Hybrid Perovskite‐Photovoltaic and Solar‐Thermal Harvesting
Huang, Gan
1; Arya, Parth H. 1; Ritzer, David B.
1,2; Alati, Nada A. 1; Abdollahi Nejand, Bahram 1,2; Paetzold, Ulrich W.
1,2; Richards, Bryce S.
1,2
1 Institut für Mikrostrukturtechnik (IMT), Karlsruher Institut für Technologie (KIT)
2 Lichttechnisches Institut (LTI), Karlsruher Institut für Technologie (KIT)
1; Arya, Parth H. 1; Ritzer, David B.
1,2; Alati, Nada A. 1; Abdollahi Nejand, Bahram 1,2; Paetzold, Ulrich W.
1,2; Richards, Bryce S.
1,21 Institut für Mikrostrukturtechnik (IMT), Karlsruher Institut für Technologie (KIT)
2 Lichttechnisches Institut (LTI), Karlsruher Institut für Technologie (KIT)
Abstract:
Single-junction photovoltaics have inherent limitations as low-energy photons
below bandgap cannot generate electrical power, wasting solar energy. Here, a
hybrid solar energy harvesting concept is presented. The prototype’s core
component consists of a semi-transparent perovskite solar module that
converts high-energy solar photons into electrical power at 14.3% efficiency,
while directing ≈55% of the low-energy photons below bandgap to a
solar-thermal collector. The prototype can achieve an overall exergy efficiency
of ≈30.0%, with exergy referring to the usefulness of transformed solar energy
and its potential to do work. This high efficiency comes from 1) photovoltaic
conversion, 2) low-temperature heat generation (60 °C) from photovoltaic
thermalization losses, and 3) high-temperature heat generation (900 °C) from
the low-energy photons in a modeled large-scale high-concentration-ratio
solar concentrator. The exergy efficiency can advance to >40% if using a
record-efficiency perovskite photovoltaic. Overall, this study provides a
high-efficiency solution for harvesting the full solar spectrum.
below bandgap cannot generate electrical power, wasting solar energy. Here, a
hybrid solar energy harvesting concept is presented. The prototype’s core
component consists of a semi-transparent perovskite solar module that
converts high-energy solar photons into electrical power at 14.3% efficiency,
while directing ≈55% of the low-energy photons below bandgap to a
solar-thermal collector. The prototype can achieve an overall exergy efficiency
of ≈30.0%, with exergy referring to the usefulness of transformed solar energy
and its potential to do work. This high efficiency comes from 1) photovoltaic
conversion, 2) low-temperature heat generation (60 °C) from photovoltaic
thermalization losses, and 3) high-temperature heat generation (900 °C) from
the low-energy photons in a modeled large-scale high-concentration-ratio
solar concentrator. The exergy efficiency can advance to >40% if using a
record-efficiency perovskite photovoltaic. Overall, this study provides a
high-efficiency solution for harvesting the full solar spectrum.
| Zugehörige Institution(en) am KIT | Institut für Mikrostrukturtechnik (IMT) Lichttechnisches Institut (LTI) |
| Publikationstyp | Zeitschriftenaufsatz |
| Publikationsjahr | 2025 |
| Sprache | Englisch |
| Identifikator | ISSN: 2198-3844 KITopen-ID: 1000185421 |
| HGF-Programm | 38.01.04 (POF IV, LK 01) Modules, Stability, Performance and Specific Applications |
| Erschienen in | Advanced Science |
| Verlag | Wiley Open Access |
| Vorab online veröffentlicht am | 24.09.2025 |
| Nachgewiesen in | Web of Science OpenAlex Dimensions Scopus |