Unlocking the potential of hematite photoanodes in acidic electrolytes: Boosting performance with ultra-small IrOx nanoparticles for efficient water splitting

Shao-Yu Yuan; Tian-Tian Li; Jun-Yuan Cui; Jian-Kun Sun; Yan-Shang Gong; Artur Braun; Hong Liu; Jian-Jun Wang

doi:10.1002/ece2.41

EcoEnergy ›› 2024, Vol. 2 ›› Issue (2) : 322 -335. DOI: 10.1002/ece2.41

RESEARCH ARTICLE

Unlocking the potential of hematite photoanodes in acidic electrolytes: Boosting performance with ultra-small IrO_x nanoparticles for efficient water splitting

Shao-Yu Yuan ¹
, Tian-Tian Li ¹
, Jun-Yuan Cui ¹
, Jian-Kun Sun ²^,^†
, Yan-Shang Gong ²
, Artur Braun ³^,^†
, Hong Liu ¹^,⁴^,^†
, Jian-Jun Wang ¹^,⁵^,^†

Author information +

History +

PDF

Abstract

Photoelectrochemical (PEC) water splitting offers a promising route for harnessing solar energy to produce clean hydrogen fuel sustainably. A major hurdle has been boosting the performance of photoanode materials within acidic electrolytes—a critical aspect for advancing PEC technology. In response to this challenge, we report a method to augment the efficacy of hematite photoanodes under acidic conditions by anchoring IrO_x nanoparticles, replete with hydroxyl groups, onto their surface. A remarkable and steady photocurrent density of 1.71 mA cm⁻² at 1.23 V versus RHE was achieved, marking a significant leap in PEC efficiency of hematite in acidic media. The introduction of the IrO_x layer notably expanded the electrochemically active surface area for more active sites, fostering improved charge separation and transfer. It also served as an effective hole capture layer, drawing photogenerated holes from hematite to facilitate swift migration to the active sites for the water oxidation process. This advancement has the potential to fully harness the capabilities of hematite photoanodes in acidic environments, thereby smoothing the path toward more effective and sustainable hydrogen production through PEC water splitting.

Keywords

acidic electrolytes / hematite photoanodes / IrOx nanoparticles / photoelectrochemical cells / water splitting

Cite this article

Download citation ▾

Shao-Yu Yuan, Tian-Tian Li, Jun-Yuan Cui, Jian-Kun Sun, Yan-Shang Gong, Artur Braun, Hong Liu, Jian-Jun Wang. Unlocking the potential of hematite photoanodes in acidic electrolytes: Boosting performance with ultra-small IrO_x nanoparticles for efficient water splitting. EcoEnergy, 2024, 2(2): 322-335 DOI:10.1002/ece2.41

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	YaoN, JiaH, ZhuJ, et al. Atomically dispersed Ru oxide catalyst with lattice oxygen participation for efficient acidic water oxidation. Chem. 2023;9(7):1882-1896.

[2]	YiP, SongY, LiC, LiuR, SunJ. Heterostructured Mn-doped NiS_x/NiO/Ni₃N nanoplate arrays as bifunctional electrocatalysts for energy-saving hydrogen production and urea degradation. Appl Surf Sci. 2023;619:156789.

[3]	ScholesGD, Fleming GR, Olaya-CastroA, van GrondelleR. Lessons from nature about solar light harvesting. Nat Chem. 2011;3(10):763-774.

[4]	GaoRT, LiuL, LiY, et al. Ru-p pair sites boost charge transport in hematite photoanodes for exceeding 1% efficient solar water splitting. Proc Natl Acad Sci USA. 2023;120(27):e2300493120.

[5]	SongY, RenY, ChengH, et al. Metal-organic framework glass catalysts from melting glass-forming cobalt-based zeolitic imidazolate framework for boosting photoelectrochemical water oxidation. Angew Chem Int Ed. 2023;62(32):e202306420.

