Biological space experiments for the simulation of Martian conditions: UV radiation and Martian soil analogues.

The survivability of resistant terrestrial microbes, bacterial spores of Bacillus subtilis, was investigated in the BIOPAN facility of the European Space Agency onboard of Russian Earth-orbiting FOTON satellites (BIOPAN I -III missions). The spores were exposed to different subsets of the extreme environmental parameters in space (vacuum, extraterrestrial solar UV, shielding by protecting materials like artificial meteorites). The results of the three space experiments confirmed the deleterious effects of extraterrestrial solar UV radiation which, in contrast to the UV radiation reaching the surface of the Earth, also contains the very energy-rich, short wavelength UVB and UVC radiation. Thin layers of clay, rock or meteorite material were shown to be only successful in UV-shielding, if they are in direct contact with the spores. On Mars the UV radiation climate is similar to that of the early Earth before the development of a protective ozone layer in the atmosphere by the appearance of the first aerobic photosynthetic bacteria. The interference of Martian soil components and the intense and nearly unfiltered Martian solar UV radiation with spores of B. subtilis will be tested with a new BIOPAN experiment, MARSTOX. Different types of Mars soil analogues will be used to determine on one hand their potential toxicity alone or in combination with solar UV (phototoxicity) and on the other hand their UV protection capability. Two sets of samples will be placed under different cut-off filters used to simulate the UV radiation climate of Mars and Earth. After exposure in space the survival of and mutation induction in the spores will be analyzed at the DLR, together with parallel samples from the corresponding ground control experiment performed in the laboratory. This experiment will provide new insights into the principal limits of life and its adaptation to environmental extremes on Earth or other planets which and will also have implications for the potential for the evolution and distribution of life.     

微重力条件下红外材料的空间生长

根据近年红外材料在空间生长的研究概况,分析了涵盖熔体、气相、液相外延和分子束外延等生长方法及各个方法生长红外材料的基本原理,在地面生长遇到的问题,以及在空间微重力环境中进行红外材料生长的优势.同时基于中国利用熔体法在天宫二号上已经进行的ZnTe:Cu晶体的空间生长科学实验及地基实验结果,通过对空间和地面实验结果进行对比,提出了在超高真空环境下,利用分子束外延方式生长高性能、大尺寸红外材料的可能性,以及未来在空间微重力条件下进行红外材料生长的研究方向及具体应用.      

Experiments in materials science on the ground and in reduced gravity using electrostatic levitators

To counter residual accelerations, dedicated levitators or positioners are necessary to support a host of materials science experiments on the ground and in microgravity. All levitators (e.g., aerodynamic, acoustic, electromagnetic, electrostatic, optical) have their own merits and limitations but the electrostatic scheme offers the combined advantages of processing millimeter-size objects, independent heating, quasi-spherical shape of molten materials, handling of materials under extreme temperatures for hours, virtually convection-free samples, and wide view around the samples for diagnostic. These attributes provide unique research opportunities in materials science on the ground as well as under reduced gravity. In particular, electrostatic levitators are very attractive to measure the physical and structural properties of equilibrium and non-equilibrium liquids, to synthesize multi-function materials, and to understand metastable phase formation, vitrification, and diffusion. In this paper, research and development carried out by the Japan Aerospace Exploration Agency over the years in the field of electrostatic levitation are summarized and the main results obtained in materials science are presented.     

Manipulation of Colloidal Droplets in Space and the Instability of Thermocapillary Convection in Large Prandtl Number Liquid Bridge in Microgravity

In 2016 and 2017, SJ-10 and TG-2 satellites were launched. In this short paper, we report recent progress on the studies of manipulation of colloidal droplets and instability of thermocapillary convection in large Prandtl number liquid bridge that based on the space experiments boarding SJ-10 and TG-2 satellites, separately. It was shown that the colloidal droplets can be successfully formed and manipulated in microgravity through the patterned substrates. In another aspect, the coffee-ring effect was observed at the first time in space. For the studies of the instability of thermocapillary convection in large Prandtl number liquid bridge in microgravity, our experiments in TG-2 broadened the way of such kind of study and abundant experimental results are emerging.      

