Carbon Letters 2024 KCI Impact Factor : 0.95 KCI-WoS Impact Factor : 4.74
-
pISSN : 1976-4251 / eISSN : 2233-4998
- https://journal.kci.go.kr/carbon
KJCKorea
Journal Central
rGO@Cu2ZnSnS4 chalcopyrites modified polypyrrole paper-based photoanode for solar water splitting
- Carbon Letters
- Abbr : Carbon Lett.
- 2024, 34(6), pp.1609~1618
- DOI : 10.1007/s42823-024-00708-2
- Publisher : Korean Carbon Society
- Research Area : Natural Science > Natural Science General > Other Natural Sciences General
- Received : December 10, 2023
- Accepted : February 20, 2023
- Published : July 1, 2024
Thakur Anupma 1, Devi Pooja 1
1Academy of Scientific and Innovative Research
Accredited
ABSTRACT
Flexible electrodes, particularly paper electrodes modified with polypyrrole, have shown promise in energy-related applications. We have earlier demonstrated the usage of paper electrodes modified with polypyrrole as a flexible and suitable photoanode for photoelectrochemical water splitting (PEC). Further, modification of this electrode system with an appropriate tandem absorber system for solar fuel production is interesting in developing efficient photoanodes. In this study, we study the PEC performance of flexible polypyrrole-based paper photoanodes (PPy-PAs) by decorating them with rGO@Cu2ZnSnS4 chalcopyrites (rGO@CZTS/PPy-PAs). The lower bandgap (~ 1.5 eV) of the rGO@CZTS/PPy-PAs system allows for efficient visible light absorption, substantially improving PEC water-splitting reactions. The rGO@CZTS/PPy-PAs exhibited an enhanced current density of ~ 13.2 mA/cm2 at 1.23 V vs RHE, ABPE of ~ 1.5%, and a hydrogen evolution rate of 177 μmoles/min/cm2. Overall, rGO@CZTS/PPy-PAs showed 2.1-fold, 1.1-fold, and 1.4-fold enhancement in photocurrent activity over PPy-PAs, CZTS/PPy-PAs, and rGO/PPy-PAs, respectively. The usability of rGO@CZTS/PPy-PAs is established in the form of stable photocurrent for more than 200 min. These findings open new possibilities for developing modified PPy PAs as flexible PEs for efficient solar-driven PEC devices and give directions on improving flexible PEs for flexible and efficient solar-driven PEC systems.
Statistics
-
148 Viewed
-
0 Downloaded
Tools
Issue List
Citation status
* References for papers published after 2024 are currently being built.
[book]
Lambers H
/ 2008
/ Plant physiological ecology
/ Springer
[journal]
Bonke SA
/ 2015
/ Renewable fuels from concentrated solar power : towards practical artificial photosynthesis
/ Energy Environ Sci
8(9)
: 2791~2796
[journal]
Thakur A
/ 2020
/ Current progress and challenges in photoelectrode materials for the production of hydrogen
/ Chem Eng J
397
: 125415~
[journal]
Sharma C
/ 2022
/ Combining experimental and engineering aspects of catalyst design for photoelectrochemical water splitting
/ ECS Adv
1(3)
: 030501~
[journal]
Thakur A
/ 2023
/ Plasmonic copper-activated ZnO microarrays for efficient photoelectrocatalytic applications
/ Chem Asian J
18(3)
: e202201155~
[book]
Thakur A
/ 2021
/ Polymer-based advanced functional composites for optoelectronic and energy applications
/ Elsevier
: 195~213
[journal]
Thakur A
/ 2021
/ Flexible polypyrrole activated micro-porous paper-based photoanode for photoelectrochemical water splitting
/ Int J Hydrog Energy
46(12)
: 8444~8453
[journal]
Neumann B
/ 2009
/ TiO2-protected photoelectrochemical tandem Cu(In, Ga)Se2 thin film membrane for light-induced water splitting and hydrogen evolution
/ J Phys Chem C
113(49)
: 20980~20989
[journal]
Liu C
/ 2016
/ Water splitting–biosynthetic system with CO2 reduction efficiencies exceeding photosynthesis
/ Science
352(6290)
: 1210~1213
[journal]
Nellist MR
/ 2016
/ Semiconductor–electrocatalyst interfaces : theory, experiment, and applications in photoelectrochemical water splitting
/ Acc Chem Res
49(4)
: 733~740
[journal]
Wang C
/ 2022
