REFERENCES

1. Fares RL, Webber ME. The impacts of storing solar energy in the home to reduce reliance on the utility. Nat Energy 2017;2:17001.

2. Kammen DM, Sunter DA. City-integrated renewable energy for urban sustainability. Science 2016;352:922-8.

3. Lelieveld J, Evans JS, Fnais M, Giannadaki D, Pozzer A. The contribution of outdoor air pollution sources to premature mortality on a global scale. Nature 2015;525:367-71.

4. Dawood F, Anda M, Shafiullah G. Hydrogen production for energy: an overview. Int J Hydrog Energy 2020;45:3847-69.

5. Tee SY, Win KY, Teo WS, et al. Recent progress in energy-driven water splitting. Adv Sci 2017;4:1600337.

6. Zou X, Zhang Y. Noble metal-free hydrogen evolution catalysts for water splitting. Chem Soc Rev 2015;44:5148-80.

7. Muradov N. Low to near-zero CO2 production of hydrogen from fossil fuels: status and perspectives. Int J Hydrog Energy 2017;42:14058-88.

8. Ran J, Jaroniec M, Qiao SZ. Cocatalysts in semiconductor-based photocatalytic CO2 reduction: achievements, challenges, and opportunities. Adv Mater 2018;30:1704649.

9. Abbott D. Keeping the energy debate clean: how do we supply the world's energy needs? Proc IEEE 2010;98:42-66.

10. Thalluri SM, Bai L, Lv C, Huang Z, Hu X, Liu L. Strategies for semiconductor/electrocatalyst coupling toward solar-driven water splitting. Adv Sci 2020;7:1902102.

11. Fujishima A, Honda K. Electrochemical photolysis of water at a semiconductor electrode. Nature 1972;238:37-8.

12. Butburee T, Bai Y, Wang H, et al. 2D Porous TiO2 single-crystalline nanostructure demonstrating high photo-electrochemical water splitting performance. Adv Mater 2018;30:e1705666.

13. Liu X, Wang F, Wang Q. Nanostructure-based WO3 photoanodes for photoelectrochemical water splitting. Phys Chem Chem Phys 2012;14:7894-911.

14. Chen D, Xie Z, Tong Y, Huang Y. Review on BiVO4-based photoanodes for photoelectrochemical water oxidation: the main influencing factors. Energy Fuels 2022;36:9932-49.

15. Hsu YK, Chen YC, Lin YG. Novel ZnO/Fe2O3 core-shell nanowires for photoelectrochemical water splitting. ACS Appl Mater Interfaces 2015;7:14157-62.

16. Zhang Y, Pan D, Tao Y, et al. Photoelectrocatalytic reduction of CO2 to syngas via SnOx-enhanced Cu2O nanowires photocathodes. Adv Funct Materials 2022;32:2109600.

17. Pan L, Muhammad T, Ma L, et al. MOF-derived C-doped ZnO prepared via a two-step calcination for efficient photocatalysis. Appl Catal B 2016;189:181-91.

18. Wang L, Shi X, Jia Y, Cheng H, Wang L, Wang Q. Recent advances in bismuth vanadate-based photocatalysts for photoelectrochemical water splitting. Chin Chem Lett 2021;32:1869-78.

19. Zhang J, Huang Y, Lu X, Yang J, Tong Y. Enhanced BiVO4 photoanode photoelectrochemical performance via borate treatment and a NiFeOx cocatalyst. ACS Sustain Chem Eng 2021;9:8306-14.

20. Lin F, Boettcher SW. Adaptive semiconductor/electrocatalyst junctions in water-splitting photoanodes. Nat Mater 2014;13:81-6.

21. Xie Z, Chen D, Zhai J, Huang Y, Ji H. Charge separation via synergy of homojunction and electrocatalyst in BiVO4 for photoelectrochemical water splitting. Appl Catal B 2023;334:122865.

22. Digdaya IA, Adhyaksa GWP, Trześniewski BJ, Garnett EC, Smith WA. Interfacial engineering of metal-insulator-semiconductor junctions for efficient and stable photoelectrochemical water oxidation. Nat Commun 2017;8:15968.

23. Bae D, Seger B, Vesborg PC, Hansen O, Chorkendorff I. Strategies for stable water splitting via protected photoelectrodes. Chem Soc Rev 2017;46:1933-54.