Science Research and Utilization Planning of China's Space Station in Operation Period 2022-2032

The core module of China's Space Station (CSS) is scheduled to be launched around the end of 2020, and the experimental module I and II will be launched in the next two years. After on-orbit constructions, CSS will be transferred into an operation period over 10 years (2022-2032 and beyond) to continuously implement space science missions. At present, based on the project selection and research work in the ground development period of CSS, China is systematically making a utilization mission planning for the operation period, which focuses on the fields of aerospace medicine and human research, space life science and biotechnology, microgravity fluid physics, combustion science, materials science, fundamental physics, space astronomy and astrophysics, Earth science, space physics and space environment, space application technology, etc. In combination with the latest development trend of space science and technology, China will continue to update planning for science research and technology development, carry out project cultivation, payload R&D, and upgrade onboard and ground experiment supporting systems to achieve greater comprehensive benefits in science, technology, economy, and society.      

我国首次空间微重力下的材料加工试验

1987年8月5日至10日,我国首次利用返回卫星进行了空间微重力下的材料加工实验。本次试验共有12个项目,其中砷化镓单晶生长达到国际先进水平,Y-Ba-Cu高温超导材料试验则为世界首次,HgCdTe红外材料,Insb半导体材料和难混合全都取得了地面不能得到的结果。这次试验的多用途加工炉吸收了国外空间加工技术的特点,构思巧妙、效果明显.一炉多用开创空间搭载的新路子。     

2000年前我国空间材料科学试验设想

讨论空间环境对材料制备的影响;提出空间材料研究的四个发展阶段和各国空间材料制备现今处在研究发展阶段的观点;分析我国空间材料研究的状况、任务及试验的可能途径;叙述空间材料科学研究的内容;对2000年前我国空间材料试验提出初步设想。     

Preliminary results of space experiment: Implications for the effects of space radiation and microgravity on survival and mutation induction in human cells

In view of the concern for the health of astronauts that may one day journey to Mars or the Moon, we investigated the effect that space radiation and microgravity might have on DNA damage and repair. We sent frozen human lymphoblastoid TK6 cells to the International Space Station where they were maintained under frozen conditions during a 134-day mission (14 November 2008 to 28 March 2009) except for an incubation period of 8 days under 1G or μG conditions in a CO₂ incubator. The incubation period started after 100 days during which the cells had been exposed to 54 mSv of space radiation. The incubated cells were then refrozen, returned to Earth, and compared to ground control samples for the determination of the influence of microgravity on cell survival and mutation induction. The results for both varied from experiment to experiment, yielding a large SD, but the μG sample results differed significantly from the 1G sample results for each of 2 experiments, with the mean ratio of μG to 1G being 0.55 for the concentration of viable cells and 0.59 for the fraction of thymidine kinase deficient (TK⁻) mutants. Among the mutants, non-loss of zygosity events (point mutations) were less frequent (31%) after μG incubation than after 1G incubation, which might be explained by the influence of μG on cellular metabolic or physiological function. Additional experiments are needed to clarify the effect of μG interferes on DNA repair.     

Large-size space laboratory for biological orbit experiments.

The study of space factors on living systems has great interest and long-term experiments during orbital flight will be important tool for increasing our knowledge. Realization of such experiments is limited by constraints of modern space stations. A new technology of large-size space laboratory for biological experiments has been developed on the basis of polymerization techniques. Using this technique there are no limits of form and size of laboratory for a space station that will permit long term experiments on Earth orbit with plants and animals in sufficient volume for creation of closed self-regulating ecological systems. The technology is based on experiments of the behavior of polymer materials in simulated free space conditions during the reaction of polymerization. The influences of space vacuum, sharp temperature changes and space plasma generated by galactic rays and Sun irradiation on chemical reaction were evaluated in their impact on liquid organic materials in laboratory conditions. The results of our study shows, that the chemical reaction is sensitive to such space factors. But we believe that the technology of polymerization could be used for the creation of space biological laboratories in Earth orbit in the near future.     

