Changes in Catalytic and Adsorptive Properties of 2 nm Pt<sub>3</sub>Mn Nanoparticles by Subsurface Atoms

Wu, Zhenwei; Bukowski, Brandon C.; Li, Zhe; Milligan, Cory A.; Zhou, Lin; Ma, Tao; Wu, Yue; Ren, Yang; Ribeiro, Fabio H.; Delgass, W. Nicholas; Greeley, Jeffrey; Zhang, Guanghui; Miller, Jeffrey T.

doi:10.1021/jacs.8b08162

Cited by 145 publications

(152 citation statements)

References 48 publications

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“…The increased olefin selectivities observed for the PtÀ Fe catalysts are consistent with previously reported IMC alkane dehydrogenation catalysts. [43][44][45][46][47][48][49][50][51] It has been proposed that the increased olefin selectivity arises from the elimination of large active-metal ensembles by incorporation of the noncatalytic promoter metals into the active surface. Segregation of the active atoms reduces hydrogenolysis, which is thought to require ensemble active sites.…”

Section: Resultsmentioning

confidence: 99%

Intermetallic Compounds as an Alternative to Single‐atom Alloy Catalysts: Geometric and Electronic Structures from Advanced X‐ray Spectroscopies and Computational Studies

et al. 2020

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Pt−Fe intermetallic compound (IMC) catalysts, including Pt3Fe, PtFe and PtFe3, are shown to have advantageous catalytic properties similar to those reported for single‐atom alloy catalysts. Suppresion of the Pt ensembles responsible for hydrogenolysis results in high olefin selectivity during propane dehydrogenation. In situ resonant inelastic X‐ray scattering (RIXS) results and density functional theory calculations show that these changes are associated with a decrease in the average energy of the filled 5d states of Pt in the Pt−Fe intermetallic compound structures compared to monometallic Pt, accompanied by an increase in the average energy of the unfilled valence bands. The decrease in energy of the filled Pt 5d orbitals increases with increasing Fe content in the IMC, i.e. PtFe3>PtFe>Pt3Fe. These results demonstrate that by altering the stoichiometry of IMC catalysts it is possible to control both the ensemble size and electronic properties of active sites, which affords another mechanism for tuning catalytic properties, in addition to changing promoter metals. The present study demonstrates the potential of ordered intermetallic compounds as an alternative to traditional solid‐solution single‐atom alloys to serve as catalysts with well‐defined and uniform active sites.

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Section: Resultsmentioning

confidence: 99%

Intermetallic Compounds as an Alternative to Single‐atom Alloy Catalysts: Geometric and Electronic Structures from Advanced X‐ray Spectroscopies and Computational Studies

et al. 2020

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“…However, the low abun-dance and CO poisoning of platinum catalysts remain a huge challenge [19]. The use of alloying with transition metals has achieved Pt-based bimetallic or multimetallic electrocatalysts that enable significantly improved activity and durability [20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36][37][38][39]. Meanwhile, precisely controlled fabrication of Pt-based alloys with tailored facets and compositions can not only improve the utilization efficiency of Pt, but also modify the electronic and geometric structures, thus benefiting for achieving higher catalytic activities [40][41][42][43].…”

Section: Introductionmentioning

confidence: 99%

超细PtCu纳米线的表面结构调控及其增强的醇类电催化氧化作用

et al. 2020

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Surface tailoring of Pt-based nanocatalysts is an effective pathway to promote their electrocatalytic performance and multifunctionality. Here, we report two kinds of one-dimensional (1D) ultrafine PtCu nanowires (smooth surface & rugged surface) synthesized via a wet chemical method and their distinct catalytic performances in electrooxidation of alcohols. The alloyed PtCu nanowires having rough surfaces with atomic steps exhibit superior catalytic activity toward multiple electrochemical reactions compared with the smooth counterpart. Density functional theory simulations show the excellent reactivity of rugged PtCu nanowires and attribute it to the surface synergetic Pt-Cu site which accounts for the promotion of water dissociation and the dehydrogenation of the carboxyl intermediate. The current study provides an insight into reasonable design of alloy nanocatalysts in energy-related electrocatalytic systems.