24. Chen D, Liu Z, Guo Z, Yan W, Ruan M. Decorating Cu2O photocathode with noble-metal-free Al and NiS cocatalysts for efficient photoelectrochemical water splitting by light harvesting management and charge separation design. Chem Eng J 2020;381:122655.

25. Zandi O, Hamann TW. Enhanced water splitting efficiency through selective surface state removal. J Phys Chem Lett 2014;5:1522-6.

26. Sivula K. Metal oxide photoelectrodes for solar fuel production, surface traps, and catalysis. J Phys Chem Lett 2013;4:1624-33.

27. Liu W, Liu H, Dang L, et al. Amorphous Cobalt-iron hydroxide nanosheet electrocatalyst for efficient electrochemical and photo-electrochemical oxygen evolution. Adv Funct Mater 2017;27:1603904.

28. Meng Q, Zhang B, Yang H, et al. Remarkable synergy of borate and interfacial hole transporter on BiVO4 photoanodes for photoelectrochemical water oxidation. Mater Adv 2021;2:4323-32.

29. Liang Z, Li M, Ye K, et al. Systematic engineering of BiVO4 photoanode for efficient photoelectrochemical water oxidation. Carbon Energy 2023:e413.

30. Yang J, Zhou J, Huang Y, Tong Y. Lanthanide-based dual modulation in hematite nanospindles for enhancing the photocatalytic performance. ACS Appl Nano Mater 2022;5:8557-65.

31. Ye K, Hu P, Liu K, et al. New findings for the much-promised hematite photoanodes with gradient doping and overlayer elaboration. Solar RRL 2022;6:2270061.

32. Liu J, Chen W, Sun Q, et al. Oxygen vacancies enhanced WO3/BiVO4 photoanodes modified by cobalt phosphate for efficient photoelectrochemical water splitting. ACS Appl Energy Mater 2021;4:2864-72.

33. Yang W, Prabhakar RR, Tan J, Tilley SD, Moon J. Strategies for enhancing the photocurrent, photovoltage, and stability of photoelectrodes for photoelectrochemical water splitting. Chem Soc Rev 2019;48:4979-5015.

34. Wang S, Chen P, Bai Y, Yun JH, Liu G, Wang L. New BiVO4 dual photoanodes with enriched oxygen vacancies for efficient solar-driven water splitting. Adv Mater 2018;30:e1800486.

35. Butson JD, Sharma A, Tournet J, et al. Unlocking ultra-high performance in immersed solar water splitting with optimised energetics. Adv Energy Mater 2023;13:2301793.

36. Kim H, Seo JW, Chung W, et al. Thermal effect on photoelectrochemical water splitting toward highly solar to hydrogen efficiency. ChemSusChem 2023;16:e202202017.

37. Li T, Zou Y, Liu Z. Magnetic-thermal external field activate the pyro-magnetic effect of pyroelectric crystal (NaNbO3) to build a promising multi-field coupling-assisted photoelectrochemical water splitting system. Appl Catal B 2023;328:122486.

38. Khan H, Lone IH, Lofland SE, Ramanujachary KV, Ahmad T. Exploiting multiferroicity of TbFeO3 nanoparticles for hydrogen generation through photo/electro/photoelectro-catalytic water splitting. Int J Hydrogen Energy 2023;48:5493-505.

39. Han Q, Han Z, Wang Y, et al. Enhanced photocatalytic hydrogen evolution by piezoelectric effects based on MoSe2/Se-decorated CdS nanowire edge-on heterostructure. J Colloid Interface Sci 2023;630:460-72.

40. Kai J, Saito R, Terabaru K, Li H, Nakajima H, Ito K. Effect of temperature on the performance of polymer electrolyte membrane water electrolysis: numerical analysis of electrolysis voltage considering gas/liquid two-phase flow. J Electrochem Soc 2019;166:F246.

41. Barco-burgos J, Eicker U, Saldaña-robles N, Saldaña-robles A, Alcántar-camarena V. Thermal characterization of an alkaline electrolysis cell for hydrogen production at atmospheric pressure. Fuel 2020;276:117910.

42. Tang S, Xing X, Yu W, et al. Synergizing photo-thermal H2 and photovoltaics into a concentrated sunlight use. iScience 2020;23:101012.

