Millisecond-timescale electrodeposition of platinum atom-doped molybdenum oxide as an efficient electrocatalyst for hydrogen evolution reaction

Yi XIAO; Wenxue SHANG; Jiyuan FENG; Airu YU; Lu CHEN; Liqiu ZHANG; Hongxia SHEN; Qiong CHENG; Lichun LIU; Song BAI

doi:10.1007/s11706-022-0606-8

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Front. Mater. Sci. ›› 2022, Vol. 16 ›› Issue (3) : 220606. DOI: 10.1007/s11706-022-0606-8

RESEARCH ARTICLE

Millisecond-timescale electrodeposition of platinum atom-doped molybdenum oxide as an efficient electrocatalyst for hydrogen evolution reaction

Yi XIAO¹^,² ,
Wenxue SHANG²^,³ ,
Jiyuan FENG² ,
Airu YU²^,⁴ ,
Lu CHEN¹^,² ,
Liqiu ZHANG² ,
Hongxia SHEN² ,
Qiong CHENG² ,
Lichun LIU¹^,²^,³^,⁴ ,
Song BAI¹

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Abstract

We present a straightforward method for one-pot electrodeposition of platinum atoms-doped molybdenum oxide (Pt·MoO_3−x) films and show their superior electrocatalytic activity in the hydrogen evolution reaction (HER). A ~15-nm-thick Pt·MoO_3−x film was prepared by one-pot electrodeposition at −0.8 V for 1 ms. Due to considerably different solute concentrations, the content of Pt atoms in the electrodeposited composite electrocatalyst is low. No Pt crystals or islands were observed on the flat Pt·MoO_3−x films, indicating that Pt atoms were homogeneously dispersed within the MoO_3−x thin film. The catalytic performance and physicochemical features of Pt·MoO_3−x as a HER electrocatalyst were characterized. The results showed that our Pt·MoO_3−x film exhibits 23- and 11-times higher current density than Pt and MoO_3−x electrodeposited individually under the same conditions, respectively. It was found that the dramatic enhancement in the HER performance was principally due to the abundant oxygen defects. The use of the developed one-pot electrodeposition and doping method can potentially be extended to various catalytically active metal oxides or hydroxides for enhanced performance in various energy storage and conversion applications.

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platinum / molybdenum oxide / electrodeposition / hydrogen evolution reaction / doping / electrocatalyst

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Yi XIAO, Wenxue SHANG, Jiyuan FENG, Airu YU, Lu CHEN, Liqiu ZHANG, Hongxia SHEN, Qiong CHENG, Lichun LIU, Song BAI. Millisecond-timescale electrodeposition of platinum atom-doped molybdenum oxide as an efficient electrocatalyst for hydrogen evolution reaction. Front. Mater. Sci., 2022, 16(3): 220606 https://doi.org/10.1007/s11706-022-0606-8

References

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

[1]	Abe J O, Popoola A P I, Ajenifuja E, , . Hydrogen energy, economy and storage: review and recommendation. International Journal of Hydrogen Energy, 2019, 44( 29): 15072– 15086 CrossRef Google scholar

[2]	Dawood F, Anda M, Shafiullah G M . Hydrogen production for energy: an overview. International Journal of Hydrogen Energy, 2020, 45( 7): 3847– 3869 CrossRef Google scholar

[3]	Ren J, Gao S, Liang H, , . Chapter 1 — The role of hydrogen energy: strengths, weaknesses, opportunities, and threats. In: Scipioni A, Manzardo A, Ren J, eds. Hydrogen Economy: Supply Chain, Life Cycle Analysis and Energy Transition for Sustainability. Academic Press, 2017, 1– 33

[4]	Zhu J, Hu L, Zhao P, , . Recent advances in electrocatalytic hydrogen evolution using nanoparticles. Chemical Reviews, 2020, 120( 2): 851– 918 CrossRef Pubmed Google scholar

[5]	Zou X, Zhang Y . Noble metal-free hydrogen evolution catalysts for water splitting. Chemical Society Reviews, 2015, 44( 15): 5148– 5180 CrossRef Pubmed Google scholar

[6]	Zheng Y, Jiao Y, Vasileff A, , . The hydrogen evolution reaction in alkaline solution: from theory, single crystal models, to practical electrocatalysts. Angewandte Chemie International Edition in English, 2018, 57( 26): 7568– 7579 CrossRef Pubmed Google scholar

[7]	Zhang A, Liang Y, Zhang H, , . Doping regulation in transition metal compounds for electrocatalysis. Chemical Society Reviews, 2021, 50( 17): 9817– 9844 CrossRef Pubmed Google scholar

[8]	de Castro I A, Datta R S, Ou J Z, , . Molybdenum oxides — from fundamentals to functionality. Advanced Materials, 2017, 29( 40): 1701619– 1701649 CrossRef Pubmed Google scholar

[9]	Saji V S, Lee C W . Molybdenum, molybdenum oxides, and their electrochemistry. ChemSusChem, 2012, 5( 7): 1146– 1161 CrossRef Pubmed Google scholar

[10]	Luo Z, Miao R, Huan T D, , . Mesoporous MoO_3−x material as an efficient electrocatalyst for hydrogen evolution reactions. Advanced Energy Materials, 2016, 6( 16): 1600528– 1600538 CrossRef Google scholar

[11]	Tang Y J, Gao M R, Liu C H, , . Porous molybdenum-based hybrid catalysts for highly efficient hydrogen evolution. Angewandte Chemie International Edition in English, 2015, 54( 44): 12928– 12932 CrossRef Pubmed Google scholar

