[1] SHI Y. Research on energy saving management models for coal- fired power plants in the context of new energy[J]. Smart Systems and Green Energy, 17(2023).

[2] LAERO C, FERRARI M D[M]. Bioethanol production from food crops, 147.

[3] HUANG L, ZAMAN S, TIAN X et al. Advanced platinum-based oxygen reduction electrocatalysts for fuel cells[J]. Accounts of Chemical Research, 311(2021).

[4] WANG Y, CHU F, ZENG J et al. Single atom catalysts for fuel cells and rechargeable batteries: principles, advances, and opportunities[J]. ACS Nano, 210(2021).

[5] SUN H, ZHAO L, YU F. Synthesis and characterization of Pt-V- SnO₂/C electrocatalysts for ethanol oxidation in acidic media[J]. International Journal of Electrochemical Science, 2768(2013).

[6] GRUZEŁ G, PIEKARZ P, PAWLYTA M et al. Preparation of Pt-skin PtRhNi nanoframes decorated with small SnO₂ nanoparticles as an efficient catalyst for ethanol oxidation reaction[J]. ACS Applied Materials & Interfaces, 22352(2019).

[7] ZHANG W, YANG Y, HUANG B et al. Ultrathin PtNiM (M=Rh, Os, and Ir) nanowires as efficient fuel oxidation electrocatalytic materials[J]. Advanced Materials, 1805833(2019).

[10] LI L, YUAN X, XIA X et al. The effect of Mo doping on the catalytic performance of Pt/C catalyst for ethanol oxidation[J]. Journal of Inorganic Materials, 1044(2014).

[11] GUO R, WANG J, AN S et al. Effect of cerium oxide prepared under different hydrothermal time on electrocatalytic performance of Pt-based anode catalysts[J]. Journal of Rare Earths, 384(2020).

[12] YI L, YU B, YI W et al. Carbon-supported bimetallic platinum-iron nanocatalysts: application in direct borohydride/hydrogen peroxide fuel cell[J]. ACS Sustainable Chemistry & Engineering, 8142(2018).

[13] TU W Z, LUO W J, CHEN C L et al. Tungsten as “adhesive” in Pt₂CuW_0.25 ternary alloy for highly durable oxygen reduction electrocatalysis[J]. Advanced Functioanal Materials, 1908230(2020).

[14] CHEN Y, ZHOU Y, TANG Y et al. Electrocatalytic properties of carbon-supported Pt-Ru catalysts with the high alloying degree for formic acid electrooxidation[J]. Journal of Power Sources, 4129(2010).

[15] ZHENG H, DENG D, ZHENG X et al. Highly reversible Zn-air batteries enabled by tuned valence electron and steric hindrance on atomic Fe-N4-C sites[J]. Nano Letters, 4672(2024).

[16] SUN L, WANG H, EID K et al. Shape-controlled synthesis of porous AuPt nanoparticles and their superior electrocatalytic activity for oxygen reduction reaction[J]. Science and Technology of Advanced Materials, 58(2016).

[17] FANG D, HE F, XIE J et al. Calibration of binding energy positions with C1s for XPS results[J]. Journal of Wuhan University of Technology-Mater. Sci. Ed., 711(2020).

[18] SHI H L, WANG R Y, LOU M R et al. A novel Pt/pyridine ionic liquid polyoxometalate/rGO tri-component hybrid and its enhancedactivities for methanol electrooxidation[J]. Electrochim Acta, 93(2019).

[19] ZHANG J, WANG J, LIU Y et al. High-performance lithium iron phosphate with phosphorus-doped carbon layers for lithium ion batteries[J]. Journal of Materials Chemistry A, 3(5), 2043(2015).

[20] ZHU T, HENSEN E J M, VAN SANTEN R A et al. Roughening of Pt nanoparticles induced bysurface-oxide formation[J]. Physical Chemistry Chemical Physics, 2268(2013).