43. Mateo D, Cerrillo JL, Durini S, Gascon J. Fundamentals and applications of photo-thermal catalysis. Chem Soc Rev 2021;50:2173-210.

44. Yu F, Wang C, Li Y, et al. Enhanced solar photothermal catalysis over solution plasma activated TiO2. Adv Sci 2020;7:2000204.

45. Ghoussoub M, Xia M, Duchesne PN, Segal D, Ozin G. Principles of photothermal gas-phase heterogeneous CO2 catalysis. Energy Environ Sci 2019;12:1122-42.

46. Xiao JD, Jiang HL. Metal-organic frameworks for photocatalysis and photothermal catalysis. Acc Chem Res 2019;52:356-66.

47. Niu F, Wang D, Li F, Liu Y, Shen S, Meyer TJ. Hybrid photoelectrochemical water splitting systems: from interface design to system assembly. Adv Energy Mater 2020;10:1900399.

48. Tayebi M, Lee B. Recent advances in BiVO4 semiconductor materials for hydrogen production using photoelectrochemical water splitting. Renew Sustain Energy Rev 2019;111:332-43.

49. Maeda K, Domen K. Photocatalytic water splitting: recent progress and future challenges. J Phys Chem Lett 2010;1:2655-61.

50. Sang Y, Zhao Z, Zhao M, Hao P, Leng Y, Liu H. From UV to near-infrared, WS2 nanosheet: a novel photocatalyst for full solar light spectrum photodegradation. Adv Mater 2015;27:363-9.

51. Zhang J, Chen H, Duan X, Sun H, Wang S. Photothermal catalysis: from fundamentals to practical applications. Mater Today 2023;68:234-53.

52. Wang X, Ma S, Liu B, Wang S, Huang W. Imperfect makes perfect: defect engineering of photoelectrodes towards efficient photoelectrochemical water splitting. Chem Commun 2023;59:10044-66.

53. Wang Y, Zhang J, Balogun M, Tong Y, Huang Y. Oxygen vacancy-based metal oxides photoanodes in photoelectrochemical water splitting. Mater Today Sustain 2022;18:100118.

54. Zhao L, Liu Y, Xing R, Yan X. Supramolecular photothermal effects: a promising mechanism for efficient thermal conversion. Angew Chem Int Ed 2020;59:3793-801.

55. Seh ZW, Kibsgaard J, Dickens CF, Chorkendorff I, Nørskov JK, Jaramillo TF. Combining theory and experiment in electrocatalysis: insights into materials design. Science 2017;355:eaad4998.

56. Kim JH, Lee JS. Elaborately modified BiVO4 photoanodes for solar water splitting. Adv Mater 2019;31:e1806938.

57. Li Z, Luo W, Zhang M, Feng J, Zou Z. Photoelectrochemical cells for solar hydrogen production: current state of promising photoelectrodes, methods to improve their properties, and outlook. Energy Environ Sci 2013;6:347-70.

58. Stepanov IA. The heats of chemical reactions: the Van't-Hoff equation and calorimetry. Z Phy Chem 2005;219:1089-97.

59. Kweon KE, Hwang GS. Structural phase-dependent hole localization and transport in bismuth vanadate. Phys Rev B 2013;87:205202.

60. Tan HL, Amal R, Ng YH. Alternative strategies in improving the photocatalytic and photoelectrochemical activities of visible light-driven BiVO4: a review. J Mater Chem A 2017;5:16498-521.

61. Matthies M, Beulke S. Considerations of temperature in the context of the persistence classification in the EU. Environ Sci Eur 2017;29:15.

62. Pendlebury SR, Barroso M, Cowan AJ, et al. Dynamics of photogenerated holes in nanocrystalline α-Fe2O3 electrodes for water oxidation probed by transient absorption spectroscopy. Chem Commun 2011;47:716-8.

63. Cowan AJ, Barnett CJ, Pendlebury SR, et al. Activation energies for the rate-limiting step in water photooxidation by nanostructured α-Fe2O3 and TiO2. J Am Chem Soc 2011;133:10134-40.

64. Sleutels TH, Darus L, Hamelers HV, Buisman CJ. Effect of operational parameters on coulombic efficiency in bioelectrochemical systems. Bioresour Technol 2011;102:11172-6.

