改造火星的技术要求

Q4 Engineering

Jbis-Journal of the British Interplanetary Society Pub Date : 1993-06-28 DOI:10.2514/6.1993-2005

R. Zubrin, C. Mckay

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引用次数: 51

摘要

火星虽然今天寒冷而干旱，但曾经拥有温暖潮湿的气候，这一点可以从火星表面广泛可见的河流特征中得到证明。据信，原始火星的温暖气候是由浓厚的二氧化碳大气引起的强烈温室效应造成的。由于水的循环作用，大部分可用的挥发性二氧化碳被固定成碳酸盐岩的形式，火星失去了温暖的气候。然而，据信，足以形成300至600立方米大气的二氧化碳仍可能以挥发形式存在，要么被吸附到风化层中，要么被冻结在南极。这些二氧化碳可能会因全球变暖而释放出来，随着二氧化碳大气的增厚，会产生正反馈，从而加速变暖趋势。因此，可以想象，通过利用火星大气/风化层二氧化碳系统固有的正反馈，工程努力可以在全球范围内产生气候和压力的剧烈变化。在本文中，我们提出了一个火星二氧化碳系统的数学模型，并用它来进行分析，阐明了正反馈加速行星工程努力的潜力。结果表明，通过利用反馈，行星工程的需求相对于以前的估计可降低约2个数量级。我们研究了产生初始变暖的各种方案的潜力，以推动这一过程，包括轨道反射镜的安置，从太阳系外进口具有高温室容量的天然挥发物，以及通过原位工业在火星表面生产人工卤代烃温室气体。如果采用轨道反射镜方案，则需要直径约为100公里的反射镜来蒸发南极帽中的二氧化碳。如果用类似太阳帆的材料制造，这种反射镜的质量将达到20万吨左右。如果用小行星或火星卫星的材料在太空中制造，大约需要120兆瓦年的能量来生产所需的铝。这一数量的电力可以由近期的多方提供

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Technological requirements for terraforming Mars

The planet Mars, while cold and arid today, once possessed a warm and wet climate, as evidenced by extensive fluvial features observable on its surface. It is believed that the warm climate of the primitive Mars was created by a strong greenhouse effect caused by a thick CO2 atmosphere. Mars lost its warm climate when most of the available volatile CO2 was fixed into the form of carbonate rock due to the action of cycling water. It is believed, however, that sufficient CO2 to form a 300 to 600 mb atmosphere may still exist in volatile form, either adsorbed into the regolith or frozen out at the south pole. This CO2 may be released by planetary warming, and as the CO2 atmosphere thickens, positive feedback is produced which can accelerate the warming trend. Thus it is conceivable, that by taking advantage of the positive feedback inherent in Mars' atmosphere/regolith CO2 system, that engineering efforts can produce drastic changes in climate and pressure on a planetary scale. In this paper we propose a mathematical model of the Martian CO2 system, and use it to produce analysis which clarifies the potential of positive feedback to accelerate planetary engineering efforts. It is shown that by taking advantage of the feedback, the requirements for planetary engineering can be reduced by about 2 orders of magnitude relative to previous estimates. We examine the potential of various schemes for producing the initial warming to drive the process, including the stationing of orbiting mirrors, the importation of natural volatiles with high greenhouse capacity from the outer solar system, and the production of artificial halocarbon greenhouse gases on the Martian surface through in-situ industry. If the orbital mirror scheme is adopted, mirrors with dimension on the order or 100 km radius are required to vaporize the CO2 in the south polar cap. If manufactured of solar sail like material, such mirrors would have a mass on the order of 200,000 tonnes. If manufactured in space out of asteroidal or Martian moon material, about 120 MWe-years of energy would be needed to produce the required aluminum. This amount of power can be provided by near-term multi

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来源期刊

Jbis-Journal of the British Interplanetary Society Earth and Planetary Sciences-Space and Planetary Science

CiteScore

0.70

自引率

0.00%

发文量

期刊介绍： The Journal of the British Interplanetary Society (JBIS) is a technical scientific journal, first published in 1934. JBIS is concerned with space science and space technology. The journal is edited and published monthly in the United Kingdom by the British Interplanetary Society. Although the journal maintains high standards of rigorous peer review, the same with other journals in astronautics, it stands out as a journal willing to allow measured speculation on topics deemed to be at the frontiers of our knowledge in science. The boldness of journal in this respect, marks it out as containing often speculative but visionary papers on the subject of astronautics.