Merging Biology and Photovoltaics: How Nature Helps Sun‐Catching

Cavinato, Luca M.; Fresta, Elisa; Ferrara, Sara; Costa, Rubén D.

doi:10.1002/aenm.202100520

Cited by 21 publications

(21 citation statements)

References 418 publications

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“…At this time, the application of some biologically derived materials with polar groups into ETL has aroused the interest of scientists, mainly because they can improve the morphology of the deposited perovskite, increase the grain size, and reduce the surface defects. In addition, these materials can modify the ETL/perovskite heterojunction interface and increase the charge extraction efficiency ( Cavinato et al, 2021 ). Table 4 summarizes the performance of PSCs prepared by several typical biological materials.…”

Section: Biological Materialsmentioning

confidence: 99%

“…Catecholamine is rich in functional groups and can effectively functionalize the surface of the film. It has been successfully used in supercapacitor and drug delivery of biological therapy ( Cavinato et al, 2021 ). Moreover, carotenoids, as natural organic pigments, are ideal substitutes for p-type semiconductors.…”

Section: Biological Materialsmentioning

confidence: 99%

“…In conclusion, due to the abundant functional groups in bio-derived materials, they can help common ETL materials to efficiently collect and transport charges, and PSCs devices modified with these materials achieve better performance ( Cavinato et al, 2021 ). Moreover, in addition to the performance enhancement, these modifications can also promote the improvement of device stability, which is crucial for the commercial production of PSCs.…”

Section: Biological Materialsmentioning

confidence: 99%

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Advances of Commercial and Biological Materials for Electron Transport Layers in Biological Applications

Yin

Chen

et al. 2022

Front. Bioeng. Biotechnol.

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Electron transport layer (ETL), one of the important layers for high-performing perovskite solar cells (PSCs), also has great potential in bioengineering applications. It could be used for biological sensors, biological imaging, and biomedical treatments with high resolution or efficiency. Seldom research focused on the development of biological material for ETL and their application in biological uses. This review will introduce commercial and biological materials used in ETL to help readers understand the working mechanism of ETL. And the ways to prepare ETL at low temperatures will also be introduced to improve the performance of ETL. Then this review summarizes the latest research on material doping, material modification, and bilayer ETL structures to improve the electronic transmission capacity of ETLs. Finally, the application of ETLs in bioengineering will be also shown to demonstrate that ETLs and their used material have a high potential for biological applications.

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Section: Biological Materialsmentioning

confidence: 99%

Section: Biological Materialsmentioning

confidence: 99%

Section: Biological Materialsmentioning

confidence: 99%

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Advances of Commercial and Biological Materials for Electron Transport Layers in Biological Applications

Yin

Chen

et al. 2022

Front. Bioeng. Biotechnol.

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“…Obwohl die Photosynthese insgesamt kein besonders energieeffizienter Prozess ist, [2] finden die primären Vorgänge der Energieübertragung beim Einfangen des Lichts und der Ladungstrennung bei der Energiestabilisierung mit sehr hohen Quanteneffizienzen statt (Vorgänge pro absorbiertem Photon) [3] . Die biomolekularen Grundlagen dieser hohen Effizienz haben das Design von künstlichen Materialien für die nachhaltige Umwandlung von Lichtenergie beeinflusst, [3, 4] und auch das Interesse an der direkten Integration photosynthetischer Komplexe in biohybride technische Anwendungen gestärkt [5–8] …”

Section: Einführungunclassified

Stabilisierung von Elektronentransferwegen erlaubt Stabilität von Biohybrid‐Photoelektroden über Jahre

Friebe

Barszcz²,

Jones

et al. 2022

Angewandte Chemie

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Die Nutzung natürlicher photosynthetischer Enzyme in biohybriden Anwendungen stellt eine attraktive und potenziell nachhaltige Möglichkeit zur Umwandlung von solarer Energie in Elektrizität und Brennstoffe dar. Jedoch begrenzt die Stabilität von photosynthetisch aktiven Proteinen nach der Implementierung in biohybride Anwendungsdesigns die operative Lebensdauer von Biophotoelektroden auf bisher wenige Stunden. In dieser Publikation demonstrieren wir, wie sich die Stabilität einer mesoporösen Elektrode, welche mit dem Photoprotein RC-LH1 aus Rhodobacter sphaeroides beschichtet ist, erheblich steigern lässt. Durch die Aufrechterhaltung der Elektronenübertragungswege konnte die operative Lebensdauer unter Dauerlicht auf 33 Tage gesteigert werden und die operative Funktionalität nach einer Lagerung über mehr zwei Jahre hinweg demonstriert werden. Kombiniert mit hohen Photoströmen, die Spitzenwerte von 4.6 mA cm À 2 erreichten, erzeugte die optimierte Biophotoelektrode eine kumulative Leistung von 86 C cm À 2 , die höchste bisher berichtete Leistung für diese Art von Elektroden. Unsere Ergebnisse zeigen, dass der Faktor, welcher die Stabilität einschränkt, die Architektur der Struktur ist, die das Photoprotein umgibt, sowie das entsprechende biohybride Sensoren und photovoltaische Geräte mit einer Betriebsdauer von mehreren Jahren möglich sind.

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“…Although photosynthesis overall is not a particularly energy‐efficient process, [2] the primary events of energy transfer during light capture, and charge separation during energy stabilization, take place with very high quantum efficiencies (events per photon absorbed) [3] . The deduced biomolecular origins of this high efficiency have guided the design of man‐made materials for sustainable solar energy conversion, [3, 4] and also driven interest in the direct integration of photosynthetic complexes in biohybrid technological devices [5–8] …”

Section: Introductionmentioning

confidence: 99%

Sustaining Electron Transfer Pathways Extends Biohybrid Photoelectrode Stability to Years

Friebe

Barszcz²,

Jones

et al. 2022

Angew Chem Int Ed

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The exploitation of natural photosynthetic enzymes in semi-artificial devices constitutes an attractive and potentially sustainable route for the conversion of solar energy into electricity and solar fuels. However, the stability of photosynthetic proteins after incorporation in a biohybrid architecture typically limits the operational lifetime of biophotoelectrodes to a few hours. Here, we demonstrate ways to greatly enhance the stability of a mesoporous electrode coated with the RC-LH1 photoprotein from Rhodobacter sphaeroides. By preserving electron transfer pathways, we extended operation under continuous high-light to 33 days, and operation after storage to over two years. Coupled with large photocurrents that reached peak values of 4.6 mA cm À 2 , the optimized biophotoelectrode produced a cumulative output of 86 C cm À 2 , the largest reported performance to date. Our results demonstrate that the factor limiting stability is the architecture surrounding the photoprotein, and that biohybrid sensors and photovoltaic devices with operational lifetimes of years are feasible.

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Merging Biology and Photovoltaics: How Nature Helps Sun‐Catching

Cited by 21 publications

References 418 publications

Advances of Commercial and Biological Materials for Electron Transport Layers in Biological Applications

Advances of Commercial and Biological Materials for Electron Transport Layers in Biological Applications

Stabilisierung von Elektronentransferwegen erlaubt Stabilität von Biohybrid‐Photoelektroden über Jahre

Sustaining Electron Transfer Pathways Extends Biohybrid Photoelectrode Stability to Years

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