/ Facile construction of novel organic–inorganic tetra(4-carboxyphenyl)porphyrin/Bi2MoO6 heterojunction for tetracycline degradation : Performance, degradation pathways, intermediate toxicity analysis and mechanism insight
/ J Colloid Interface Sci
605
: 727~740
[journal]
Landman A
/ 2017
/ Photoelectrochemical water splitting in separate oxygen and hydrogen cells
/ Nat Mater
16(6)
: 646~
[journal]
Tan Y
/ 2014
/ Novel synthesis of rutile titanium dioxide–polypyrrole nano composites and their application in hydrogen generation
/ Synth Met
189
: 77~85
[journal]
Frank AJ
/ 1985
/ Polymer-modified electrodes, catalysis and water-splitting reactions
/ J Photochem
29(1–2)
: 195~204
[journal]
Wang D
/ 2008
/ Sunlight photocatalytic activity of polypyrrole–TiO2 nanocomposites prepared by ‘in situ’method
/ Catal Commun
9(6)
: 1162~1166
[journal]
Zhang S
/ 2012
/ Synthesis and photoactivity of CdS photocatalysts modified by polypyrrole
/ Int J Hydrog Energy
37(17)
: 13030~13036
[journal]
Wang Z
/ 2013
/ Polypyrrole sensitized ZnO nanorod arrays for efficient photo-electrochemical splitting of water
/ Physica B
419
: 51~56
[journal]
Sahasrabudhe A
/ 2018
/ Value added transformation of ubiquitous substrates into highly efficient and flexible electrodes for water splitting
/ Nat Commun
9(1)
: 1~14
[journal]
Dinh PH
/ 2020
/ CuWO4 decorated by polypyrrole(PPy)protector/sensitizer for novel photocatalytic and stable water splitting for hydrogen generation
/ Int J Hydrog Energy
45(41)
: 21442~21449
[journal]
Brijesh K
/ 2019
/ Chemically prepared polypyrrole/ZnWO4 nanocomposite electrodes for electrocatalytic water splitting
/ Int J Hydrog Energy
44(2)
: 757~767
[journal]
Li X
/ 2017
/ Precisely locate Pd-polypyrrole on TiO2 for enhanced hydrogen production
/ Int J Hydrog Energy
42(40)
: 25195~25202
[journal]
Ghosh S
/ 2020
/ Enhanced solar hydrogen generation using Cu–Cu2O integrated polypyrrole nanofibers as heterostructured catalysts
/ Int J Hydrog Energy
45(11)
: 6159~6173
[journal]
Ghosh S
/ 2019
/ Functionalized conjugated polymer with plasmonic Au nanoalloy for photocatalytic hydrogen generation under visible-NIR
/ Int J Hydrog Energy
44(26)
: 13262~13272
[journal]
Saianand G
/ 2022
/ Conducting polymer based visible light photocatalytic composites for pollutant removal : progress and prospects
/ Environ Technol Innov
28
: 102698~
[journal]
Zhang C
/ 2019
/ Harnessing solar-driven photothermal effect toward the water–energy nexus
/ Adv Sci
6(18)
: 1900883~
[journal]
Song N
/ 2022
/ Confinement of prussian blue analogs boxes inside conducting polymer nanotubes enables significantly enhanced catalytic performance for water treatment
/ Adv Funct Mater
32(34)
: 2204751~
[journal]
Farid MU
/ 2023
/ Advancements in nano-enabled membrane distillation for a sustainable water–energy–environment nexus
/ Adv Mater
: 2307950~
[journal]
Liras M
/ 2019
/ Hybrid materials based on conjugated polymers and inorganic semiconductors as photocatalysts : from environmental to energy applications
/ Chem Soc Rev
48(22)
: 5454~5487
[journal]
Kumar R
/ 2019
/ Polypyrrole-based nanomaterials : a novel strategy for reducing toxic chemicals and others related to environmental sustainability applications
/ Chemosphere
303
: 134993~
[journal]
Kim H
/ 2021
/ Porous framework-based hybrid materials for solar-to-chemical energy conversion : from powder photocatalysts to photoelectrodes
/ Inorg Chem Front
8(17)
: 4107~4148
[journal]
Heng S
/ 2020
/ Enhanced photocatalytic hydrogen production of the polyoxoniobate modified with RGO and PPy
/ Nanomaterials
10(12)
: 2449~
[journal]
Kumar N
/ 2020
/ Polypyrrole-promoted rGO–MoS2 nanocomposites for enhanced photocatalytic conversion of CO2 and H2O to CO, CH4, and H2 products
/ ACS Appl Energy Mater
3(10)
: 9897~9909
[journal]
Chen S
/ 2020
/ Semiconductor-based photocatalysts for photocatalytic and photoelectrochemical water splitting : will we stop with photocorrosion?
