We report on a non-interacting technique for thermal characterization of fluids based on surface plasmon resonance interrogation. Using liquid volumes less than 20 micro liters we have determined the materials' thermo-optic coefficients with an accuracy of better than 10^{-5} 1/{\deg}C and demonstrated temperature sensing with an accuracy of 0.03 {\deg}C. The apparatus employs a low-power probe laser, requiring only a single wavelength, polarization and interrogation angle for accurate characterization. The device is particularly suited for precise diagnostics of liquids and gases within microfluidic systems, and may also be readily integrated into a variety of lab-on-chip platforms, providing rapid and accurate temperature diagnostics.
@article{arxiv.1009.4904,
title = {Surface plasmon based thermo-optic and temperature sensor for microfluidic thermometry},
author = {Lawrence Davis and Miriam Deutsch},
journal= {arXiv preprint arXiv:1009.4904},
year = {2015}
}