1.1本指南涵盖了测量多模阶跃折射率石英光纤传输的拉曼光谱信号的实时、原位辐射诱导变化的方法。本指南具体论述了稳态电离辐射（即α、β、γ、质子等），并根据辐射源的不同，适当改变剂量学和屏蔽注意事项。 1.2本指南中给出的测试程序不用于测试光纤的其他光学和非光学组件- 基于拉曼传感器系统，但可以修改为在连续辐照环境中测试其他组件。 1.3以国际单位制表示的数值应视为标准值。本标准不包括其他计量单位。 1.4 本标准并非旨在解决与其使用相关的所有安全问题（如有）。本标准的用户有责任在使用前制定适当的安全和健康实践，并确定监管限制的适用性。 ====意义和用途====== 4.1电离环境将影响用于从远程位置传输光谱信息的光纤/电缆的性能。为了评估光纤传感器系统的性能，必须确定光纤中电离辐射或两者产生的光谱变化或干扰的类型和幅度。 4.2测试结果可作为光纤拉曼光谱传感器系统中使用的光纤的选择标准。 注1 — 当光纤暴露于电离辐射时，其衰减通常会增加。这主要是由于在光学材料的缺陷位置捕获辐射电子和空穴，即形成色心。这些色心通过热或光学（光漂白）过程或两者的结合而减少，会导致恢复，通常会导致辐射诱导衰减的减少。辐照后衰减的恢复取决于许多变量，包括测试样品的温度、样品的成分、使用的光谱和辐射类型、应用于测试样品的总剂量、用于测量衰减的光强和工作光谱。 在某些连续条件下，恢复永远不会完成。

1.1 This guide covers the method for measuring the real time, in situ radiation-induced alterations to the Raman spectral signal transmitted by a multimode, step index, silica optical fiber. This guide specifically addresses steady-state ionizing radiation (that is, alpha, beta, gamma, protons, etc.) with appropriate changes in dosimetry, and shielding considerations, depending upon the irradiation source. 1.2 The test procedure given in this guide is not intended to test the other optical and non-optical components of an optical fiber-based Raman sensor system, but may be modified to test other components in a continuous irradiation environment. 1.3 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use. ====== Significance And Use ====== 4.1 Ionizing environments will affect the performance of optical fibers/cables being used to transmit spectroscopic information from a remote location. Determination of the type and magnitude of the spectral variations or interferences produced by the ionizing radiation in the fiber, or both, is necessary for evaluating the performance of an optical fiber sensor system. 4.2 The results of the test can be utilized as a selection criteria for optical fibers used in optical fiber Raman spectroscopic sensor systems. Note 1 — The attenuation of optical fibers generally increases when they are exposed to ionizing radiation. This is due primarily to the trapping of radiolytic electrons and holes at defect sites in the optical materials, that is, the formation of color centers. The depopulation of these color centers by thermal or optical (photobleaching) processes, or both, causes recovery, usually resulting in a decrease in radiationinduced attenuation. Recovery of the attenuation after irradiation depends on many variables, including the temperature of the test sample, the composition of the sample, the spectrum and type of radiation employed, the total dose applied to the test sample, the light level used to measure the attenuation, and the operating spectrum. Under some continuous conditions, recovery is never complete.