65. Harmon M, Gamba IM, Ren K. Numerical algorithms based on Galerkin methods for the modeling of reactive interfaces in photoelectrochemical (PEC) solar cells. J Comput Phys 2016;327:140-67.

66. Kreider ME, Gallo A, Back S, et al. Precious metal-free nickel nitride catalyst for the oxygen reduction reaction. ACS Appl Mater Interfaces 2019;11:26863-71.

67. Liu C, Wang Z, Zhang T, Zhang Y, Su J. Photo/thermal dual-activation improves the photocurrent of bismuth vanadate for pec water splitting. ChemElectroChem 2022;9:e202200646.

68. Ye X. Elevated temperature photo-electrochemical water splitting. 2016. Available from: http://purl.stanford.edu/vy785kk1866 [Last accessed on 30 Nov 2023].

69. Isik M, Delice S, Gasanly N. Temperature-dependent optical properties of TiO2 nanoparticles: a study of band gap evolution. Opt Quant Electron 2023;55:905.

70. Landman A, Dotan H, Shter GE, et al. Photoelectrochemical water splitting in separate oxygen and hydrogen cells. Nat Mater 2017;6:646-51.

71. Zhao H, Tian F, Wang R, Chen R. A review on bismuth-related nanomaterials for photocatalysis. Rev Adv Sci Eng 2014;3:3-27.

72. Varshni YP. Temperature dependence of the elastic constants. Phys Rev B 1970;2:3952-8.

73. Leszczynski M, Suski T, Teisseyre H, et al. Thermal expansion of gallium nitride. J Appl Phys 1994;76:4909-11.

74. Hsu K, Wang C, Liu C. The growth of GaN nanorods with different temperature by molecular beam epitaxy. J Electrochem Soc 2010;157:K109.

75. Ye CH, Fang XS, Wang M, Zhang LD. Temperature-dependent photoluminescence from elemental sulfur species on ZnS nanobelts. J Appl Phys 2006;99:063504.

76. Pejova B, Abay B, Bineva I. Temperature dependence of the band-gap energy and sub-band-gap absorption tails in strongly quantized ZnSe nanocrystals deposited as thin films. J Phys Chem C 2010;114:15280-91.

77. Lee MG, Kim DH, Sohn W, et al. Conformally coated BiVO4 nanodots on porosity-controlled WO3 nanorods as highly efficient type II heterojunction photoanodes for water oxidation. Nano Energy 2016;28:250-60.

78. Tang R, Yin R, Zhou S, et al. Layered MoS2 coupled MOFs-derived dual-phase TiO2 for enhanced photoelectrochemical performance. J Mater Chem A 2017;5:4962-71.

79. Lee SA, Lee TH, Kim C, et al. Tailored NiOx/Ni cocatalysts on silicon for highly efficient water splitting photoanodes via pulsed electrodeposition. ACS Catal 2018;8:7261-9.

80. Chen D, Li X, Huang J, Chen Y, Liu Z, Huang Y. Boosting charge transfer of Fe doping BiVO4/CoOx for photoelectrochemical water splitting. ACS Appl Energy Mater 2023;6:8495-502.

81. Pejova B, Abay B. Nanostructured CdSe films in low size-quantization regime: temperature dependence of the band gap energy and sub-band gap absorption tails. J Phys Chem C 2011;115:23241-55.

82. Zhang L, Ye X, Boloor M, Poletayev A, Melosh NA, Chueh WC. Significantly enhanced photocurrent for water oxidation in monolithic Mo: BiVO4/SnO2/Si by thermally increasing the minority carrier diffusion length. Energy Environ Sci 2016;9:2044-52.

83. Tang S, Qiu W, Xu X, et al. Harvesting of infrared part of sunlight to enhance polaron transport and solar water splitting. Adv Funct Materials 2022;32:2110284.

84. Zhou C, Zhang L, Tong X, Liu M. Temperature effect on photoelectrochemical water splitting: a model study based on BiVO4 photoanodes. ACS Appl Mater Interfaces 2021;13:61227-36.

85. Wang Z, Yang C, Lin T, et al. Visible-light photocatalytic, solar thermal and photoelectrochemical properties of aluminium-reduced black titania. Energy Environ Sci 2013;6:3007-14.

