RhO2 Modified BiVO4 Thin Film Photoanodes: Preparation and Photoelectrocatalytic Water Splitting Performance

Yue HU; Lin AN; Xin HAN; Chengyi HOU; Hongzhi WANG; Yaogang LI; Qinghong ZHANG

doi:10.15541/jim20210798

[1] M FANG, Q CAI, Q QIN et al. Mo-doping induced crystal orientation reconstruction and oxygen vacancy on BiVO₄ homojunction for enhanced solar-driven water splitting. Chemical Engineering Journal, 127796(2021).

[2] W ZHANG, Q SHEN, J XUE et al. Preparation and photoelectrochemical water oxidation of hematite nanobelts containing highly ordered oxygen vacancies. Journal of Inorganic Materials, 1290-1296(2021).

[3] X HAN, T SI, Q LIU et al. 2D bimetallic RuNi alloy co-catalysts remarkably enhanced the photocatalytic H₂ evolution performance of g-C₃N₄ nanosheets. Chemical Engineering Journal, 130824(2021).

[4] K SU, Y ZHANG, F LU et al. Platinum decorated titanium dioxide nanosheets for efficient photoelectrocatalytic hydrogen evolution reaction. Journal of Inorganic Materials, 1200-1204(2019).

[5] J H KIM, J S LEE. Elaborately modified BiVO₄ photoanodes for solar water splitting. Advanced Materials, 1806938(2019).

[6] Y M HE, T HAMANN, D W WANG. Thin film photoelectrodes for solar water splitting. Chemical Society Reviews, 2182-2215(2019).

[7] D BAE, B SEGER, P C K VESBORG et al. Strategies for stable water splitting via protected photoelectrodes. Chemical Society Reviews, 1933-1954(2017).

[8] X LU, K H YE, S ZHANG et al. Amorphous type FeOOH modified defective BiVO₄ photoanodes for photoelectrochemical water oxidation. Chemical Engineering Journal, 131027(2022).

[9] J JIAN, G S JIANG, DE KROL R VAN et al. Recent advances in rational engineering of multinary semiconductors for photoelectrochemical hydrogen generation. Nano Energy, 457-480(2018).

[10] Y GAO, W FAN, K QU et al. Confined growth of Co-Pi co- catalyst by organic semiconductor polymer for boosting the photoelectrochemical performance of BiVO₄. New Journal of Chemistry, 8160-8167(2019).

[11] B PENG, M XIA, C LI et al. Network structured CuWO₄/BiVO₄/ Co-Pi nanocomposite for solar water splitting. Catalysts, 663-672(2018).

[12] K H YE, Z L WANG, J W GU et al. Carbon quantum dots as a visible light sensitizer to significantly increase the solar water splitting performance of bismuth vanadate photoanodes. Energy & Environmental Science, 772-779(2017).

[13] Q Y ZENG, J H LI, L S LI et al. Synthesis of WO₃/BiVO₄ photoanode using a reaction of bismuth nitrate with peroxovanadate on WO₃ film for efficient photoelectrocatalytic water splitting and organic pollutant degradation. Applied Catalysis B-Environmental, 21-29(2017).

[14] D K ZHONG, S CHOI, D R GAMELIN. Near-complete suppression of surface recombination in solar photoelectrolysis by "Co-Pi" catalyst-modified W: BiVO₄. Journal of the American Chemical Society, 18370-18377(2011).

[15] V RITLENG, C SIRLIN, M PFEFFER. Ru-, Rh-, and Pd-catalyzed C-C bond formation involving C-H activation and addition on unsaturated substrates: reactions and mechanistic aspects. Chemical Reviews, 1731-1769(2002).

[16] G SONG, F WANG, X LI. C-C, C-O and C-N bond formation via rhodium (III)-catalyzed oxidative C-H activation. Chemical Society Reviews, 3651-3678(2012).

[17] C T CAMPBELL. Ultrathin metal films and particles on oxide surfaces: structural, electronic and chemisorptive properties. Surface Science Reports, 1-111(1997).

