AI Article Synopsis
- A thermoradiative diode harnesses power by tapping into the thermal emission from Earth and releasing it to the cold night sky, with performance influenced by atmospheric conditions.
- The study models the impact of downwelling radiation, finding power densities ranging from 0.34 to 6.5 W/m² at optimum bandgaps around 0.094 eV.
- The research indicates that limiting emission and absorption angles can slightly enhance power output, but suggests that a higher bandgap diode (around 0.25 eV) is preferable if its efficiency is significantly better than that of the lower bandgap device.
Article Abstract
A thermoradiative diode is a device that can generate power through thermal emission from the warm Earth to the cold night sky. Accurate assessment of the potential power output requires knowledge of the downwelling radiation from the atmosphere. Here, accurate modeling of this radiation is used alongside a detailed balance model of a diode at the Earth's surface temperature to evaluate its performance under nine different atmospheric conditions. In the radiative limit, these conditions yield power densities between 0.34 and 6.5 W.m, with optimal bandgaps near 0.094 eV. Restricting the angles of emission and absorption to less than a full hemisphere can marginally increase the power output. Accounting for non-radiative processes, we suggest that if a 0.094 eV device would have radiative efficiencies more than two orders of magnitude lower than a diode with a bandgap near 0.25 eV, the higher bandgap material is preferred.
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Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11616091 | PMC |
| http://dx.doi.org/10.1016/j.isci.2024.111346 | DOI Listing |
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