86. Dias P, Lopes T, Andrade L, Mendes A. Temperature effect on water splitting using a Si-doped hematite photoanode. J Power Sources 2014;272:567-80.

87. Ye X, Yang J, Boloor M, Melosh NA, Chueh WC. Thermally-enhanced minority carrier collection in hematite during photoelectrochemical water and sulfite oxidation. J Mater Chem A 2015;3:10801-10.

88. He B, Jia S, Zhao M, et al. General and robust photothermal-heating-enabled high-efficiency photoelectrochemical water splitting. Adv Mater 2021;33:2004406.

89. Zhang Q, Ning X, Fan Y, et al. Insight into interface charge regulation through the change of the electrolyte temperature toward enhancing photoelectrochemical water oxidation. J Colloid Interface Sci 2021;588:31-9.

90. He B, Zhao F, Yi P, et al. Spinel-oxide-integrated BiVO4 photoanodes with photothermal effect for efficient solar water oxidation. ACS Appl Mater Interfaces 2021;13:48901-12.

91. Huang J, Hu X, Wang J, et al. Unraveling photothermal-enhanced bulk charge transport and surface oxygen reactions in TiO2 photoanodes for highly efficient photoelectrochemical water oxidation. Chem Eng J 2023;462:142246.

92. Hu X, Huang J, Cao Y, et al. Photothermal-boosted polaron transport in Fe2O3 photoanodes for efficient photoelectrochemical water splitting. Carbon Energy 2023;5:e369.

93. Lu X, Ye K, Zhang S, et al. Amorphous type FeOOH modified defective BiVO4 photoanodes for photoelectrochemical water oxidation. Chem Eng J 2022;428:131027.

94. Zhang Y, Huang Y, Zhu SS, et al. Covalent S-O bonding enables enhanced photoelectrochemical performance of Cu2S/Fe2O3 heterojunction for water splitting. Small 2021;17:2100320.

95. Xue F, Wu H, Liu Y, et al. CuS nanosheet-induced local hot spots on g-C3N4 boost photocatalytic hydrogen evolution. Int J Hydrog Energy 2023;48:6346-57.

96. Zhao F, Sheng H, Sun Q, et al. Harvesting the infrared part of solar light to promote charge transfer in Bi2S3/WO3 photoanode for enhanced photoelectrochemical water splitting. J Colloid Interface Sci 2022;621:267-74.

97. Deng C, Peng L, Ling X, et al. Construction of S-scheme Zn0.2Cd0.8S/biochar aerogel architectures for boosting photocatalytic hydrogen production under sunlight irradiation. J Clean Prod 2023;414:137616.

98. Tai Z, Sun G, Zhang X, et al. Embedding laser-generated CdTe nanocrystals into ultrathin ZnIn2S4 nanosheets with sulfur vacancies for boosted photocatalytic H2 evolution. J Mater Sci Technol 2023;166:113-22.

99. Wang K, Liu J, Tao Y, Benetti D, Rosei F, Sun X. Temperature-dependence photoelectrochemical hydrogen generation based on alloyed quantum dots. J Phys Chem C 2022;126:174-82.

100. Li L, Shi H, Yu H, et al. Ultrathin MoSe2 nanosheet anchored CdS-ZnO functional paper chip as a highly efficient tandem Z-scheme heterojunction photoanode for scalable photoelectrochemical water splitting. Appl Catal B 2021;292:120184.

101. Guo MJ, Zhao TY, Xing ZP, et al. Hollow Octahedral Cu2-xS/CdS/Bi2S3 p-n-p type tandem heterojunctions for efficient photothermal effect and robust visible-light-driven photocatalytic performance. Acs Appl Mater Interfaces 2020;12:40328-38.

102. Zhong W, Wang C, Zhao H, et al. Synergistic effect of photo-thermal catalytic glycerol reforming hydrogen production over 2D Au/TiO2 nanoflakes. Chem Eng J 2022;446:137063.

103. Valenti M, Jonsson MP, Biskos G, Schmidt-ott A, Smith WA. Plasmonic nanoparticle-semiconductor composites for efficient solar water splitting. J Mater Chem A 2016;4:17891-912.

