Compacted stainless steel mesh-supported Co3O4 porous nanobelts for HCHO catalytic oxidation and Co3O4@Co3S4 via in situ sulfurization as platinum-free counter electrode for flexible dye-sensitized solar cells

[Display omitted] •Co3O4 porous nanobelts were fabricated on the compacted stainless steel mesh (CSSM).•Co3O4/CSSM exhibits stronger catalytic activity and stability for HCHO oxidation.•Co3O4/CSSM is converted to Co3O4@Co3S4 via in-situ sulfurization for various periods.•Co3O4@Co3S4 acts as counter...

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Bibliographic Details
Published in:Applied surface science 2021-01, Vol.536, p.147815, Article 147815
Main Authors: Li, Zhengdao, Chen, Liang, Yang, Qichao, Yang, Hao, Zhou, Yong
Format: Article
Language:English
Subjects:
Catalytic oxidation
Co3O4@Co3S4
Compacted stainless steel mesh
Counter electrode
In situ sulfurization
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Summary:[Display omitted] •Co3O4 porous nanobelts were fabricated on the compacted stainless steel mesh (CSSM).•Co3O4/CSSM exhibits stronger catalytic activity and stability for HCHO oxidation.•Co3O4/CSSM is converted to Co3O4@Co3S4 via in-situ sulfurization for various periods.•Co3O4@Co3S4 acts as counter electrode of flexible dye-sensitized solar cell (FDSSC).•Optimized Co3O4@Co3S4 based FDSSCs get higher efficiency than that of sputtered Pt. Noble metal Pt is usually employed as the effective catalyst for HCHO oxidation and counter electrode (CE) of dye-sensitized solar cell (DSSC), but its low reserve and high cost inspire the exploration of more efficient and low-cost alternatives. In this study, first, Co3O4 porous nanobelts were directly grown on compacted stainless steel mesh (CSSM) by simple hydrothermal method with post heat-treatment. Due to the synergistic effect of Co3O4 and flexible substrate, this immobilized Co3O4 exhibited stronger catalytic activity and stability for HCHO oxidation compared to powdered Co3O4 with similar morphology; Second, the immobilized Co3O4 film was converted to Co3O4@Co3S4 porous nanobelts film via in-situ sulfurization reaction for various periods. The obtained Co3O4@Co3S4 was used as the CE of flexible DSSCs, and a maximum power conversion efficiency of 5.30% was achieved, which was higher than that of the DSSC with a sputtered Pt CE (5.23%). Furthermore, the FDSSCs using this CE still preserved over 93% of its initial conversion efficiency after consecutive bending tests with different angles and 15-day aging test. The excellent electrocatalytic activity, mechanical and long-term stability and low material cost of the optimized Co3O4@Co3S4 electrode provide it with promising potential application as CE of FDSSCs.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2020.147815