Steering the formation of supported Pt–Sn nanoalloys by reactive metal–oxide interaction

Neitzel, Armin; Kovács, Gâbor; Lykhach, Yaroslava; Tsud, Nataliya; Kozlov, Sergey M.; Škála, Tomáš; Vorokhta, Mykhailo; Matolín, Vladimı́r; Neyman, Konstantin M.; Libuda, Jörg

doi:10.1039/c6ra18801j

Cited by 7 publications

(4 citation statements)

References 44 publications

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“…Neitzel et al. prepared Pt‐Sn nanoparticles with very small particles sizes which were supported on a reactive metal oxide (CeO 2 ) by depositing Pt on Sn‐CeO 2 under ultra‐high vacuum to facilitate reduction of Sn 2+ to yield Sn blended with Pt. The vacuum enabled the complete reduction of all the ions to metallic Pt and Sn.…”

Section: Introductionmentioning

confidence: 99%

Pt‐Sn Nanoparticles Supported on Carbon Nanodots as Anode Catalysts for Alcohol Electro‐oxidation in Acidic Conditions

2018

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The Pt‐Sn/CNDs electrocatalyst was synthesized by the alcohol reduction method with the aim to reduce platinum loading and improve electroactivity. XPS results showed that the nanoparticles were present in the form of Pt‐Sn metallic alloy with a significant amount of SnO‐ species which facilitate the rapid oxidation of CO intermediates. The lattice parameter of Pt in Pt‐Sn/CNDs electrocatalyst was calculated to be 0.3926 nm; this value is higher than 0.3921 nm, the lattice parameter of Pt in Pt/CNDs electrocatalyst. XRD results proved that incorporating tin (Sn) into the Pt/CNDs electrocatalyst modifies the face centred cubic shape of platinum to a crystalline structure which improves the alcohol electro‐oxidation reactions. The electrochemical tests proved that the Pt‐Sn/CNDs electrocatalyst exhibited high current densities and lower poisoning rates compared to the Pt/CNDs and Pt/C electrocatalysts. The Pt‐Sn/CNDs electrocatalyst showed the greatest electroactivity for both methanol and ethanol electro‐oxidation reactions.

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Section: Introductionmentioning

confidence: 99%

Pt‐Sn Nanoparticles Supported on Carbon Nanodots as Anode Catalysts for Alcohol Electro‐oxidation in Acidic Conditions

2018

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“…This shift to higher binding energy is attributed to the formation of a Sn–Pt alloy, given that the metallic Sn(3d 5/2 ) binding energy is 0.3–0.6 eV higher in Pt–Sn alloy nanoparticles; , a similar shift of +0.2–0.3 eV is observed for Sn alloyed into Pt(111) surfaces. ,, The loss of the SnO x peak is ascribed to the diffusion of Sn away from the interface with TiO 2 and into the interior of the cluster in order to increase the favorable interactions between Pt and Sn atoms . The relatively large heat of formation (30–80 kJ/mol) for intermetallic PtSn compounds favors alloying over the monometallic phases. − Similarly, the deposition of 0.13 ML Pt on 0.13 ML Sn causes a decrease in the SnO x intensity and a smaller shift in the Sn(3d 5/2 ) binding energy of +0.1 eV. For both the low and high coverage surfaces, the Sn(3d 5/2 ) binding energy of SnO x also shifts by −0.3 eV after Pt deposition and could be related to disruption of the SnO x phases following the addition of Pt atoms.…”

Section: Resultsmentioning

confidence: 85%

“…The Pt(4f) spectra for pure Pt and Sn on Pt (θ Pt,Sn = 0.05 and 0.13 ML) show that there is a small 0.2 eV shift to higher binding energy after Sn deposition on the Pt clusters for both coverages (Figure S2). Since the surface of the clusters is expected to be Sn-rich based on the lower surface free energy of Sn compared to Pt, the shift in the Pt(4f) peaks could be attributed in part to a surface core level shift due to the loss of the low binding energy, undercoordinated Pt atoms at the surface. , However, a positive shift (∼+0.3 eV) in Pt(4f 7/2 ) binding energy is also consistent with Pt–Sn alloying, ,,,,,− which is expected to occur, given the ability of Pt–Sn systems to alloy over a wide range of compositions …”

