近地空间辐射环境与防护方法概述

摘要/Abstract

摘要： 介绍了宇宙空间及空间站内的辐射环境,针对各类太空辐射,选用合适的屏蔽材料、选择发射时机和运行轨道躲避强太空辐射,合理采用各种辐射防护方法和生物化学防护剂进行防护。

Abstract: The radiation conditions in space andwithin space stations were overviewed. On account of all kinds of space radiation, there are lots of measures for protection, including choosing suitable shielding material,adopting launch timing and orbit, using of various radiation protection methods and biochemical protective agents.

Key words: Space radiation, HZE particles, Radiation protection

中图分类号:

Q691

程彭超, 闵锐. 近地空间辐射环境与防护方法概述[J]. 辐射防护通讯, 2017, 37(1): 14-21.

Cheng Pengchao, Min Rui. An Overview of Near-Earth Space Radiation and its Protection[J]. RADIATION PROTECTION BULLETIN, 2017, 37(1): 14-21.

参考文献

[1] Sihver L, Ploc O, Puchalska M, et al. Radiation environmentat aviation altitudes and in space[J]. Radiation Protection Dosimetry, 2015,164(4):477-483.
[2] Sanzari J K, Diffenderfer E S, Hagan S, et al. Dermatopathology effects of simulated solar particle event radiation exposure in the porcinemodel[J]. Life Sciences in Space Research, 2015,6:21-8.
[3] Ukhorskiy A Y, Sitnov M I, Mitchell D G, et al. Rotationally driven 'zebra stripes'in Earth's inner radiation belt[J]. Nature, 2014,507(7492):338-340
[4] Myers C E, Yamada M, Ji H, et al. A dynamic magnetic tension force as the cause of failed solar eruptions[J]. Nature, 2015,528(7583):526-529.
[5] Vilmer N. Solar flares and energetic particles[J]. Philosophical transactions Series A, Mathematical, Physical, and Engineering Sciences,2012,370(1970):3241-3268.
[6] Cranmer S R, Asgari-Targhi M, Miralles M P, et al. The role of turbulence in coronal heating and solar wind expansion[J]. PhilosophicalTransactions Series A, Mathematical, Physical, and Engineering Sciences, 2015,373(2041):20140148.
[7] Luhmann J G, Petrie G, Riley P. Solar origins of solar windproperties during the cycle 23 solar minimum and rising phase of cycle 24[J].Journal of Advances Research, 2013,4(3):221-228.
[8] Poletto G. Sources of solar wind over the solar activity cycle[J]. Journal of Advances Research, 2013,4(3):215-220.
[9] Cucinotta F A. Space Radiation Risks for Astronauts on Multiple International Space Station Missions[J]. Public Library of Science one, 2014,9(4):e96099.
[10] Mertsch P, Funk S. Solution to the cosmic ray anisotropy problem[J]. Physical Review Letters, 2015,114(2):021101.
[11] Zeitlin C, La Tessa C. The Role of Nuclear Fragmentation in Particle Therapy and Space Radiation Protection[J]. Frontiers in Oncology, 2016,6:65.
[12] Dietze G, Bartlett D T, Cool D A, et al. Assessment of radiation exposure of astronauts in space[R]. ICRP Publication 123, 2013, 42(4):1-339.
[13] Ahlers M. Anomalous anisotropies of cosmic rays from turbulent magnetic fields[J]. Physical Review Letters, 2014,112(2):021101.
[14] Ukhorskiy A Y, Sitnov M I, Mitchell D G, et al. Rotationally driven zebra stripes in Earth's inner radiation belt[J]. Nature, 2014,507(7492):338-340.
[15] Roberts P H, King E M. On the genesis of the Earth's magnetism[J]. Reports on Progress in Physics, 2013,76(9):096801.
[16] King E M, Aurnou J M. Magnetostrophic balance as the optimal statefor turbulent magnetoconvection[J]. Proceedings of the National Academy of Sciences of the United States of America, 2015,112(4):990-994.
[17] Di Fino L, Casolino M, De Santis C, et al. Heavy-ion anisotropy measured by ALTEA in the International Space Station[J]. Radiation Research, 2011,76(3):397-406.
[18] Badhwar G D, Atwell W, Badavi F F, et al. Space radiation absorbeddose distribution in a human phantom[J]. Radiation Research, 2002,157(1):76-91.
[19] Pálfalvi J K, Akatov Y, Szabó J, et al. Detection of primary andsecondary cosmic ray particles aboard the ISS using SSNTD stacks[J]. Radiation Protection Dosimetry, 2006,120(1-4):427-432.
[20] Bernabeu J, Casanova I. Geant4-based radiation hazard assessment for human exploration missions[J]. Advances in Space Research, 2007,40:1368-1380.
