Abstract: With the aim to improve the reliability of calculating and thus predicting the thermal deformation of cryogenically cooled silicon monochromators for intense synchrotron x-ray beams, we have measured the thermal conductivity of several specimen with different purities: float zone (FZ), Czochralski (CZ) single crystal materials and a Si$-99.3$/Ge$-0.7$/ (SG) crystal between 85 K and room temperature with 1% accuracy. We have shown by finite element analysis that a measured 30% increase of conductivity between the FZ and the CZ crystals leads to an increase of 30 to 40% of the thermal slope. Whereas the performances of these two materials were just acceptable, the 9 times reduced thermal conductivity of the SG crystal turned out to increase the thermal slope error by a factor 19 to a prohibitive value of 143 $mu@rad, as compared to 7.6 $mu@rad for the FZ crystal. Therefore, the application of SG crystals to cryogenic cooling cannot be recommended. In addition, we determined the thermal conductivity of germanium single crystals in the same temperature range. For the silicon FZ and the germanium materials, excellent agreement with recommended values was found. Moreover, we detected a small, but non-negligible dependence of thermal conductivity on the crystallographic direction (a few % at 85 K) that, to our knowledge, has not been published in previous papers. !17
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机译:摘要:为了提高计算的可靠性,并由此预测用于强同步加速器X射线的深冷硅单色仪的热变形,我们测量了几种不同纯度的样品的热导率:浮区(FZ),切克劳斯基(Czochralski) (CZ)单晶材料和Si $ -99.3 $ / Ge $ -0.7 $ /(SG)晶体,在85 K和室温之间,精度为1%。我们已经通过有限元分析表明,在FZ和CZ晶体之间测得的电导率增加了30%,导致热斜率增加了30%至40%。尽管这两种材料的性能是可以接受的,但SG晶体的热导率降低了9倍,导致热斜率误差增加了19倍,达到了143 $ mu @ rad的禁止值,而7.6 $ mu @rad为FZ晶体。因此,不推荐将SG晶体应用于低温冷却。此外,我们确定了在相同温度范围内锗单晶的热导率。对于硅FZ和锗材料,发现与推荐值具有极好的一致性。此外,据我们所知,我们发现导热系数对晶体学方向的依赖性很小(但不可忽略)(在85 K时为几%),而在先前的论文中尚未发表。 !17
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