| AEROSPACE MATERIALS |
|
|
|
|
|
| Potential Approaches to In-situ Utilization of Martian Resources: a Technical Analysis |
| FENG Lei, SHU Wenxiang, WEN Chen, CUI Qingxin*, BAI Jingying, LI Xinxin
|
| Beijing Spacecrafts, Beijing 100094, China |
|
|
|
|
Abstract Humanity has orbited, landed on, and roved and inspected Mars, with new insights into Mars's internal structure and environmental studies including weathers, climates and others. Based on the latest probing and data analysis of Mars's resources, Mars's livability and feasibility for establishing bases are analyzed. In view of China's unmanned and manned Mars mission probes in the future, the analysis of main functions of Mars's resources is carried out from the following five aspects: (ⅰ) preparing water, oxygen, plants, and other life support materials; (ⅱ) preparing propellants; (ⅲ) preparing wind, solar and other powers; (ⅳ) building infrastructure with blocks, 3D printing or others; (ⅴ) in-situ manufacturing of metals, chemical engineering materials and products. Considering the features of Mars' resources and the practical needs of future Mars mission probes, this paper systematically analyzes centering around the application channels for Mars' in-situ materials, which is referential to research of the technology of Mars's individual or integrated resource exploitation.
|
|
Published: 25 November 2022
Online: 2022-11-25
|
|
|
|
|
1 Zacny K, Paulsen G, Craft J, et al.Concepts and Approaches for Mars Exploration, 2012, 1679, 4268.
2 Sanders G.In: 48th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition. Orlando, 2010, pp.799.
3 Yu Y M, Gan P P, Zhou P, et al.Remote Sensing for Land & Resources, 2009(4), 6(in Chinese).
于艳梅, 甘甫平, 周萍,等.国土资源遥感, 2009(4), 6.
4 Sanders G B, Larson W E.Advances in Space Research, 2011, 47(1), 20.
5 Geoffrey A L, Dan H. In: Proceedings of the IEEE 4th World Conference on Photovoltaic Energy Conversion. New York, 2006, pp.151.
6 Guo L L, Wang P, Zhu S Y. In-situ resource utilization technology for manned lunar and Mars exploration missions, China Space Navigation Press, China, 2018, pp.27(in Chinese).
果林丽, 王平, 朱思涌.面向载人月球及火星探测任务的原位资源利用技术, 中国宇航出版社, 2018, pp.27.
7 Hoffman S J, Andrews A, Joosten B K, et al.In: 2017 IEEE Aerospace Conference. Montana, 2017, pp.1.
8 Walton K S, Le Van M D.In: Strategic Research to Enable NASA's Exploration Missions Conference and Workshop. Cleveland, 2004, pp.2.
9 Hecht M, Hoffman J, Rapp D, et al.Space Science Reviews, 2021, 217(1), 1.
10 Hartvigsen J, Elangovan S, Elwell J, et al. ECS Transactions, 2017, 78(1), 3317.
11 Parrish C F, Lueck D E, Jennings P A.American Institute of Physics, 2001, 552(1), 133.
12 Kerslake T W, Benson S W. Research & technology 1999, National Aeronautics and Space Administration, USA, 2000, pp.163.
13 Bubenheim D L. SAE Transactions, 1998, 1, 107.
14 Delgado-Bonal A, Martin-Torres F J, Vazquez-Martin S, et al. Energy, 2016, 102, 550.
15 Zhao Y, Ding C, Zhu J, et al. Angewandte Chemie International Edition, 2020, 59(24),9653.
16 Grossman K, Sakthivel T S, Mantovani J, et al. In: Joint Meeting of the Space Resources Roundtable. Denver, 2016, No. KSC-E-DAA-TN31958.
17 Werkheiser M J, Fiske M, Edmunson J, et al.In: AIAA SPACE 2015 Conference and Exposition. Californ, 2015, pp.4451.
18 Badescu V. Mars: prospective energy and material resources, Springer Science & Business Media, Germany, 2009, pp.430. |
|
|
|
渝公网安备50019002502923号 © Editorial Office of Materials Reports.
2022, Vol. 36 