[6]	YinZ-H, HuangY, JiangL-W, et al. Revealing the in situ evolution of tetrahedral NiMoO₄ micropillar array for energyefficient alkaline hydrogen production assisted by urea electrolysis. Small Struct. 2023;4(9):2300028.

[7]	TamiratAG, RickJ, DubaleAA, Su W-N, HwangB-J. Using hematite for photoelectrochemical water splitting: a review of current progress and challenges. Nanoscale Horiz. 2016;1(4):243-267.

[8]	LiC-C, LuoZ-B, WangT, Gong J-L. Surface, bulk, and interface: rational design of hematite architecture toward efficient photoelectrochemical water splitting. Adv Mater. 2018;30(30):1707502.

[9]	Ben-NaimM, PalmDW, StricklerAL, et al. A spin coating method to deposit iridium-based catalysts onto silicon for water oxidation photoanodes. ACS Appl Mater Interfaces. 2020;12(5):5901-5908.

[10]	GuoQ, ZhaoQ, Crespo-OteroR, et al. Single-atom iridium on hematite photoanodes for solar water splitting: catalyst or spectator? J Am Chem Soc. 2023;145(3):1686-1695.

[11]	RakhiRB, ChenW, HedhiliMN, Cha D, AlshareefHN. Enhanced rate performance of mesoporous CO₃O₄ nanosheet supercapacitor electrodes by hydrous RuO₂ nanoparticle decoration. ACS Appl Mater Interfaces. 2014;6(6):4196-4206.

[12]	LiA, KongS, GuoC, et al. Enhancing the stability of cobalt spinel oxide towards sustainable oxygen evolution in acid. Nat Catal. 2022;5(2):109-118.

[13]	TangT, LiuX, LuoX, et al. Unconventional bilateral compressive strained Ni-Ir interface synergistically accelerates alkaline hydrogen oxidation. J Am Chem Soc. 2023;145(25):13805-13815.

[14]	YangZ, YangH, ShangL, Zhang T. Ordered ptfeir intermetallic nanowires prepared through a silica-protection strategy for the oxygen reduction reaction. Angew Chem Int Ed. 2022;61(8):e202113278.

[15]	TilleySD, CornuzM, SivulaK, Grätzel M. Light-induced water splitting with hematite: improved nanostructure and iridium oxide catalysis. Angew Chem Int Ed. 2010;49(36):6405-6408.

[16]	LiW, Sheehan SW, HeD, et al. Hematite-based solar water splitting in acidic solutions: functionalization by mono-and multilayers of iridium oxygen-evolution catalysts. Angew Chem. 2015;127(39):11590-11594.

[17]	YuanS-Y, JiangL-W, HuJ-S, Liu H, WangJ-J. Fully dispersed irox atomic clusters enable record photoelectrochemical water oxidation of hematite in acidic media. Nano Lett. 2023;23(6):2354-2361.

[18]	LiuC, XuY, LuoH, WangW, LiangQ, Chen Z. Synthesis and photoelectrochemical properties of CoOOH/phosphorusdoped hematite photoanodes for solar water oxidation. Chem Eng J. 2019;363:23-32.

[19]	ChandraD, Katsuki T, MasakiT, et al. Highly efficient electrocatalytic water oxidation by a transparent ordered mesoporous film of intermediate IrO_x(OH)_y. ACS Appl Energy Mater. 2021;4(5):4355-4364.

[20]	AbbottDF, Lebedev D, WaltarK, et al. Iridium oxide for the oxygen evolution reaction: correlation between particle size, morphology, and the surface hydroxo layer from operando xas. Chem Mater. 2016;28(18):6591-6604.

[21]	ChengJ, YangJ, KitanoS, et al. Impact of Ir-valence control and surface nanostructure on oxygen evolution reaction over a highly efficient Ir-TiO₂ nanorod catalyst. ACS Catal. 2019;9(8):6974-6986.

[22]	SmithRDL, Sporinova B, FaganRD, TrudelS, Berlinguette CP. Facile photochemical preparation of amorphous iridium oxide films for water oxidation catalysis. Chem Mater. 2014;26(4):1654-1659.