104. Cushing SK, Li J, Bright J, et al. Controlling plasmon-induced resonance energy transfer and hot electron injection processes in metal@TiO2 core-shell nanoparticles. J Phys Chem C 2015;119:16239-44.

105. Lee S, Sun Y, Cao Y, Kang SH. Plasmonic nanostructure-based bioimaging and detection techniques at the single-cell level. Trends Analyt Chem 2019;117:58-68.

106. Zhang Z, Zhang L, Hedhili MN, Zhang H, Wang P. Plasmonic gold nanocrystals coupled with photonic crystal seamlessly on TiO2 nanotube photoelectrodes for efficient visible light photoelectrochemical water splitting. Nano Lett 2013;13:14-20.

107. Liu ZW, Hou WB, Pavaskar P, Aykol M, Cronin SB. Plasmon resonant enhancement of photocatalytic water splitting under visible illumination. Nano Lett 2011;11:1111-16.

108. Tang T, Li M, Liang Z, et al. Promoting plasmonic hot hole extraction and photothermal effect for the oxygen evolution reactions. Chemistry 2023;29:e202300225.

109. Agarwal D, Aspetti CO, Cargnello M, et al. Engineering localized surface plasmon interactions in gold by silicon nanowire for enhanced heating and photocatalysis. Nano Lett 2017;17:1839-45.

110. Huang Y, Long B, Tang M, et al. Bifunctional catalytic material: an ultrastable and high-performance surface defect CeO2 nanosheets for formaldehyde thermal oxidation and photocatalytic oxidation. Appl Catal B 2016;181:779-87.

111. Subramanyam P, Meena B, Sinha GN, Deepa M, Subrahmanyam C. Decoration of plasmonic Cu nanoparticles on WO3/Bi2S3 QDs heterojunction for enhanced photoelectrochemical water splitting. Int J Hydrog Energy 2020;45:7706-15.

112. Saeed S, Siddique H, Dai R, et al. Enhanced PEC water splitting performance of silver nanoparticle-coated CdS nanowire photoanodes: the role of silver deposition. J Phys Chem C 2021;45:7542-51.

113. Gelija D, Loka C, Goddati M, Bak N, Lee J, Kim MD. Integration of Ag plasmonic metal and WO3/InGaN heterostructure for photoelectrochemical water splitting. Acs Appl Mater Interfaces 2023;15:34883-94.

114. Song R, Liu M, Luo B, Geng J, Jing D. Plasmon-induced photothermal effect of sub-10-nm Cu nanoparticles enables boosted full-spectrum solar H2 production. AIChE J 2020;66:e17008.

115. Li J, Hatami M, Huang Y, Luo B, Jing D, Ma L. Efficient photothermal catalytic hydrogen production via plasma-induced photothermal effect of Cu/TiO2 nanoparticles. Int J Hydrog Energy 2023; 48:6336-45.

116. Subramanyam P, Meena B, Suryakala D, Deepa M, Subrahmanyam C. Plasmonic nanometal decorated photoanodes for efficient photoelectrochemical water splitting. Catal Today 2021;379:1-6.

117. Wu J, Xu X, Guo X, Xie W, Pan L, Chen Y. Polypyrrole modification on BiVO4 for photothermal-assisted photoelectrochemical water oxidation. J Chem Phys 2023;158:091102.

118. Zhao M, Chen T, He B, et al. Photothermal effect-enhanced photoelectrochemical water splitting of a BiVO4 photoanode modified with dual-functional polyaniline. J Mater Chem A 2020;8:15976-83.

119. Xu W, Meng L, Tian W, Li S, Cao F, Li L. Polypyrrole serving as multifunctional surface modifier for photoanode enables efficient photoelectrochemical water oxidation. Small 2022;18:2105240.

120. Hu C, Dai L. Carbon-based metal-free catalysts for electrocatalysis beyond the ORR. Angew Chem Int Ed 2016;55:11736-58.

121. Li T, Guo Z, Ruan M, Zou Y, Liu Z. Doping regulating spontaneous polarization and pyroelectric effects to synergistically promote the water splitting efficiency of niobate (KxNa1-xNbO3) pyro-photo-electrical coupling system. Appl Surf Sci 2022;592:153255.

