مرکز منطقه ای اطلاع رساني علوم و فناوري - Photoelectronic Responses in Solution-Processed Perovskite CH<inline-formula> <img src="/images/tex/20448.gif" alt="_{\\bf 3}"> </inline-formula>NH<inline-formula> <img src="/images/tex/20074.gif" alt="_{\\bf 3}"> </inline-formula>PbI<inline-formula> <img

Title :

Photoelectronic Responses in Solution-Processed Perovskite CH $_{\\bf 3}$ NH $_{\\bf 3}$ PbI

Author :

Yamada, Y. ; Nakamura, T. ; Endo, Miyuki ; Wakamiya, Atsushi ; Kanemitsu, Yoshihiko

Author_Institution :

Inst. for Chem. Res., Kyoto Univ., Uji, Japan

Volume :

Issue :

fYear :

2015

fDate :

Jan. 2015

Firstpage :

401

Lastpage :

405

Abstract :

Photoelectronic responses of organic-inorganic hybrid perovskite CH₃NH₃PbI₃ on mesoporous TiO₂ electrodes are investigated. On the basis of near-band-edge optical absorption and photoluminescence spectra, the bandgap energy and exciton binding energy as a function of temperature are obtained. The exciton binding energy is much smaller than thermal energy at room temperature, which means that most excitons are thermally dissociated, and optical processes are determined by the photoexcited electrons and holes. We determined the temperature dependence of exciton binding energy, which changes from ~30 meV at 13 K to 6 meV at 300 K. In addition, the bandgap energy and the exciton binding energy show abrupt changes at 150 K due to structural phase transition. Our fundamental optical studies provide essential information for improving the device performance of solar cells based on halide perovskite semiconductors.

Keywords :

binding energy; dissociation; energy gap; excitons; mesoporous materials; organic semiconductors; photoexcitation; photoluminescence; porous semiconductors; solar cells; solid-state phase transformations; titanium compounds; TiO₂; bandgap energy; device performance; exciton binding energy; halide perovskite semiconductors; mesoporous titania electrodes; near-band-edge optical absorption; optical processes; organic-inorganic hybrid perovskite; photoabsorption spectroscopy; photoelectronic responses; photoexcited electrons; photoexcited holes; photoluminescence spectra; solution-processed perovskite solar cells; structural phase transition; temperature 13 K; temperature 150 K; temperature 300 K; temperature dependence; thermal dissociation; thermal energy; Absorption; Excitons; Optical device fabrication; Optical scattering; Photonic band gap; Photovoltaic cells; Temperature measurement; Photoluminescence; semiconductor devices; solar energy;

fLanguage :

English

Journal_Title :

Photovoltaics, IEEE Journal of

Publisher :

ieee

ISSN :

2156-3381

Type :

jour

DOI :

10.1109/JPHOTOV.2014.2364115

Filename :

6949074

Link To Document :

https://search.ricest.ac.ir/dl/search/defaultta.aspx?DTC=49&DC=29820