[23]	PfeiferV, JonesTE, VelezJJV, et al. The electronic structure of iridium oxide electrodes active in water splitting. Phys Chem Chem Phys. 2016;18(4):2292-2296.

[24]	PfeiferV, JonesTE, VelezJJV, et al. The electronic structure of iridium and its oxides. Surf Interface Anal. 2016;48(5):261-273.

[25]	ChenS, ZhangS, GuoL, et al. Reconstructed Ir–O–Mo species with strong bronsted acidity for acidic water oxidation. Nat Commun. 2023;14(1):4127.

[26]	GaoJ, HuangX, CaiW, WangQ, JiaC, LiuB. Rational design of an iridium-tungsten composite with an iridium-rich surface for acidic water oxidation. ACS Appl Mater Interfaces. 2020;12(23):25991-26001.

[27]	CaoD, LuoW, FengJ, Zhao X, LiZ, ZouZ. Cathodic shift of onset potential for water oxidation on a Ti⁴⁺ doped Fe₂O₃ photoanode by suppressing the back reaction. Energy Environ Sci. 2014;7(2):752-759.

[28]	WangZ-Y, LiH-M, YiS-S, et al. In-situ coating of multifunctional FeCo-bimetal organic framework nanolayers on hematite photoanode for superior oxygen evolution. Appl Catal B Environ Energy. 2021;297:120406.

[29]	TangP, XieH, RosC, et al. Enhanced photoelectrochemical water splitting of hematite multilayer nanowire photoanodes by tuning the surface state via bottom-up interfacial engineering. Energy Environ Sci. 2017;10(10):2124-2136.

[30]	KwonJeong I, Mahadik MA, KimS, et al. Transparent zirconium-doped hematite nanocoral photoanode via in-situ diluted hydrothermal approach for efficient solar water splitting. Chem Eng J. 2020;390:124504.

[31]	WangG, LingY, WheelerDA, et al. Facile synthesis of highly photoactive α-Fe₂O₃-based films for water oxidation. Nano Lett. 2011;11(8):3503-3509.

[32]	ZhangY, HuangY, ZhuS-S, et al. Covalent S-O bonding enables enhanced photoelectrochemical performance of Cu₂S/Fe₂O₃ heterojunction for water splitting. Small. 2021;17(30):2100320.

[33]	FanZ, XuZ, YanS, ZouZ. Tuning the ion permeability of an Al₂O₃ coating layer on Fe₂O₃ photoanodes for improved photoelectrochemical water oxidation. J Mater Chem A. 2017;5(18):8402-8407.

[34]	WangJ-J, HuY, TothR, Fortunato G, BraunA. A facile nonpolar organic solution process of a nanostructured hematite photoanode with high efficiency and stability for water splitting. J Mater Chem A. 2016;4(8):2821-2825.

[35]	LiJ, Cushing SK, ZhengP, MengF, ChuD, WuN. Plasmoninduced photonic and energy-transfer enhancement of solar water splitting by a hematite nanorod array. Nat Commun. 2013;4(1):2651.

[36]	HuangY, JiangL-W, LiuH, WangJ-J. Electronic structure regulation and polysulfide bonding of Co-doped (Ni, Fe)_(1+x)S enable highly efficient and stable electrocatalytic overall water splitting. Chem Eng J. 2022;441:136121.

[37]	SilvaTM, Simões AMP, FerreiraMGS, WallsM, Da Cunha Belo M. Electronic structure of iridium oxide films formed in neutral phosphate buffer solution. J Electroanal Chem. 1998;441(1-2):5-12.

[38]	LiH-M, WangZ-Y, JingH-J, et al. Synergetic integration of passivation layer and oxygen vacancy on hematite nanoarrays for boosted photoelectrochemical water oxidation. Appl Catal B Environ Energy. 2021;284:119760.

