A thermocouple of Au-Ni with only 2.5-μm-wide electrodes on a 30-nm-thick Si3N4 membrane was fabricated by a simple low-resolution electron beam lithography and lift off procedure. The thermocouple is shown to be sensitive to heat generated by laser as well as an electron beam. Nano-thin membrane was used to reach a high spatial resolution of energy deposition and to realise a heat source of sub-1 μm diameter. This was achieved due to a limited generation of secondary electrons, which increase a lateral energy deposition. A low thermal capacitance of the fabricated devices is useful for the real time monitoring of small and fast temperature changes, e.g., due to convection, and can be detected through an optical and mechanical barrier of the nano-thin membrane. Temperature changes up to ~2?×?105 K/s can be measured at 10?kHz rate. A simultaneous down-sizing of both, the heat detector and heat source strongly required for creation of thermal microscopy is demonstrated. Peculiarities of Seebeck constant (thermopower) dependence on electron injection into thermocouple are discussed. Modeling of thermal flows on a nano-membrane with presence of a micro-thermocouple was carried out to compare with experimentally measured temporal response.
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机译:通过简单的低分辨率电子束光刻和剥离工艺,在厚度仅为30 nm的Si3N4膜上制备了仅具有2.5μm宽电极的Au-Ni热电偶。显示热电偶对激光以及电子束产生的热量敏感。纳米薄膜被用来达到能量沉积的高空间分辨率,并实现小于1μm直径的热源。这是由于产生有限的二次电子而实现的,这增加了横向能量沉积。所制造的器件的低热电容可用于实时监测例如由于对流引起的小而快速的温度变化,并且可以通过纳米薄膜的光学和机械屏障来检测。可以以10kHz的速率测量高达〜2?×?105 K / s的温度变化。演示了同时缩小热检测器和热源的尺寸,这是创建热显微镜的必要条件。讨论了塞贝克常数(热功率)对电子注入热电偶的特殊性。在存在微热电偶的情况下,对纳米膜上的热流进行了建模,以与实验测得的时间响应进行比较。
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