Thermal interface materials (TIMs) serve a critical role in the thermal management of electronic systems by enhancing the flow of heat from source to sink. Nanostructured materials, such as arrays of carbon nanotubes (CNTs) have been shown to outperform many commercially available TIMs due to their low intrinsic resistance and large compliance that enables them to conform to rough surfaces. These characteristics, combined with their low density and ability to withstand vacuum environments and extreme temperatures, make CNT-based TIMs very suitable for space applications. In space, materials are exposed to high doses of gamma radiation due to the lack of an atmosphere to serve as an absorbing medium. With typical design lifetimes of 5 to 10 years or even more, total radiation exposure can be significant and can affect the structure and performance of the TIM. In this work, the potentially adverse effects on the thermal performance of CNT TIMs of gamma-ray irradiation is reported. CNT TIMs were irradiated in a gamma cell at a rate of 250 rad/s to total doses of 50 and 100 Mrad. The thermal interface resistance was measured before and after gamma-ray irradiation using a transient photoacoustic (PA) method at room temperature and a contact pressure of 134 kPa and indicated no adverse effects of gamma-ray exposure on thermal performance.
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机译:热界面材料(TIMS)通过增强来自源进入的热量的热管理,在电子系统的热管理中发挥关键作用。已经显示纳米结构材料,例如碳纳米管(CNT)阵列,由于它们的质量耐性低和大规则,使得它们能够符合粗糙表面而优于许多商业上可获得的时间。这些特性与它们的低密度和能力耐受真空环境和极端温度,使基于CNT的TIM非常适合空间应用。在太空中,由于缺乏气氛作为吸收介质,材料暴露于高剂量的γ辐射。典型设计寿命为5至10年甚至更多,总辐射曝光可能很大,并会影响蒂姆的结构和性能。在这项工作中,报道了对γ射线照射CNT频率的潜在不利影响。 CNT TIM以250 rad / s的速率照射在γ细胞中至总剂量为50和100mrad。在室温下使用瞬态光声(PA)方法和134kPa的接触压力,在γ射线照射之前和之后测量热界面电阻,并表明γ射线暴露对热性能的不利影响。
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