Preparing for space: Increasing technical readiness of low-cost high-performance remote sensing using high-altitude ballooning

Two widely available, small size, weight and power camera systems were flown above 97 % of Earth’s atmosphere and showed utility in single filter vegetation and soil analysis in a space analogue environment. The experiment was conducted as a low-cost verification and test analogue to flying on vastly more expensive low Earth orbit missions. Normalised Difference Vegetation Index (NDVI) was used as the metric by which performance was analysed for ground calibration testing, low and near-space altitude remote sensing. Ground calibration testing with a laboratory-grade spectrometer revealed that both cameras were able to return consistent NDVI results, and high-altitude balloon flight allowed similar data capture from an environment similar to space. Although compressed captured imagery had been processed using gamma correction and pre-image processing, these were able to be corrected provided that access to radiometrically-calibrated data was available. The two hobbyist cameras were shown to return scientifically useful results, demonstrating performance, and additionally their utility for citizen science applications in the near-space environment.     

天宫二号碲化锌晶体生长

在天宫二号飞船综合材料实验炉六工位采用碲熔剂法生长了碲化锌晶体,生长时最高温度为800℃,以0.5mm·h-1的提拉速度向炉膛内部提拉生长晶体.飞行实验后,用相同实验参数在地面进行了对比实验.结果发现,空间样品尾部有一个非常大的橙色结晶区域（约10mm×6mm×2mm）,而地面生长样品中碲化锌晶体尺寸仅为约3mm×3mm×1mm,空间生长的碲化锌晶粒尺寸明显优于地面.空间微重力环境下,由于毛细作用,空间样品的塞子处有Te和ZnTe的外延膜生成.而地面生长的锭条在塞子处只有零星点状气相生产物.因此微重力条件有利于碲化锌晶体材料的生长.      

中国微重力科学研究回顾与展望

微重力科学主要研究微重力环境中物质运动的规律,以及不同重力环境中重力对物质运动的影响.中国微重力科学研究起步于20世纪60年代,兴起于80年代中后期,经过多年发展,目前已初具规模,在一些重要方向具有明显特色和一定优势.本文回顾了中国微重力科学研究的早期历程,评述了近年来中国微重力科学研究进展,特别是利用实践十号科学实验...     

实践十号卫星有效载荷胶体材料箱地基实验

胶体材料箱是装载于实践十号上的重要载荷,用于空间胶体自组装的实验研究.地基实验阐明了常重力下的蒸发驱动胶体自组装机制.围绕胶体材料箱开展地基实验研究,制备了一种亲/疏水限位基片,分析了蒸发过程中受限液滴接触角的变化规律.通过同步显微观察法研究受限胶体液滴内部粒子的沉积行为,发现粒子沉积图案的形成过程由三种动力学行为控制.另外,通过落塔装置模拟短时微重力环境,分析重力瞬变引起限位基片上液滴的振荡过程,揭示了振荡过程中两个不同阶段的振荡特性.地基实验结果为在轨实验工况确定以及空间与地面实验对比提供了数据支撑,这对箱体工程参数设定以及空间实验条件匹配等具有重要意义.      

空间小鼠实验有效载荷研究进展

啮齿动物是空间研究中常见的模型对象,已开展的空间生物实验中,小鼠表现出对飞行条件的有效适应.通过空间培养,研究者可对失重环境下小鼠的生理行为、骨骼和神经系统变化做进一步研究分析.本文对空间小鼠实验有效载荷的研究进展及其空间飞行实验进行了概述,为中国空间站上的小鼠培养箱设计提供参考.概述了地面小鼠培养技术和装置,为空间小...     

空间站材料科学加工试验炉的选择

对国际空间站上各国准备选用的材料科学试验加工炉进行了介绍. 主要呈现以下特点: 高度集成化的材料制备、测试、分析和处理等综合实验能力; 更高的精度、稳定性以及更长的使用寿命; 模块化、标准化和组合式; 应用遥科学实验技术. 从1998 年开始, 为适应未来中国空间站试验的需求, 发展了几类遥科学的空间加工炉及在长时间无人条件下由机器人照料的任意次更换样品的遥操作原型炉. 提出在中国载人航天工程第三步, 即空间站阶段的前期关键技术预研中, 设计和研发功能专业化, 结构模块化和接口标准化的典型功能实验单元, 通过技术集成可以在短时间内高效可靠地完成空间实验设备的配置、集成化和空间应用.      