Section: Resultsmentioning

confidence: 88%

Oxidation of Sn at the Cluster–Support Interface: Sn and Pt–Sn Clusters on TiO₂(110)

et al. 2021

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The growth of Sn and Pt–Sn clusters on TiO2(110) has been studied by scanning tunneling microscopy, X-ray photoelectron spectroscopy (XPS), low energy ion scattering (LEIS), and density functional theory (DFT). At low Sn coverages (0.02 ML), single-layer high clusters of SnO x are formed with a narrow size distribution and uniform spatial distribution. XPS experiments indicate that these clusters consist of oxidized Sn, and the corresponding reduction in the TiO2 substrate is observed. At higher Sn coverages, the surface is still dominated by two-dimensional clusters of SnO x , but larger three-dimensional clusters of metallic Sn also appear. As the Sn coverage is increased, the number of three-dimensional clusters increases, and the ratio of Sn/SnO x increases, suggesting that SnO x and reduced TiO x form at the cluster–support interface. When Pt is deposited on top of the Sn/SnO x clusters, the relatively mobile Pt atoms diffuse across the TiO2 surface and become incorporated into existing Sn/SnO x clusters. Furthermore, the addition of Pt to the Sn/SnO x clusters causes the reduction of SnO x to metallic Sn and the oxidation of Ti3+ to Ti4+; this behavior is attributed to the formation of Pt–Sn alloy clusters, which results in the diffusion of Sn away from the interface with the TiO2 support. In contrast, when Sn is deposited on an equal coverage of Pt clusters, new Sn/SnO x clusters are formed that coexist with Pt–Sn clusters. However, the surfaces of both Pt on Sn and Sn on Pt clusters are Sn-rich due to the lower surface free energy of Sn compared to Pt. DFT calculations demonstrate that M–TiO2 bonding is favored over M–M bonding for M = Sn, unlike for transition metals such as M = Pt, Au, Ni, and Co. Furthermore, the substantial charge transfer from Sn to TiO2 leads to dipole–dipole repulsion of Sn atoms that prevents agglomeration into the larger clusters that are observed for the mid-late transition metals. DFT studies also confirm that the addition of Pt to a Sn cluster results in strong Pt–Sn bond formation and diminished Sn–O interactions.

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“…We believe that the mechanism of Co 2+ reduction is associated with the reactive metal-support interaction (RMSI) [45,46] between the Pt and the Co-CeO2 solid solution coupled with the reduction of Co 2+ to Co 0 followed by its diffusion to Pt. The similar effect was also observed upon deposition of Pt onto Sn-doped CeO2(111) film at 300 K in UHV [45]. The reactive interaction of Pt with Sn 2+ led to the reduction of Sn 2+ yielding supported Pt-Sn nanoalloys.…”

Section: Co@pt Nanostructure On Ceo2(111)mentioning

confidence: 99%

Nanoscale architecture of ceria-based model catalysts: Pt–Co nanostructures on well-ordered CeO2(111) thin films

Lykhach

Škála

Neitzel

et al. 2020

Chinese Journal of Catalysis

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Steering the formation of supported Pt–Sn nanoalloys by reactive metal–oxide interaction

Cited by 7 publications

References 44 publications

Pt‐Sn Nanoparticles Supported on Carbon Nanodots as Anode Catalysts for Alcohol Electro‐oxidation in Acidic Conditions

Pt‐Sn Nanoparticles Supported on Carbon Nanodots as Anode Catalysts for Alcohol Electro‐oxidation in Acidic Conditions

Oxidation of Sn at the Cluster–Support Interface: Sn and Pt–Sn Clusters on TiO₂(110)

Nanoscale architecture of ceria-based model catalysts: Pt–Co nanostructures on well-ordered CeO2(111) thin films

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Steering the formation of supported Pt–Sn nanoalloys by reactive metal–oxide interaction

Cited by 7 publications

References 44 publications

Pt‐Sn Nanoparticles Supported on Carbon Nanodots as Anode Catalysts for Alcohol Electro‐oxidation in Acidic Conditions

Pt‐Sn Nanoparticles Supported on Carbon Nanodots as Anode Catalysts for Alcohol Electro‐oxidation in Acidic Conditions

Oxidation of Sn at the Cluster–Support Interface: Sn and Pt–Sn Clusters on TiO2(110)

Nanoscale architecture of ceria-based model catalysts: Pt–Co nanostructures on well-ordered CeO2(111) thin films

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Oxidation of Sn at the Cluster–Support Interface: Sn and Pt–Sn Clusters on TiO₂(110)