/ J Mater Chem A
8(5)
: 2286~2322
[journal]
Feng K
/ 2020
/ MoSx-CdS/Cu2ZnSnS4-based thin film photocathode for solar hydrogen evolution from water
/ Appl Catal B Environ
268
: 118438~
[journal]
Huang S
/ 2013
/ Band positions and photoelectrochemical properties of Cu2ZnSnS4 thin films by the ultrasonic spray pyrolysis method
/ J Phys D Appl Phys
46(23)
: 235108~
[journal]
Abdulla HS
/ 2012
/ Optical and electrical properties of thin films of polyaniline and polypyrrole
/ Int J Electrochem Sci
7
: 10666~10678
[journal]
Bredas J
/ 1984
/ Polarons and bipolarons in polypyrrole : evolution of the band structure and optical spectrum upon doing
/ Phys Rev B
30(2)
: 1023~
[journal]
Padhi DK
/ 2017
/ Green synthesis of Fe3O4/RGO nanocomposite with enhanced photocatalytic performance for Cr(VI)reduction, phenol degradation, and antibacterial activity
/ ACS Sustain Chem Eng
5(11)
: 10551~10562
[journal]
Kaloni TP
/ 2016
/ Band gap modulation in polythiophene and polypyrrole-based systems
/ Sci Rep
6
: 36554~
[journal]
Ferhati H
/ 2018
/ Graded band-gap engineering for increased efficiency in CZTS solar cells
/ Opt Mater
76
: 393~399
[journal]
Suryawanshi MP
/ 2017
/ Aqueous-solution-processed Cu2ZnSn(S, Se)4 thin-film solar cells via an improved successive ion-layer-adsorption–reaction sequence
/ ACS Omega
2(12)
: 9211~9220
[book]
Sharma N
/ 2017
/ Macromolecular symposia
/ Wiley Online Library
[book]
Sudhagar P
/ 2016
/ Photoelectrochemical solar fuel production
/ Springer
: 105~160
[journal]
Yao B
/ 2017
/ Paper-based electrodes for flexible energy storage devices
/ Adv Sci
4(7)
: 1700107~
[journal]
Kong X
/ 2023
/ Preparation of TiO2/CdS/Ni(OH)2 composite photoanode for nonsacrificial photoelectrochemical water splitting
/ ACS Appl Energy Mater
6(22)
: 11654~11662
[journal]
Ye K-H
/ 2019
/ Enhancing photoelectrochemical water splitting by combining work function tuning and heterojunction engineering
/ Nat Commun
10(1)
: 3687~
[journal]
Thakur A
/ 2018
/ Citrus limetta organic waste recycled carbon nanolights : photoelectro catalytic, sensing, and biomedical applications
/ ACS Sustain Chem Eng
7(1)
: 502~512
[journal]
Suryawanshi MP
/ 2017
/ Enhanced solar water oxidation performance of TiO2 via band edge engineering : a tale of sulfur doping and earth-abundant CZTS nanoparticles sensitization
/ ACS Catal
7(12)
: 8077~8089
[journal]
Jeon D
/ 2018
/ WO3/conducting polymer heterojunction photoanodes for efficient and stable photoelectrochemical water splitting
/ ACS Appl Mater Interfaces
10(9)
: 8036~8044
[journal]
Ha E
/ 2014
/ Significant enhancement in photocatalytic reduction of water to hydrogen by Au/Cu2ZnSnS4 nanostructure
/ Adv Mater
26(21)
: 3496~3500