, Marty, Bernard, Pratt, Lisa M, Udry, Arya, Zorzano, Maria-Paz, Beaty, David W, Cavalazzi, Barbara, Cockell, Charles S., Debaille, Vinciane, Grady, Monica M., Hutzler, Aurore, McCubbin, Francis M., Regberg, Aaron B., Smith, Alvin L., Smith, Caroline L, Summons, Roger E., Swindle, Timothy D., Tait, Kimberly T., Tosca, Nicholas J., Usui, Tomohiro, Velbel, Michael A., Wadhwa, Meenakshi, and Westall, Frances

Abstract

The Mars Sample Return (MSR) Campaign represents one of the most ambitious scientific endeavors ever undertaken. Analyses of the martian samples would offer unique science benefits that cannot be attained through orbital or landed missions that rely only on remote sensing and in situ measurements, respectively. As currently designed, the MSR Campaign comprises a number of scientific, technical, and programmatic bodies and relationships, captured in a series of existing and anticipated documents. Ensuring that all required scientific activities are properly designed, managed, and executed would require significant planning and coordination. Because there are multiple scientific elements that would need to be executed to achieve MSR Campaign success, it is critical to ensure that the appropriate management, oversight, planning, and resources are made available to accomplish them. This could be achieved via a formal MSR Science Management Plan (SMP). A subset of the MSR Science Planning Group 2 (MSPG2)—termed the SMP Focus Group—was tasked to develop inputs for an MSR Campaign SMP. The scope is intended to cover the interface to the Mars 2020 mission, science elements in the MSR flight program, ground-based science infrastructure, MSR science opportunities, and the MSR sample and science data management. In this report, a comprehensive MSR Science Program is proposed that comprises specific science bodies and/or activities that could be implemented to address the science functionalities throughout the MSR Campaign. The proposed structure was designed by taking into consideration previous management review processes, a set of guiding principles, and key lessons learned from previous robotic exploration and sample return missions.

50. Rationale and Proposed Design for a Mars Sample Return (MSR) Science Program

Author

Haltigin, Timothy, Hauber, Ernst, Kminek, Gerhard, Meyer, Michael A., Agee, Carl B., Busemann, Henner, Carrier, Brandi Lee, Glavin, Daniel P., Hays, Lindsay E, Marty, Bernard, Pratt, Lisa M, Udry, Arya, Zorzano, Maria-Paz, Beaty, David W, Cavalazzi, Barbara, Cockell, Charles S., Debaille, Vinciane, Grady, Monica M., Hutzler, Aurore, McCubbin, Francis M., Regberg, Aaron B., Smith, Alvin L., Smith, Caroline L, Summons, Roger E., Swindle, Timothy D., Tait, Kimberly T., Tosca, Nicholas J., Usui, Tomohiro, Velbel, Michael A., Wadhwa, Meenakshi, Westall, Frances, Haltigin, Timothy, Hauber, Ernst, Kminek, Gerhard, Meyer, Michael A., Agee, Carl B., Busemann, Henner, Carrier, Brandi Lee, Glavin, Daniel P., Hays, Lindsay E, Marty, Bernard, Pratt, Lisa M, Udry, Arya, Zorzano, Maria-Paz, Beaty, David W, Cavalazzi, Barbara, Cockell, Charles S., Debaille, Vinciane, Grady, Monica M., Hutzler, Aurore, McCubbin, Francis M., Regberg, Aaron B., Smith, Alvin L., Smith, Caroline L, Summons, Roger E., Swindle, Timothy D., Tait, Kimberly T., Tosca, Nicholas J., Usui, Tomohiro, Velbel, Michael A., Wadhwa, Meenakshi, and Westall, Frances

Abstract

The Mars Sample Return (MSR) Campaign represents one of the most ambitious scientific endeavors ever undertaken. Analyses of the martian samples would offer unique science benefits that cannot be attained through orbital or landed missions that rely only on remote sensing and in situ measurements, respectively. As currently designed, the MSR Campaign comprises a number of scientific, technical, and programmatic bodies and relationships, captured in a series of existing and anticipated documents. Ensuring that all required scientific activities are properly designed, managed, and executed would require significant planning and coordination. Because there are multiple scientific elements that would need to be executed to achieve MSR Campaign success, it is critical to ensure that the appropriate management, oversight, planning, and resources are made available to accomplish them. This could be achieved via a formal MSR Science Management Plan (SMP). A subset of the MSR Science Planning Group 2 (MSPG2)—termed the SMP Focus Group—was tasked to develop inputs for an MSR Campaign SMP. The scope is intended to cover the interface to the Mars 2020 mission, science elements in the MSR flight program, ground-based science infrastructure, MSR science opportunities, and the MSR sample and science data management. In this report, a comprehensive MSR Science Program is proposed that comprises specific science bodies and/or activities that could be implemented to address the science functionalities throughout the MSR Campaign. The proposed structure was designed by taking into consideration previous management review processes, a set of guiding principles, and key lessons learned from previous robotic exploration and sample return missions.

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