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“…Being a solid-state mixture of two or more metal components, iNPs possess not only modified crystal structures to accommodate different elements, but also altered surface geometric and electronic structures that could directly correlate with catalytic activity and selectivity, 11,12 given that the adsorption of reactive species is highly dependent on the structure of the active sites. [13][14][15] Intermetallic structures tend to minimize their free energy by forming atomic configurations commensurate with strong chemical bonds. As a result, different elements can alternate in specific sites and form ordered phases.…”

Section: Introductionmentioning

confidence: 99%

Toward Phase and Catalysis Control: Tracking the Formation of Intermetallic Nanoparticles at Atomic Scale

Wang

Chen

et al. 2019

Chem

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Intermetallic nanoparticles (iNPs) have yielded enormous successes in catalytic applications by the formation of ordered phases. However, atomic level understanding of the alloying mechanism, which plays a pivotal role for controlling intermetallic phases and tailoring their catalytic properties, is still elusive. In this study, we discovered a consecutive formation of ordered Pt3Sn and PtSn phases during the growth of Pt-Sn iNP inside a well-defined nano-reactor at elevated temperature using in-situ scanning transmission electron microscopy. We found that the surface-mediated diffusion of Sn controls overall dynamics of the reaction, while the unique coherent interfacial structure is determinative for the PtSn transformation. We then further controlled the phase selection of Pt-Sn iNPs and demonstrated their distinguishable catalytic behaviors. Our findings not only provide detailed experimental evidence on the alloying mechanism in intermetallic nanoscale systems, but also pave the way for mechanistic control of synthesis and catalytic properties of iNPs. SUMMARYIntermetallic nanoparticles (iNPs) have yielded enormous successes in catalytic applications by the formation of ordered phases. However, atomic level understanding of the alloying mechanism, which plays a pivotal role for controlling intermetallic phases and tailoring their catalytic properties, is still elusive. In this study, we discovered a consecutive formation of ordered Pt3Sn and PtSn phases during the growth of Pt-Sn iNP inside a well-defined nanoreactor at elevated temperature using in-situ scanning transmission electron microscopy. We found that the surface-mediated diffusion of Sn controls overall dynamics of the reaction, while the unique coherent interfacial structure is determinative for the PtSn transformation. We then further controlled the phase selection of Pt-Sn iNPs and demonstrated their distinguishable catalytic behaviors. Our findings not only provide detailed experimental evidence on the alloying mechanism in intermetallic nanoscale systems, but also pave the way for mechanistic control of synthesis and catalytic properties of iNPs.

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Changes in Catalytic and Adsorptive Properties of 2 nm Pt₃Mn Nanoparticles by Subsurface Atoms

Cited by 145 publications

References 48 publications

Intermetallic Compounds as an Alternative to Single‐atom Alloy Catalysts: Geometric and Electronic Structures from Advanced X‐ray Spectroscopies and Computational Studies

Intermetallic Compounds as an Alternative to Single‐atom Alloy Catalysts: Geometric and Electronic Structures from Advanced X‐ray Spectroscopies and Computational Studies

超细PtCu纳米线的表面结构调控及其增强的醇类电催化氧化作用

Toward Phase and Catalysis Control: Tracking the Formation of Intermetallic Nanoparticles at Atomic Scale

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Changes in Catalytic and Adsorptive Properties of 2 nm Pt3Mn Nanoparticles by Subsurface Atoms

Cited by 145 publications

References 48 publications

Intermetallic Compounds as an Alternative to Single‐atom Alloy Catalysts: Geometric and Electronic Structures from Advanced X‐ray Spectroscopies and Computational Studies

Intermetallic Compounds as an Alternative to Single‐atom Alloy Catalysts: Geometric and Electronic Structures from Advanced X‐ray Spectroscopies and Computational Studies

超细PtCu纳米线的表面结构调控及其增强的醇类 电催化氧化作用

Toward Phase and Catalysis Control: Tracking the Formation of Intermetallic Nanoparticles at Atomic Scale

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Changes in Catalytic and Adsorptive Properties of 2 nm Pt₃Mn Nanoparticles by Subsurface Atoms

超细PtCu纳米线的表面结构调控及其增强的醇类电催化氧化作用