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1. Optimization of GaSb thermophotovoltaic diodes with metallic photonic crystal front-surface filters

   https://doi.org/10.1109/MWSCAS.2017.8053055  

   Licht, Abigail S.; Shemelya, Corey S.; DeMeo, Dante F.; Carlson, Emily S.; Vandervelde, Thomas E. (August 2017, Optimization of GaSb Thermophotovoltaic Diodes with Metallic Photonic Crystal Front-Surface Filters)

   Abstract— A promising technology for waste-heat recovery applications is thermophotovoltaics (TPVs), which use photovoltaic diodes to convert thermal energy into electricity. The most commonly used TPV diode material is gallium antimonide (GaSb). Recently, GaSb TPV diodes were fabricated with front-surface metallic photonic crystal (MPhC) filters to more optimally convert the incident spectrum. This method showed promising initial results, in part due to a shifting of the photogenerated carriers away from the front-surface and into the device. In this paper, we use the Atlas-Silvaco software package to optimize the TPV diode structure for MPhCs. We investigate the addition of an intrinsic region in the device to take advantage of the shifted photogeneration profile from the MPhCs. This design allows for a 10% improvement in internal quantum at the peak MPhC transmission wavelength. https://doi.org/10.1109/MWSCAS.2017.8053055 

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2. Design of Selective Metasurface Filter for Thermophotovoltaic Energy Conversion

   https://doi.org/10.30919/esee999  

   Ramesh, Rajagopalan; Ni, Qing; Alshehri, Hassan; Azeredo, Bruno; Wang, Liping (January 2023, ES Energy & Environment)

   Optical filters with narrow transmission band above the bandgap of thermophotovoltaic (TPV) cells are not restrained by the rigorous thermal reliability as needed for the emitters. In this work, a novel metasurface filter made of an aluminum nanopillar (AlNP) array on a quartz substrate is proposed to achieve spectrally selective transmission above the bandgap of the TPV cell. Optical simulations using Finite-difference time-domain were carefully performed to determine the appropriate AlNP period, diameter, and height such that the resulting nanopillar array will show narrowband transmission at a wavelength of 1.9 μm, which is close to the bandgap of a commercial gallium antimonide (GaSb) TPV cell. The narrow-band transmission enhancement can be attributed to the magnetic polariton (MP) resonance between neighboring Al nanopillars. The MP mechanism is further confirmed by an inductor-capacitor circuit model and the effects of the nanopillars period, diameter, height, as well as incidence angles were discussed. Moreover, open-circuit voltage, short-circuit current density, output electric power, and conversion efficiency were evaluated for the GaSb TPV cell coupled with the AlNP metasurface filter structure with enhanced TPV performance. 

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3. Ultraviolet and Near‐Infrared Dual‐Band Selective‐Harvesting Transparent Luminescent Solar Concentrators

   https://doi.org/10.1002/aenm.202003581  

   Yang, Chenchen; Sheng, Wei; Moemeni, Mehdi; Bates, Matthew; Herrera, Christopher_K; Borhan, Babak; Lunt, Richard_R (February 2021, Advanced Energy Materials)

   Abstract Visibly transparent luminescent solar concentrators (TLSC) can optimize both power production and visible transparency by selectively harvesting the invisible portion of the solar spectrum. Since the primary applications of TLSCs include building envelopes, greenhouses, automobiles, signage, and mobile electronics, maintaining aesthetics and functionalities is as important as achieving high power conversion efficiencies (PCEs) in practical deployment. In this work, massive‐downshifting phosphorescent nanoclusters and fluorescent organic molecules are combined into a TLSC system as ultraviolet (UV) and near‐infrared (NIR) selective‐harvesting luminophores, respectively, demonstrating UV and NIR dual‐band selective‐harvesting TLSCs with PCE over 3%, average visible transmittance (AVT) exceeding 75% and color metrics suitable for the window industry. With distinct wavelength‐selectivity and effective utilization of the invisible portion of the solar spectrum, this work reports the highest light utilization efficiency (PCE × AVT) of 2.6 for a TLSC system, the highest PCE of any transparent photovoltaic (TPV) devices with AVT greater than 70%, and outperforms the practical limit for non‐wavelength‐selective TPV. 

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4. WIDE-BANDGAP SEMICONDUCTORS Gallium Nitride, GaN - Silicon Carbide, SiC

   Michael Haralambous, Chrysanthos Panayiotou (January 2022, WIDE-BANDGAP SEMICONDUCTORS)

   About the LASER-TEC Laser and Fiber Optics Educational Series This series was created for use in engineering technology programs such as electronics, photonics, laser electro-optics, etc. This series of publications has three goals in mind: 1) to create educational materials for areas of laser electro-optics technology in which no materials exist, 2) to work with industry to use, adapt, and enhance available industry-created materials, 3) to make these materials available at no cost which, in turn, would generate more accessible education to everyone (including technicians). The Laser and Fiber Optics Educational Series is available for free online at www.laser-tec.org. About Wide-Bandgap Semiconductors New semiconductors based on silicon carbide (SiC) and gallium nitride (GaN) are now commercially available, which has been instrumental in removing obstacles that legacy silicon bipolar and metal-oxide-semiconductor field-effect transistor (MOSFET) devices could not overcome. These new devices have superior power-handling abilities due to their better thermal properties, higher switching frequencies, and lower conduction losses. Collectively, these properties make wide-bandgap devices the preferred technology for high-power conversion applications with efficiencies approaching 99%. For this reason, this new technology must be introduced to existing curricula, preparing engineers and technicians to tackle today’s and tomorrow’s power electronics challenges. This module is intended for use in technical programs after coverage of basic semiconductor theory and discrete devices such as silicon diodes, bipolar junction, field effect, and MOSFET transistors. 

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5. Semitransparent thermophotovoltaics for efficient utilization of moderate temperature thermal radiation

   https://doi.org/10.1073/pnas.2215977119  

   Lenert, Andrej; Burger, Tobias; Roy-Layinde, Bosun; Lentz, Rebecca; Berquist, Zachary J.; Forrest, Stephen R. (November 2022, Proceedings of the National Academy of Sciences)

   Recent advances in thermophotovoltaic (TPV) power generation have produced notable gains in efficiency, particularly at very high emitter temperatures. However, there remains substantial room for improving TPV conversion of waste, solar, and nuclear heat streams at temperatures below 1,100°C. Here, we demonstrate the concept of transmissive spectral control that enables efficient recuperation of below-bandgap photons by allowing them to transmit through the cell to be absorbed by a secondary emitter. We fabricate a semitransparent TPV cell consisting of a thin InGaAs–InP heterojunction membrane supported by an infrared-transparent heat-conducting substrate. The device absorbs less than 1% of below-bandgap radiation, resulting in a TPV efficiency of 32.5% at an emitter temperature of 1,036°C. To our knowledge, this represents an 8% absolute improvement (~33% relative) in efficiency relative to the best TPV devices at such low temperatures. By enabling near-zero photon loss, the semitransparent architecture facilitates high TPV efficiencies over a wide range of applications. 

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