Design of CoNi alloy/graphene as an efficient Pt-free counter electrode in liquid junction photovoltaic devices

[Display omitted] •Bimetallic CoNi nanoparticles/reduced graphene oxide are prepared by dry plasma reduction.•The electrocatalytic activity as well as electric conductivity is significantly enhanced.•The highest efficiency is recorded from device employed Co0.3Ni0.7/reduced graphene oxide counter el...

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Bibliographic Details
Published inSynthetic metals Vol. 230; pp. 97 - 104
Main Authors Park, Eunhee, Lee, Yoojin, Dao, Van-Duong, Cam, Nguyen Thi Dieu, Choi, Ho-Suk
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 01.08.2017
Elsevier BV
Subjects
Alloys
Charge transfer
Chemical composition
Cobalt
CoNi alloy
Counter electrode
Devices
Diffusion
Dry plasma reduction
Dye-sensitized solar cell
Dye-sensitized solar cells
Electrodes
Graphene
Optimization
Photovoltaic cells
Reduce graphene oxide
Synthesis
CoNi alloy
Dye-sensitized solar cell
Reduce graphene oxide
Dry plasma reduction
Counter electrode
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Summary:[Display omitted] •Bimetallic CoNi nanoparticles/reduced graphene oxide are prepared by dry plasma reduction.•The electrocatalytic activity as well as electric conductivity is significantly enhanced.•The highest efficiency is recorded from device employed Co0.3Ni0.7/reduced graphene oxide counter electrode.•The strategy is for Pt-free counter electrode in PV-device using bimetallic CoNi nanoparticles/reduced graphene oxide. CoxNi1-x alloys (0≤x≤1) are successfully synthesized and immobilized on a reduced graphene oxide (RGO) surface using the dry plasma reduction method. HRSEM and XPS measurements are used to analyze the morphology and chemical composition of the developed materials. Then, the developed materials are applied as Pt-free counter electrodes (CEs) in liquid junction photovoltaic devices. In order to obtain efficient CEs, the chemical composition of the CoxNi1-x/RGO is controlled through optimizing the volume ratio of the Co and Ni precursors during the synthesizing process. It is found that the highest efficiency was 6.75% for the device using Co0.3Ni0.7/RGO CE, which is also higher than those of the devices using Pt CE (6.63%), Co/RGO (6.33%), and Ni/RGO (5.52%). The obtained results can be explained through the optimization of the charge-transfer resistance and diffusion impedance values of the developed materials. The strategy is simple and efficient; thus, it is promising for fabricating cost-effective CE materials for dye-sensitized solar cells.
ISSN:0379-6779
1879-3290
DOI:10.1016/j.synthmet.2017.06.002