[39]	XiongD, LiW, WangX, Liu L. Passivation of hematite nanorod photoanodes with a phosphorus overlayer for enhanced photoelectrochemical water oxidation. Nanotechnology. 2016;27(37):375401.

[40]	HuW, LinL, ZhangR, Yang C, YangJ. Highly efficient photocatalytic water splitting over edge-modified phosphorene nanoribbons. J Am Chem Soc. 2017;139(43):15429-15436.

[41]	JeonTH, MoonG-h, ParkH, Choi W. Ultra-efficient and durable photoelectrochemical water oxidation using elaborately designed hematite nanorod arrays. Nano Energy. 2017;39:211-218.

[42]	YiS-S, WulanB-R, YanJ-M, Jiang Q. Highly efficient photoelectrochemical water splitting: surface modification of cobaltphosphate-loaded CO₃O₄/Fe₂O₃ p-n heterojunction nanorod arrays. Adv Funct Mater. 2019;29(11):1801902.

[43]	KhanAZ, Kandiel TA, Abdel-AzeimS, JahangirTN, Alhooshani K. Phosphate ions interfacial drift layer to improve the performance of CoFe-prussian blue hematite photoanode toward water splitting. Appl Catal B Environ Energy. 2022;304:121014.

[44]	VenkatachalamA, MarkJAM, DeivatamilD, Revathi J, JesurajJP. Sunlight active photocatalytic studies of Fe₂O₃ based nanocomposites developed via two-pot synthesis technique. Inorg Chem Commun. 2021;124:108417.

[45]	AbidMA, KadhimDA. Novel comparison of iron oxide nanoparticle preparation by mixing iron chloride with henna leaf extract with and without applied pulsed laser ablation for methylene blue degradation. J Environ Chem Eng. 2020;8(5):104138.

[46]	LuY, YangY, FanX, et al. Boosting charge transport in bivO₄ photoanode for solar water oxidation. Adv Mater. 2022;34(8):2108178.

[47]	SongK, HouH, ZhangD, He F, YangW. In-situ cationexchange strategy for engineering single-atomic co on TiO₂ photoanode toward efficient and durable solar water splitting. Appl Catal B Environ Energy. 2023;330:122630.

[48]	KlahrB, Gimenez S, Fabregat-SantiagoF, BisquertJ, Hamann TW. Photoelectrochemical and impedance spectroscopic investigation of water oxidation with “Co-Pi”-coated hematite electrodes. J Am Chem Soc. 2012;134(40):16693-16700.

[49]	KlahrB, Gimenez S, Fabregat-SantiagoF, HamannT, Bisquert J. Water oxidation at hematite photoelectrodes: the role of surface states. J Am Chem Soc. 2012;134(9):4294-4302.

[50]	Badia-BouL, Mas-Marza E, RodenasP, et al. Water oxidation at hematite photoelectrodes with an iridium-based catalyst. J Phys Chem C. 2013;117(8):3826-3833.

[51]	DiasP, Andrade L, MendesA. Hematite-based photoelectrode for solar water splitting with very high photovoltage. Nano Energy. 2017;38:218-231.

[52]	GaoRT, ZhangJ, NakajimaT, et al. Single-atomic-site platinum steers photogenerated charge carrier lifetime of hematite nanoflakes for photoelectrochemical water splitting. Nat Commun. 2023;14(1):2640.

[53]	GaoR-T, NguyenNT, NakajimaT, et al. Dynamic semiconductor-electrolyte interface for sustainable solar water splitting over 600 hours under neutral conditions. Sci Adv. 2023;9(1):eade4589.

[54]	DongZ, ZhouC, ChenW, et al. Cerium dioxide as an electron buffer to stabilize Iridium for efficient water electrolysis. Adv Funct Mater. 2024:2400809.

[55]	ZhuY, ZhangS, ChenR, et al. Controllable electronic transfer tailoring d-band center via cobalt-oxygen-bridged Ru/Fe dualsites for boosted oxygen evolution. Small. 2024:2310611.