122. Moon HK, Lee SH, Choi HC. In vivo near-infrared mediated tumor destruction by photothermal effect of carbon nanotubes. ACS Nano 2009;3:3707-13.

123. Wang Y, Chen D, Zhang J, et al. Charge relays via dual carbon-actions on nanostructured BiVO4 for high performance photoelectrochemical water splitting. Adv Funct Mater 2022;32:2112738.

124. Hu XQ, Huang J, Zhao FF, et al. Photothermal effect of carbon quantum dots enhanced photoelectrochemical water splitting of hematite photoanodes. J Mater Chem A 2020;8:14915-20.

125. Cai J, Tang X, Liu C, et al. Bifunctional photothermal effect to promote band bending and water oxidation kinetics for improving photoelectrochemical water splitting. Sol Energy Mater Sol Cells 2023;257:112360.

126. Noureen L, Xie Z, Hussain M, et al. BiVO4 and reduced graphene oxide composite hydrogels for solar-driven steam generation and decontamination of polluted water. Sol Energy Mater Sol Cells 2021;222:110952.

127. Wu Y, Sun Y, Fu W, et al. Graphene-based modulation on the growth of urchin-like Na2Ti3O7 microspheres for photothermally enhanced H2 generation from ammonia borane. ACS Appl Nano Mater 2020;3:2713-22.

128. Fang J, Sun F, Kheradmand A, et al. Solar thermo-photo catalytic hydrogen production from water with non-metal carbon nitrides. Fuel 2023;353:129277.

129. Wang M, Wan Z, Li Z, et al. Full spectrum solar hydrogen production by tandems of perovskite solar cells and photothermal enhanced electrocatalysts. Chem Eng J 2023;460:141702.

130. Qi J, Zhang W, Cao R. A new strategy for solar-to-hydrogen energy conversion: photothermal-promoted electrocatalytic water splitting. ChemElectroChem 2019;6:2762-5.

131. Xie X, Wang R, Ma Y, et al. Photothermal-effect-enhanced photoelectrochemical water splitting in MXene-nanosheet-modified ZnO nanorod arrays. ACS Appl Nano Mater 2022;5:11150-9.

132. Zhang Y, Song X, Xue S, Liang Y, Jiang H. Fabrication of hierarchically structured S-doped NiFe hydroxide/oxide electrodes for solar-assisted oxygen evolution reaction in seawater splitting. Appl Catal A 2023;649:118965.

133. Zhang Y, Hu L, Zhang Y, Wang X, Wang H. Snowflake-Like Cu2S/MoS2/Pt heterostructure with near infrared photothermal-enhanced electrocatalytic and photoelectrocatalytic hydrogen production. Appl Catal B 2022;315:121540.

134. Cao A, Sang L, Yu Z, et al. Investigation of the local photothermal effects by fabricating a CQDs/Au/TiO2 photoelectrode in a PEC water splitting system. Catal Sci Technol 2022;12:1859-68.

135. Zhao Y, Sang L, Wang C. Thermoplasmonics effect of Au-rGO/TiO2 photoelectrode in solar-hydrogen conversion. Sol Energy Mater Sol Cells 2023;255:112306.

136. Landman A, Halabi R, Dias P, et al. Decoupled photoelectrochemical water splitting system for centralized hydrogen production. Joule 2020;4:448-71.

137. Pareek A, Dom R, Borse PH. Fabrication of large area nanorod like structured CdS photoanode for solar H2 generation using spray pyrolysis technique. Int J Hydrog Energy 2013;38:36-44.

138. Vilanova A, Dias P, Azevedo J, et al. Solar water splitting under natural concentrated sunlight using a 200 cm2 photoelectrochemical-photovoltaic device. J Power Sources 2020;454:227890.

139. Song R, Luo B, Geng J, Song D, Jing D. Photothermocatalytic hydrogen evolution over Ni2P/TiO2 for full-spectrum solar energy conversion. Ind Eng Chem Res 2018;57:7846-54.

140. Hu S, Geng J, Jing D. Photothermal effect promoting photocatalytic process in hydrogen evolution over graphene-based nanocomposite. Top Catal 2021.

141. Gao M, Connor PKN, Ho GW. Plasmonic photothermic directed broadband sunlight harnessing for seawater catalysis and desalination. Energy Environ Sci 2016;9:3151-60.

