Detector packages consisting of thermoluminescence detectors (TLD), nuclear emulsions and plastic track detectors were exposed at identical positions inside MIR space station and on shuttle flights inside Spacelab and Spacehab during different phases of the solar cycle. The objectives of the investigations are to provide data on charge and energy spectra of heavy ions, and the contribution of events with low-energy deposit (protons, electrons, gamma, etc.) to the dose, as well as the contribution of secondaries, such as nuclear disintegration stars and neutrons. For neutron dosimetry (LiF)-Li-6 (TLD600) and (LiF)-Li-7 (TLD700) chips were used both of which have almost the same response to gamma rays but different response to neutrons. Neutrons in space are produced mainly in evaporation and knock-on processes with energies mainly of 1-10 MeV and up to several 100 MeV, respectively. The energy spectrum undergoes continuous changes toward greater depth in the attenuating material until an equilibrium is reached. In equilibrium, the spectrum is a wide continuum extending down to thermal energies to which the (LiF)-Li-6 is sensitive. Based on the difference of absorbed doses in the 6LiF and 7LiF chips, thermal neutron fluxes from 1 to 2.3 cm(-2) s(-1) are calculated using the assumption that the maximum induced dose in TLD600 for 1 neutron cm(-2) is 1.6 x 10-(10) Gy (Horrowitz and Freeman, Nucl. Instr. and Meth. 157 (1978) 393). It is assumed that the flux of high-energy neutrons is at least of that quantity. Tissue doses were calculated taking as a mean ambient absorbed dose per neutron 6 x 10(-12) Gy cm(2) (for a 10 MeV neutron). The neutron equivalent doses for the above-mentioned fluxes are 52 mu Gy d(-1) and 120 mu Gy d(-1). In recent experiments, a personal neutron dosimeter was integrated into the dosimeter packages. First results of this dosimeter which is based on nuclear track detectors with converter foils are reported. For future measurements, a scintillator counter with anticoincidence logic is under development. (C) 2001 Elsevier Science Ltd. All rights reserved. [References: 13]
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机译:在太阳周期的不同阶段,由热致发光探测器(TLD),核乳剂和塑料径迹探测器组成的探测器组件暴露在MIR空间站内的相同位置以及Spacelab和Spacehab内部的航天飞机飞行中。研究的目的是提供有关重离子的电荷和能谱的数据,以及低能量沉积的事件(质子,电子,γ等)对剂量的贡献,以及二次离子的贡献,例如核分裂星和中子。对于中子剂量测定(LiF)-Li-6(TLD600)和(LiF)-Li-7(TLD700)芯片,它们对伽玛射线的响应几乎相同,但对中子的响应却不同。太空中子的产生主要是通过蒸发和连锁过程产生的,能量分别主要为1-10 MeV和高达100 MeV。能量谱在衰减材料中朝着更大的深度连续变化,直到达到平衡为止。在平衡状态下,光谱是一个宽的连续谱,向下延伸到(LiF)-Li-6敏感的热能。根据6LiF和7LiF芯片中吸收剂量的差异,使用1个中子cm(-2)在TLD600中的最大诱导剂量的假设来计算从1到2.3 cm(-2)s(-1)的热中子通量)为1.6 x 10-(10)Gy(Horrowitz和Freeman,Nucl.Instr。and Meth.157(1978)393)。假定高能中子的通量至少为该量。计算组织剂量为每个中子6 x 10(-12)Gy cm(2)的平均环境吸收剂量(对于10 MeV中子)。上述通量的中子当量剂量为52μGy d(-1)和120μGy d(-1)。在最近的实验中,将个人中子剂量计集成到剂量计包装中。据报道该剂量计的初步结果是基于带有转换箔的核径迹探测器。对于未来的测量,具有反符合逻辑的闪烁计数器正在开发中。 (C)2001 Elsevier ScienceLtd。保留所有权利。 [参考:13]
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