Operational Performance of a Photonic Based Microcalorimeter: Specific Heat Measurement

Volume 8: Fluids Engineering; Heat Transfer and Thermal Engineering Pub Date : 2022-10-30 DOI:10.1115/imece2022-95148

Yuwei Zhang, G. Kowalski

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Abstract

A photonic-based nanohole array sensor microcalorimetry is developed at the Microfluidic laboratory at Northeastern University utilizing changes in the extraordinary optical transmission (EOT). This experiment utilized calorimetry to conduct a novel specific heat measurement method for non-reacting fluids on the microscale level. This paper describes a calibration process and an accuracy test for this novel calorimetry. The test chamber was prefilled with deionized (DI) water (55 μl) and heated to steady state. Then room temperature DI water (15 μl) was injected and was treated as an unknown material. The temperature time history is recorded by the thermistor data acquisition system and the EOT by a CCD camera. An energy balance equation and algorithm were developed to calculate the specific heat of the injected material which was compared with its known value. The observed EOT and the corresponding temperature calculated from it exhibit the same trends. The error between the measured and known specific heat specific is 2–6%. The calorimetry has a significantly faster thermal response than traditional calorimeters and requires less compound with high accuracy.

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光子微热量计的工作性能:比热测量

东北大学微流体实验室利用超光传输(EOT)的变化，开发了一种基于光子的纳米孔阵列传感器微热法。本实验利用量热法在微尺度上对非反应流体进行比热测量。本文描述了这种新型量热仪的校准过程和精度测试。实验室内预充去离子水(55 μl)，加热至稳态。然后注入室温DI水(15 μl)，作为未知物质处理。温度时程由热敏电阻数据采集系统记录，EOT由CCD摄像机记录。建立了能量平衡方程和算法，计算了注射材料的比热，并与已知比热进行了比较。观测到的EOT和由此计算出的相应温度表现出相同的趋势。所测比热比与已知比热比的误差为2-6%。与传统的量热仪相比，该量热仪的热响应速度明显快于传统的量热仪。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Volume 8: Fluids Engineering; Heat Transfer and Thermal Engineering

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