[12]	Hua W, Sun H H, Xu F, , . A review and perspective on molybdenum-based electrocatalysts for hydrogen evolution reaction. Rare Metals, 2020, 39( 4): 335– 351 CrossRef Google scholar

[13]	Jian C, Cai Q, Hong W, , . Enhanced hydrogen evolution reaction of MoO_x/Mo cathode by loading small amount of Pt nanoparticles in alkaline solution. International Journal of Hydrogen Energy, 2017, 42( 27): 17030– 17037 CrossRef Google scholar

[14]	Datta R S, Haque F, Mohiuddin M, , . Highly active two dimensional α-MoO_3−x for the electrocatalytic hydrogen evolution reaction. Journal of Materials Chemistry A: Materials for Energy and Sustainability, 2017, 5( 46): 24223– 24231 CrossRef Google scholar

[15]	Haque F, Zavabeti A, Zhang B Y, , . Ordered intracrystalline pores in planar molybdenum oxide for enhanced alkaline hydrogen evolution. Journal of Materials Chemistry A: Materials for Energy and Sustainability, 2019, 7( 1): 257– 268 CrossRef Google scholar

[16]	Gomez Vidales A, Omanovic S . Evaluation of nickel‒molybdenum-oxides as cathodes for hydrogen evolution by water electrolysis in acidic, alkaline, and neutral media. Electrochimica Acta, 2018, 262: 115– 123 CrossRef Google scholar

[17]	Mardosaitė R, Valatka E . S-containing molybdenum oxide films as pH neutral hydrogen evolution electrocatalyst prepared by electrodeposition. International Journal of Electrochemical Science, 2019, 14( 1): 387– 401 CrossRef Google scholar

[18]	Li L, Zhang T, Yan J, , . P doped MoO_3−x nanosheets as efficient and stable electrocatalysts for hydrogen evolution. Small, 2017, 13( 25): 1700441– 1700447 CrossRef Pubmed Google scholar

[19]	Xu N, Cao G, Gan L, , . Carbon-coated cobalt molybdenum oxide as a high-performance electrocatalyst for hydrogen evolution reaction. International Journal of Hydrogen Energy, 2018, 43( 52): 23101– 23108 CrossRef Google scholar

[20]	Hu B, Jian S, Yin G, , . Hetero-element-doped molybdenum oxide materials for energy storage systems. Nanomaterials, 2021, 11( 12): 3302– 3317 CrossRef Pubmed Google scholar

[21]	Jiang P, Yang Y, Shi R, , . Pt-like electrocatalytic behavior of Ru–MoO₂ nanocomposites for the hydrogen evolution reaction. Journal of Materials Chemistry A: Materials for Energy and Sustainability, 2017, 5( 11): 5475– 5485 CrossRef Google scholar

[22]	Liu S, Chen C, Zhang Y, , . Vacancy-coordinated hydrogen evolution reaction on MoO_3−x anchored atomically dispersed MoRu pairs. Journal of Materials Chemistry A: Materials for Energy and Sustainability, 2019, 7( 24): 14466– 14472 CrossRef Google scholar

[23]	Lee D, Kim Y, Kim H W, , . In situ electrochemically synthesized Pt‒MoO_3−x nanostructure catalysts for efficient hydrogen evolution reaction. Journal of Catalysis, 2020, 381: 1– 13 CrossRef Google scholar

[24]	Xu J, Zhang C, Liu H, , . Amorphous MoO_x-stabilized single platinum atoms with ultrahigh mass activity for acidic hydrogen evolution. Nano Energy, 2020, 70: 104529– 104536 CrossRef Google scholar

[25]	Shang W, Xiao Y, Yu A, , . Visible-light-enhanced electrocatalytic hydrogen evolution using electrodeposited molybdenum oxide. Journal of the Electrochemical Society, 2022, 169( 3): 034529– 034535 CrossRef Google scholar

[26]	Klein J, Engstfeld A K, Brimaud S, , . Pt nanocluster size effects in the hydrogen evolution reaction: approaching the theoretical maximum activity. Physical Chemistry Chemical Physics, 2020, 22( 34): 19059– 19068 CrossRef Pubmed Google scholar

[27]	Sun J, Zhang X, Jin M, , . Robust enhanced hydrogen production at acidic conditions over molybdenum oxides-stabilized ultrafine palladium electrocatalysts. Nano Research, 2021, 14( 1): 268– 274 CrossRef Google scholar

[28]	Seguin L, Figlarz M, Cavagnat R, , . Infrared and Raman spectra of MoO₃ molybdenum trioxides and MoO₃·xH₂O molybdenum trioxide hydrates. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 1995, 51( 8): 1323– 1344 CrossRef Google scholar

[29]	Ji F, Ren X, Zheng X, , . 2D-MoO₃ nanosheets for superior gas sensors. Nanoscale, 2016, 8( 16): 8696– 8703 CrossRef Pubmed Google scholar

[30]	Dieterle M, Weinberg G, Mestl G . Raman spectroscopy of molybdenum oxides. Part I: Structural characterization of oxygen defects in MoO_3−x by DR UV/VIS, Raman spectroscopy and X-ray diffraction. Physical Chemistry Chemical Physics , 2002, 4: 812– 821 CrossRef Google scholar

[31]	Pan W, Tian R, Jin H, , . Structure, optical, and catalytic properties of novel hexagonal metastable h-MoO₃ nano- and microrods synthesized with modified liquid-phase processes. Chemistry of Materials, 2010, 22( 22): 6202– 6208 CrossRef Google scholar