Intercalative and non-intercalative photo-recharge using all-solid-state cells for solar energy conversion and storage

Photo-rechargeable systems, which can efficiently convert and store solar energy into chemical energy within single devices, are essential to harness sunlight effectively. Photo-(de)intercalation plays a pivotal role in the functionality of photo-rechargeable systems. Nevertheless, the photo-(de)int...

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Bibliographic Details
Published in:Sustainable energy & fuels 2024-03, Vol.8 (6), p.1236-1244
Main Authors: Yoshimoto, Masataka, Tamura, Kazuhisa, Watanabe, Kenta, Shimizu, Keisuke, Horisawa, Yuhei, Kobayashi, Takeshi, Tsurita, Hanae, Suzuki, Kota, Kanno, Ryoji, Hirayama, Masaaki
Format: Article
Language:English
Subjects:
Anatase
Batteries
Charging
Chemical energy
Decomposition reactions
Electrode materials
Electrolytes
Electrolytic cells
Electron transfer
Energy conversion
Energy storage
Epitaxial growth
Intercalation
Irradiation
Light irradiation
Radiation
Side reactions
Solar energy
Solar energy conversion
Solid state
Storage batteries
Supercapacitors
Thin films
Titanium dioxide
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Summary:Photo-rechargeable systems, which can efficiently convert and store solar energy into chemical energy within single devices, are essential to harness sunlight effectively. Photo-(de)intercalation plays a pivotal role in the functionality of photo-rechargeable systems. Nevertheless, the photo-(de)intercalation process has not been conclusively confirmed owing to potential interference from side reactions, such as the decomposition of liquid electrolytes and the elution of electrode materials. In this study, we successfully demonstrated photo-responsive Li + -deintercalation using an all-solid-state thin-film battery composed of epitaxially grown anatase TiO 2 doped with Nb (a-TiO 2 :Nb) as the cathode, in combination with operando X-ray diffractometry. Under light irradiation, Li + -deintercalation occurred and was subsequently reversibly intercalated into a-TiO 2 :Nb during discharge. Furthermore, it was observed that a portion of the charge capacity under light irradiation resulted from non-intercalative (non-redox-reactive) electron transfer, akin to supercapacitors. These findings suggest that both intercalative and non-intercalative photo-charging mechanisms can be applied to secondary batteries and supercapacitors, respectively. Therefore, photo-rechargeable all-solid-state cells, encompassing both secondary batteries and supercapacitors, hold significant promise for advancing solar energy conversion and storage. We have successfully demonstrated both Li + -deintercalative and non-intercalative photo-recharge using a-TiO 2 :Nb/Li 3 PO 4 /Li in an all-solid-state cell and operando X-ray diffractometry.
ISSN:2398-4902
2398-4902
DOI:10.1039/d3se01636f