142. Hu S, Shi J, Luo B, Ai C, Jing D. Significantly enhanced photothermal catalytic hydrogen evolution over Cu2O-rGO/TiO2 composite with full spectrum solar light. J Colloid Interface Sci 2022;608:2058-65.

143. Zhang L, Zhang X, Mo H, et al. Synergistic modulation between non-thermal and thermal effects in photothermal catalysis based on modified In2O3. ACS Appl Mater Interfaces 2023;15:39304-18.

144. Ding L, Li K, Li J, et al. Integrated coupling utilization of the solar full spectrum for promoting water splitting activity over a CIZS semiconductor. ACS Nano 2023;17:11616-25.

145. Han H, Meng X. Hydrothermal preparation of C3N4 on carbonized wood for photothermal-photocatalytic water splitting to efficiently evolve hydrogen. J Colloid Interface Sci 2023;650:846-56.

146. Li J, Ding L, Su Z, et al. Non-lignin constructing the gas-solid interface for enhancing the photothermal catalytic water vapor splitting. Adv Mater 2023;35:e2305535.

147. Wu Z, Li C, Li Z, et al. Niobium and titanium carbides (MXenes) as Superior photothermal supports for CO2 photocatalysis. ACS Nano 2021;15:5696-705.

148. Zhang J, Li M, Tan X, et al. Confined FeNi alloy nanoparticles in carbon nanotubes for photothermal oxidative dehydrogenation of ethane by carbon dioxide. Appl Catal B 2023;339:123166.

149. Zhang J, Xie K, Jiang Y, et al. Photoinducing different mechanisms on a Co-Ni bimetallic alloy in catalytic dry reforming of methane. ACS Catal 2023;13:10855-65.

150. Huang Y, Hu H, Wang S, Balogun M, Ji H, Tong Y. Low concentration nitric acid facilitate rapid electron-hole separation in vacancy-rich bismuth oxyiodide for photo-thermo-synergistic oxidation of formaldehyde. Appl Catal B 2017;218:700-8.

151. Huang Y, Lu Y, Lin Y, et al. Cerium-based hybrid nanorods for synergetic photo-thermocatalytic degradation of organic pollutants. J Mater Chem A 2018;6:24740-7.

152. Xiong R, Tang C, Li K, et al. Plasmon photothermal-promoted solar photocatalytic hydrogen production over a CoCr2O4/g-C3N4 heterojunction. J Mater Chem A 2022;10:22819-33.

153. Lin Z, Gao Q, Diao P. Promoting the electrocatalytic oxygen evolution reaction on NiCo2O4 with infrared-thermal effect: a strategy to utilize the infrared solar energy to reduce activation energy during water splitting. J Colloid Interface Sci 2023;638:54-62.

154. Dong B, Li F, Feng S. A visible-IR responsive BiVO4/TiO2 photoanode with multi-effect point defects for photothermal enhancement of photoelectrochemical water splitting. Chem Commun 2022;58:1621-4.

155. Zhang H, Lu Y, Han W, Zhu J, Zhang Y, Huang W. Solar energy conversion and utilization: towards the emerging photo-electrochemical devices based on perovskite photovoltaics. Chem Eng J 2020;393:124766.

156. Kim S, Piao G, Han DS, Shon HK, Park H. Solar desalination coupled with water remediation and molecular hydrogen production: a novel solar water-energy nexus. Energy Environ Sci 2018;11:344-53.

157. Cai H, Li L, Ni H, Xiao G, Yue Z, Jiang F. GeSe-based photovoltaic thin film photoelectrode for natural seawater desalination. Sep Purif Technol 2023;318:124034.

158. Kim YJ, Hong H, Yun J, Kim SI, Jung HY, Ryu W. Photosynthetic nanomaterial hybrids for bioelectricity and renewable energy systems. Adv Mater 2021;33:e2005919.

159. Zhou Y, Ma Y, Wang X, et al. Leaf-structure-inspired through-hole electrode with boosted mass transfer and photothermal effect for oxygen evolution reactions. Adv Funct Mater 2023;33:2304296.

160. Zhang B, Luo H, Ai B, et al. Modulating surface electron density of heterointerface with bio-inspired light-trapping nano-structure to boost kinetics of overall water splitting. Small 2023;19:e2205431.

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