Thickness-dependent radiative properties of Y-Ba-Cu-O thin films
Abstract
Some applications of high-temperature superconductors where their radiative behavior is important, such as bolometers, optically triggered switches and gates, and space-cooled electronics, require the superconductor to be in the form of a very thin film whose radiative properties cannot be adequately represented by a semi-infinite analysis. Two properties of particular importance are the film absorptance and the combined film/substrate absorptance, which are crucial to the operation of many devices. Here, calculations of the spectral, normal-incidence absorptance of superconducting-state Y-Ba-Cu-O films on MgO substrates suggest that a decrease in the film thickness often leads to an increase in both the film and the film/substrate absorptance. Furthermore, both can exhibit a maximum of some optimal value of film thickness. Room-temperature experiments verify the qualitative features of the spectral film/substrate absorptance, indicating the assumption that the film is a smooth, continuous slab with a refractive index equal to that of well-aligned bulk Y-Ba-Cu-O is valid, at least in the normal state and for films as thin as 35 nm.
- Publication:
-
ASME Journal of Heat Transfer
- Pub Date:
- February 1992
- Bibcode:
- 1992ATJHT.114..227P
- Keywords:
-
- Copper Oxides;
- Film Thickness;
- High Temperature Superconductors;
- Radiation Absorption;
- Superconducting Films;
- Thin Films;
- Barium Oxides;
- Magnesium Oxides;
- Optical Switching;
- Substrates;
- Yttrium Oxides;
- Solid-State Physics