[18] D A COLBY, A S TSAI, R G BERGMAN et al. Rhodium catalyzed chelation-assisted C-H bond functionalization reactions. Accounts of Chemical Research, 814-825(2012).

[19] T OHNO, L BAI, T HISATOMI et al. Photocatalytic water splitting using modified GaN:ZnO solid solution under visible light: long-time operation and regeneration of activity. Journal of the American Chemical Society, 8254-8259(2012).

[20] S WANG, P CHEN, J H YUN et al. An electrochemically treated BiVO₄ photoanode for efficient photoelectrochemical water splitting. Angewandte Chemie International Edition, 8500-8504(2017).

[21] Y MIAO, J LIU, L CHEN et al. Single-atomic-Co cocatalyst on (040) facet of BiVO₄ toward efficient photoelectrochemical water splitting. Chemical Engineering Journal, 131011(2022).

[22] S C PERRY, D PANGOTRA, L VIEIRA et al. Electrochemical synthesis of hydrogen peroxide from water and oxygen. Nature Reviews Chemistry, 442-458(2019).

[23] Y P ZHANG, Y LI, D Q NI et al. Improvement of BiVO₄ photoanode performance during water photo-oxidation using Rh-doped SrTiO₃ perovskite as a co-catalyst. Advanced Functional Materials, 1902101(2019).

[24] H FEI, J SHAO, H LI et al. Construction of ultra-thin 2D CN-Br- 0.12/2% RhO_x photo-catalyst with rapid electron and hole separation for efficient bisphenol A degradation. Applied Catalysis B- Environmental, 120623(2021).

[25] E R LEITE, A P MACIEL, I T WEBER et al. Development of metal oxide nanoparticles with high stability against particle growth using a metastable solid solution. Advanced Materials, 905-908(2002).

[26] K T FOUNTAINE, H J LEWERENZ, H A ATWATER. Interplay of light transmission and catalytic exchange current in photoelectrochemical systems. Applied Physics Letters, 173901(2014).

[27] K R TOLOD, S HERNANDEZ, N RUSSO. Recent advances in the BiVO₄ photocatalyst for sun-driven water oxidation: top-performing photoanodes and scale-up challenges. Catalysts, 13-23(2017).

[28] H SHE, P YUE, J HUANG et al. One-step hydrothermal deposition of F:FeOOH onto BiVO₄ photoanode for enhanced water oxidation. Chemical Engineering Journal, 123703(2020).

[29] S JU, J JUN, D HUH et al. Simultaneous improvement of absorption and separation efficiencies of Mo:BiVO₄ photoanodes via nanopatterned SnO₂/Au hybrid layers. ACS Sustainable Chemistry & Engineering, 17000-17007(2019).

[30] J QI, D KONG, D LIU et al. Bimetallic phosphide decorated Mo-BiVO₄ for significantly improved photoelectrochemical activity and stability. RSC Advances, 15629-15634(2019).

[31] X YIN, W QIU, W LI et al. High porosity Mo doped BiVO₄ film by vanadium re-substitution for efficient photoelectrochemical water splitting. Chemical Engineering Journal, 124365(2020).

[32] J JIAN, Y XU, X YANG et al. Embedding laser generated nanocrystals in BiVO₄ photoanode for efficient photoelectrochemical water splitting. Nature Communications, 2609(2019).

[33] F COSTANTINO, P V KAMAT. Do sacrificial donors donate H₂ in photocatalysis. ACS Energy Letters, 242-246(2021).

[34] K MAEDA, A XIONG, T YOSHINAGA et al. Photocatalytic overall water splitting promoted by two different cocatalysts for hydrogen and oxygen evolution under visible light. Angewandte Chemie International Edition, 4096-4099(2010).

[35] D WANG, R LI, J ZHU et al. Photocatalytic water oxidation on BiVO₄ with the electrocatalyst as an oxidation cocatalyst: essential relations between electrocatalyst and photocatalyst. The Journal of Physical Chemistry C, 5082-5089(2012).