Organics produced by ion irradiation of ices: some recent results.

Some results, recently obtained from laboratory experiments of ion irradiation of ice mixtures containing H, C, N, and O, are here summarized. They are relevant to the formation and evolution of complex organics on interstellar dust, comets and other small bodies in the external Solar System. In particular the formation of CN-bearing species is discussed. Interstellar dust incorporated into primitive Solar System bodies and subsequently delivered to the early Earth, may have contributed to the origin of life. The delivery of CN-bearing species seems to have been necessary because molecules containing the cyanogen bond are difficult to be produced in an environment that is not strongly reducing as that of the early Earth probably was. Moreover we report on an ongoing research program concerning the interaction between refractory materials produced by ion irradiation of simple ices and biological materials (amino acids, proteins, cells).     

The Japanese FMPT and related ground experiments—material experiments aspects

Japanese program of space experiment called FMPT (First Material Processing Test) has been reviewed from material experiments aspects. After looking at whole view of the FMPT by describing the kinds of equipments, the materials to be studied and the organizations to which PI belongs, several experiments are picked up and their objectives, the method of experiments, and expected results are reviewed. The impacts of FMPT on the Japanese scientists are finally discussed.     

The effect of microgravity on the development of plant protoplasts flown on Biokosmos 9.

An experiment using plant protoplasts has been accepted for the IML-1 Space Shuttle mission scheduled for 1991. Preparatory experiments have been performed using both fast and slow rotating clinostats and in orbit to study the effect of simulated and real weightlessness on protoplast regeneration. Late access to the space vehicles before launch has required special attention since it is important to delay cell wall regeneration until the samples are in orbit. On a flight on Biokosmos 9 ("Kosmos-2044") in September 1989 some preliminary results were obtained. Compared to the ground control, the growth of both carrot and rapeseed protoplasts was decreased by 18% and 44% respectively, after 14 days in orbit. The results also indicated that there is less cell wall regeneration under micro-g conditions. Compared to the ground controls the production of cellulose in rapeseed and carrot flight samples was only 46% and 29% respectively. The production of hemicellulose in the flight samples was 63% and 67% respectively of that of the ground controls. In both cases all samples reached the stage of callus development. The peroxidase activity was also found to be lower in the flight samples than in the ground controls, and the number of different isoenzymes was decreased in the flight samples. In general, the regeneration processes were retarded in the flight samples with respect to the ground controls. From a simulation experiment for IML-1 performed in January 1990 at ESTEC, Holland, regenerated plants have been obtained. These results are discussed and compared to the results obtained on Biokosmos 9. Protoplast regeneration did not develop beyond the callus stage in either the flight or the ground control samples from the Biokosmos 9 experiment.     

Progress in Space Material Researches

New progress in the post researches on space grown materials, the development of experiment facilities, and the experiment techniques for space materials researches were introduced. Besides the conventional materials, such as alloys, semiconductors, and optical crystals, new materials have also been prepared on the ground.     

一种通用红外成像跟踪实验装置的设计

介绍了一种先进的红外成像跟踪实验装置的研究与设计实现,给出了系统结构、主要性能参数、跟踪算法设计以及试验结果.在成功设计含双微处理机的并行图像识别跟踪器基础上,针对不同类型的目标开发了不同的跟踪算法以及噪声生成算法程序.该实验装置能模拟多种红外跟踪系统,可安装在直升机上对多种目标进行搜索、捕获和跟踪试验,试验恶劣天气、烟雾以及改变空间分辨率等系统参数对图像识别与跟踪的影响,也可进行各种干扰试验,以检查干扰效果.经试验验证,该系统有很好的应用效果.这些试验为模拟实验的研究提供大量原始素材,将为红外图像跟踪系统的设计和使用提供重要数据.