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Exploring Graphene Quantum Dots/TiO2 interface in photoelectrochemical reactions: Solar to fuel conversion

Authors
Sudhagar, PitchaimuthuHerraiz-Cardona, IsaacPark, HunSong, TaesupNoh, Seung HyunGimenez, SixtoSero, Ivan MoraFabregat-Santiago, FranciscoBisquert, JuanTerashima, ChiakiPaik, UngyuKang, Yong SooFujishima, AkiraHan, Tae Hee
Issue Date
Jan-2016
Publisher
Pergamon Press Ltd.
Keywords
TiO2; graphene quantum dots; water splitting; solar fuel; photoelectrochemical; charge transfer
Citation
Electrochimica Acta, v.187, pp 249 - 255
Pages
7
Indexed
SCI
SCIE
SCOPUS
Journal Title
Electrochimica Acta
Volume
187
Start Page
249
End Page
255
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/24086
DOI
10.1016/j.electacta.2015.11.048
ISSN
0013-4686
1873-3859
Abstract
Photocarrier (e(-)/ h(+)) generation at low dimension graphene quantum dots offers multifunctional applications including bioimaging, optoelectronics and energy conversion devices. In this context, graphene quantum dots onto metal oxide electron transport layer finds great deal of attention in solar light driven photoelectrochemical (PEC) hydrogen fuel generation. The merits of combining tailored optical properties of the graphene quantum dots sensitizer with the transport properties of the host wide band gap one dimensional nanostructured semiconductor provide a platform for high charge collection which promotes catalytic proton reduction into fuel generation at PEC cells. However, understanding the underlying mechanism of photocarrier transfer characteristics at graphene quantum dots/metal oxide interface during operation is often difficult as graphene quantum dots may have a dual role as sensitizer and catalyst. Therefore, exploring photocarrier generation and injection at graphene quantum dot/metal oxide heterointerfaces in contact with hole scavenging electrolyte afford a new pathway in developing graphene quantum dots based photoelectrochemical fuel generation systems. In this work, we demonstrate direct assembly of surface modified graphene quantum dots (similar to 2 nm particle size) onto TiO2 hollow nanowire (similar to 3 mm in length and similar to 100 to 250 nm in diameter) by electrostatic attraction and examine the photocarrier accumulation and recombination processes leading to device operation. Optical characterization reveals that GQDs absorbed light photons at visible light wavelength up to 600 nm. Hybrid TiO2-GQDs heterostructures show a photocurrent enhancement of similar to 70% for water oxidation compared to pristine TiO2 using sacrificial-free electrolyte, which is further validated by incident photon to current efficiency. Additionally, the charge accumulation processes and charge transfer characteristics are investigated by electrochemical impedance spectroscopy. These results provide the platform to understand the insights of graphene quantum dots/metal oxide interfaces in PEC reactions and discuss the feasibility of graphene quantum dots in wide range of electrochemical and photoelectrochemical based fuel conversion devices.
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서울 공과대학 > 서울 유기나노공학과 > 1. Journal Articles
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