Nikoobakht, B.
(2025),
Evidence for a geometry-dependent bandgap energy and heat accumulation in low-dimensional optical cavities, Nanophotonics, [online], https://doi.org/10.1117/1.JNP.19.042204, https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=959223
(Accessed October 16, 2025)
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Evidence for a geometry-dependent bandgap energy and heat accumulation in low-dimensional optical cavities
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Abstract
Within an optical nanocavity, the temperature dependence of the emission wavelength defines its emission energy stability. Thermal management, therefore, is crucial in controlling wavelength drift and/or radiative recombination rates, especially in electrically driven light sources. Our results show that heat accumulation in a nanocavity directly depends on its geometry, orientation, and interface area with the underlying substrate. We use the temperature dependence of the bandgap to compare the heat retention in nanocavities with lateral and standing orientations. For this purpose, we compare lateral nanofins (fins) and free-standing nanopillars, a.k.a., nanowires (NWs). Hyperspectral cathodoluminescence (CL) microscopy is used to monitor the temperature dependence of the bandgap. Results show that the emission energy of a lateral nanocavity is less dependent on temperature variation compared with that of a standing one. This variation in temperature dependence is attributed to the extent of heat accumulation in the lattice. It is shown that the retained heat in a nanocavity depends on its interface area with the underlying substrate and its surface-to-volume ratio, where the former is the predominant factor. Theoretical modeling shows that introducing a short heat pulse to a standing-nanostructure results in a rapid temperature increase. The initial heating is due to the ultrafast phonon–phonon couplings and build-up of lattice heat. By increasing the interface area between the nanostructure and the substrate, the temperature spike disappeared. Results show the interface area has a far more important contribution than a larger surface-to-volume ratio in heat dissipation. These findings are particularly significant in thermal management of electrically driven optical nanocavities, where operating temperatures could exceed 350 K. As such, although the design and fabrication of efficient nanocavities are essential, controlling their thermal interactions with the surrounding is equally important. Interfacial engineering thus plays a vital role in developing built-in mechanisms for realization of efficient and stable nanoscale light sources.Citation
Nanophotonics
Volume
15
Issue
4
Pub Type
Journals
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Keywords
AlGaN, fin, light-emitting diode, nanoLED, optical cavity, cathodoluminescence
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Created June 18, 2025, Updated September 30, 2025