[21] 马丹. 国际太空站实验显示宇宙实际辐射量或被高估[EB/OL]. [2015－01－05]. http://world.huanqiu.com/exclusive/2015-01/5340046.html.
[22] Li M, Gonon G, Buonanno M, et al. Health Risks of Space Exploration: Targeted and Nontargeted Oxidative Injury by High-Charge and High-Energy Particles[J]. Antioxidants & Redoxsignaling, 2014,20(9):1501-1521.
[23] Cucinottaa F A, Alp Murat, Sulzman F M, et al. Space radiation risks to the central nervous system[J]. Life Sciences in Space Research, 2014,2:54-69.
[24] Ongaro F. From space medicine to preventive and personalized health care on earth[J]. Acta Astronautica, 2014,104:409-411.
[25] Kennedy A R. biological effects of space radiation and developmentof effective countermeasures[J]. Life Sciences in Space Research,2014,1:10-43.
[26] Durante M, Eighth W K. Sinclair keynote address: heavy ions in therapy and space benefits and risks[J]. Health Physics, 2012,103(5):532-539.
[27] Crucian B, Stowe R, Mehta S, et al. Immune system dysregulation occurs during short duration spaceflight on board the space shuttle[J]. Journalof Clinical Immunology, 2013,33(2):456-465.
[28] Crucian B, Stowe R, Quiriarte H, et al. Monocyte phenotype and cytokine production profiles are dysregulated by short-duration spaceflight[J].Aviation Space and Environmental Medicine, 2011,82: 857-62.
[29] Crucian B, Simpson R J, Mehta S, et al. Terrestrial stress analogsfor spaceflight associated immune system dysregulation[R]. Brain Behavior andImmunity, 2014,39:23-32.
[30] Dietze G, Bartlett D T, Cool D A, et al. Assessment of radiation exposure of astronauts in space[R]. ICRP Publication 123, 2013,42(4):1-339.
[31] Vana N, Hajek M, Berger T, et al. Novel shielding materials for space and air travel[J]. Radiation Protection Dosimetry, 2006,120:405-409.
[32] El-Jaby S, Richardson R B. Monte Carlo simulations of the secondary neutron ambient and effective dose equivalent rates from surface to suborbital altitudes and low Earth orbit[J]. Life sciences in space research, 2015,6:1-9.
[33] Pugliese M, Bengin V, Casolino M, et al. Tests of shielding effectiveness of Kevlar and Nextel onboard the International Space Station and the Foton-M3 capsule[J]. Radiation and Environmental Biophysics, 2010,49(3):359-363.
[34] Mortazavi S M, Cameron J R, Niroomand-rad. A adaptive response studies may help choose astronauts for long-term space travel[J]. Advances in Space Research:the Official Journal of the Committee on Space Research, 2003,31:1543-1551.
[35] Vasin M V. Comments on the mechanisms of action of radiation protective agents: basis components and their polyvalence[J]. Springerplus, 2014,3:414.
[36] Mortazavi S M, Rahimi S, Mosleh-Shirazi M A, et al. Comparative Study on the Life-Saving Radioprotective Effects of Vitamins A, E, C and Over-the-Counter Multivitamins[J]. Journal of Biomedical Physics & Engineering, 2015,5(2):59-66.
[37] Shinde A, Epperly M W, Cao S, et al. Improved hematopoiesis in GS-nitroxide (JP4-039)-treated mouse long-term bone marrow cultures and radioresistance of derived bone marrow stromal cell lines[J]. In Vivo, 2014,28(5):699-708.
[38] Greenberger J, Kagan V, Bayir H, et al. Antioxidant Approaches toManagement of Ionizing Irradiation Injury[J]. Antioxidants (Basel), 2015,4(1):82-101.
[39] Schreurs A S, Shirazi-Fard Y, Shahnazari M, et al. Dried plum diet protects from bone loss caused by ionizing radiation[J]. Scientific Reports,2016,6:21343.
[40] 程彭超, 闵锐. 辐射防护/减轻/调节剂研究综述[J]. 辐射研究与辐射工艺学报, 2015,13(6):1-8.
[41] Brown S L, Kolozsvary A, Liu J, et al. Antioxidant diet supplementation starting 24 hours after exposure reduces radiation lethality[J]. Radiation Research, 2010,173(4):462-468.
[42] Mettler F A , Brenner D, Coleman C N, et al. Can radiation risks to patients be reduced without reducing radiation exposure The status of chemicalradioprotectants[J]. American Journal of Roentgenology, 2011,196(3):616-618.