Your search keyword '"Moran Ethan"' showing total 2 results

1. High albedo daytime radiative cooling for enhanced bifacial PV performance

Author

Kim Hannah, Gao Yiwei, Moran Ethan, Howle Annyn, McSherry Sean, Cira Spencer, and Lenert Andrej

Subjects

radiative cooling, ground albedo, bifacial, photovoltaics, Physics, QC1-999

Abstract

We present a radiative cooling material capable of enhancing albedo while reducing ground surface temperatures beneath fielded bifacial solar panels. Electrospinning a layer of polyacrylonitrile nanofibers, or nanoPAN, onto a polymer-coated silver mirror yields a total solar reflectance of 99 %, an albedo of 0.96, and a thermal emittance of 0.80. The combination of high albedo and high emittance is enabled by wavelength-selective scattering induced by the hierarchical morphology of nanoPAN, which includes both thin fibers and bead-like structures. During outdoor testing, the material outperforms the radiative cooling power of a state-of-the-art control by ∼20 W/m2 and boosts the photocurrent produced by a commercial silicon cell by up to 6.4 mA/cm2 compared to sand. These experiments validate essential characteristics of a high-albedo radiative-cooling reflector with promising potential applications in thermal and light management of fielded bifacial panels.

Published

2023

2. High albedo daytime radiative cooling for enhanced bifacial PV performance.

Author

Kim, Hannah, Gao, Yiwei, Moran, Ethan, Howle, Annyn, McSherry, Sean, Cira, Spencer, and Lenert, Andrej

Subjects

ALBEDO, PHOTOVOLTAIC power systems, SOLAR panels, COOLING, EARTH temperature, SURFACE temperature, PHOTOCATHODES

Abstract

We present a radiative cooling material capable of enhancing albedo while reducing ground surface temperatures beneath fielded bifacial solar panels. Electrospinning a layer of polyacrylonitrile nanofibers, or nanoPAN, onto a polymer-coated silver mirror yields a total solar reflectance of 99 %, an albedo of 0.96, and a thermal emittance of 0.80. The combination of high albedo and high emittance is enabled by wavelength-selective scattering induced by the hierarchical morphology of nanoPAN, which includes both thin fibers and bead-like structures. During outdoor testing, the material outperforms the radiative cooling power of a state-of-the-art control by ∼20 W/m2 and boosts the photocurrent produced by a commercial silicon cell by up to 6.4 mA/cm2 compared to sand. These experiments validate essential characteristics of a high-albedo radiative-cooling reflector with promising potential applications in thermal and light management of fielded bifacial panels. [ABSTRACT FROM AUTHOR]

Published

2024