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Astronomy and space science, including their associated basic research activities, enjoy broad popular backing. People generally
support them, and say that they follow their results with interest. This article summarizes some of the detailed results of
public surveys in the United States, focusing on popular opinions and attitudes, and the somewhat paradoxical finding that
despite being interested and supportive, people are often ignorant about the basic facts. I explore some of the reasons for
the popularity of space science, and suggest ways of justifying space science research in the broader context of science research.
I argue that vigorous and innovative education and outreach programs are important, and can be made even more effective.
This revised version was published online in June 2006 with corrections to the Cover Date. 相似文献
3.
周其焕 《中国民航学院学报》2005,23(1):61-64
为减少和消除海峡两岸科技文化交流上的词汇障碍,各学科广泛开展着科技术语的调查研究、交流和讨论。当前做法为两步走,首先是分析两岸用词上相同和差异的词目,共同编订对照本,共建对照和约定;然后逐步地通过对存在差异的个例进行选优汰劣和具体的商榷,过渡到更多的协调和一致。 相似文献
4.
Luo Xucheng 《宇航学报》1990,(3)
本文研究了入射波电场为任意线极化时,平直地面反射波中左旋圆极化分量和右旋圆极化分量的数学描述,引入了地面对这类波的等效反射系数的概念,并给予了物理解释,讨论了应用的有关问题。 相似文献
5.
美国科技文献资源体系建设及启示 总被引:4,自引:0,他引:4
介绍了美国联邦政府和国家航空般天局(NASA)科技文献信息资源体系建设,科技信息纲领的内涵、宗旨、任务、目标,实施科技信息纲领的工作程序、组织管理机构,科技信息产品和服务,以及美国国家技术信息服务中心(NTIS)和航空航天科技信息中心(CASI)的运作情况,论述了美国科技文献信息资源在推动科技进步中的作用,并在研究分析的基础上给出了结论。 相似文献
6.
D. Koschny V. Dhiri K. Wirth J. Zender R. Solaz R. Hoofs R. Laureijs T.-M Ho B. Davidsson G. Schwehm 《Space Science Reviews》2007,128(1-4):167-188
ESA’s Rosetta mission was launched in March 2004 and is on its way to comet 67P/Churyumov-Gerasimenko, where it is scheduled
to arrive in summer 2014. It comprises a payload of 12 scientific instruments and a Lander. All instruments are provided by
Principal Investigators, which are responsible for their operations.
As for most ESA science missions, the ground segment of the mission consists of a Mission Operations Centre (MOC) and a Science
Operations Centre (SOC). While the MOC is responsible for all spacecraft-related aspects and the final uplink of all command
timelines to the spacecraft, the scientific operations of the instruments and the collection of the data and ingestion into
the Planetary Science Archive are coordinated by the SOC. This paper focuses on the tasks of the SOC and in particular on
the methodology and constraints to convert the scientific goals of the Rosetta mission to operational timelines. 相似文献
7.
Mercury’s unusually high mean density has always been attributed to special circumstances that occurred during the formation of the planet or shortly thereafter, and due to the planet’s close proximity to the Sun. The nature of these special circumstances is still being debated and several scenarios, all proposed more than 20 years ago, have been suggested. In all scenarios, the high mean density is the result of severe fractionation occurring between silicates and iron. It is the origin of this fractionation that is at the centre of the debate: is it due to differences in condensation temperature and/or in material characteristics (e.g. density, strength)? Is it because of mantle evaporation due to the close proximity to the Sun? Or is it due to the blasting off of the mantle during a giant impact? In this paper we investigate, in some detail, the fractionation induced by a giant impact on a proto-Mercury having roughly chondritic elemental abundances. We have extended the previous work on this hypothesis in two significant directions. First, we have considerably increased the resolution of the simulation of the collision itself. Second, we have addressed the fate of the ejecta following the impact by computing the expected reaccretion timescale and comparing it to the removal timescale from gravitational interactions with other planets (essentially Venus) and the Poynting–Robertson effect. To compute the latter, we have determined the expected size distribution of the condensates formed during the cooling of the expanding vapor cloud generated by the impact. We find that, even though some ejected material will be reaccreted, the removal of the mantle of proto-Mercury following a giant impact can indeed lead to the required long-term fractionation between silicates and iron and therefore account for the anomalously high mean density of the planet. Detailed coupled dynamical–chemical modeling of this formation mechanism should be carried out in such a way as to allow explicit testing of the giant impact hypothesis by forthcoming space missions (e.g. MESSENGER and BepiColombo). 相似文献
8.
王心丰 《南京航空航天大学学报》1986,(4)
本文根据半角转动的原理,提出了一种连杆位置综合的解析方法。此法概念清晰,计算比较方便。而且易于与图解法相沟通。列出了连杆五个位置综合问题的四个非线性方程。在解法上把上述问题化归为用优化方法求解。 相似文献
9.
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