[21] HUANG M, JIANG Y, JIN C et al. Pt-Cu alloy with high density of surface Pt defects for efficient catalysis of breaking C-C bond in ethanol[J]. Electrochimica Acta, 29(2014).

[22] MAI T P, CHIKU M, HIGUCHI E et al. Structure-controlled Rh/Sn/Pt ternary catalysts for complete oxidation reaction of ethanol to carbon dioxide[J]. ECS Transaction, 675(2015).

[24] PENG H, REN J, WANG Y et al. One-stone, two birds: alloying effect and surface defects induced by Pt on Cu_2-xSe nanowires to boost CC bond cleavage for electrocatalytic ethanol oxidation[J]. Nano Energy, 106307(2021).

[25] MO Y, GUO R, AN S et al. Preparation of broom strong cerium oxide and its effect on the performance of Pt based anode catalysts[J]. Journal of Inorganic Materials, 1991(2018).

[26] TIAN X L, ZHAO X, SU Y Q et al. Engineering bunched Pt-Ni alloy nanocages for efficient oxygen reduction in practical fuel cells[J]. Science, 850(2019).

[27] ZOU L L, FAN J, ZHOU Y et al. Conversion of PtNi alloy from disordered to ordered for enhanced activity and durability in methanol- tolerant oxygen reduction reactions[J]. NanoResearch, 2777(2015).

[28] SARAVANAN C, MARKOVIC N M, HEAD-GORDON M et al. Stripping and bulk Co electro-oxidation at the Pt electrode interface: dynamic Monte Carlo simulations[J]. The Journal of Chemical Physics, 6404(2001).

[29] SHI Y, MA Z R, XIAO Y Y et al. Electronic metal-support interaction modulates single-atom platinum catalysis for hydrogen evolution reaction[J]. Nature Communications, 3021(2021).

[30] WEI Z Z, YAO Z H, ZHOU Q et al. Optimizing alkyne hydrogenation performance of Pd on carbon in situ decorated with oxygen- deficient TiO₂ by integrating the reaction and diffusion[J]. ACS Catalysis, 10656(2019).

[31] ZHU Y M, BU L Z, SHAO Q et al. Structurally ordered Pt₃Sn nanofibers with highlighted antipoisoning property as efficient ethanol oxidation electrocatalysts[J]. ACS Catalysis, 3455(2020).

[32] YAO Y, GUO R, AN S. In situ loaded Pt-Co high index facets catalysts: preparation and electrocatalytic performance[J]. Journal of Inorganic Materials, 71(2023).

[34] LIU J, ZHANG H, GONG H et al. Polyethylene/polypropylene bicomponent spunbond air filtration materials containing magnesium stearate for efficient fine particle capture[J]. ACS Applied Materials & Interfaces, 40592(2019).

[36] ZHOU Q, PAN Z, WU D et al. Pt-CeO₂/TiN NTs derived from metal organic frameworks as high-performance electrocatalyst for methanol electrooxidation[J]. International Journal of Hydrogen Energy, 10646(2019).

[38] LIU H, WANG S, JIA F. Conversion of commercial Pt/C to clean Pt-Cu/C catalyst with high activity toward methanol oxidation[J]. Electrochimica Acta, 331(2015).

[39] SUN Q, KIM S. Synthesis of nitrogen-doped graphene supported Pt nanoparticles catalysts and their catalytic activity for fuel cell[J]. Electrochimica Acta, 566(2015).

[40] RIBADENEIRA E, HOYOS B A. Evaluation of Pt-Ru-Ni and Pt-Sn-Ni catalysts as anodes indirect ethanol fuel cells[J]. Journal of Power Sources, 238(2008).

[41] GUO R, MO Y, AN S et al. Controllable synthesis of cerium oxide hollow spheres and their influence on the electrocatalytic performance of Pt based catalysts[J]. Journal of Inorganic Materials, 779(2018).