Add to ORKGThe origin of the synergistic catalytic effect between metal catalysts and reducible oxides has been debated for decades. Clarification of this effect, namely, the strong metal-support interaction (SMSI), requires an understanding of the geometric and electronic structures of metal-metal oxide interfaces under operando conditions. We show that the inherent lattice mismatch of bimetallic materials selectively creates surface segregation of subsurface metal atoms. Interfacial metal-metal oxide nanostructures are then formed under chemical reaction environments at ambient pressure, which thus increases the catalytic activity for the CO oxidation reaction. Our in situ surface characterizations using ambient-pressure scanning tunneling microscop...
To determine the optimal structure and size of a cluster suitable for modeling chemical processes on...
Identification of structures of active sites of catalysts under realistic conditions is key for unde...
Supported Au-Ni nanocatalysts consisting of Au nanoparticies decorated with Ni/NiO nanostructures we...
© 2019 Elsevier B.V.The formation of interfacial metal–oxide structures on the Pt3Ni(111)bimetallic ...
Synergetic effect of surface and subsurface Ni species at Pt-Ni bimetallic catalysts for CO oxidatio...
Bimetallic catalysts are widely used in many heterogeneous catalytic processes. With rational design...
Various Ni-Pt(111) model surfaces were constructed in a well-defined way by using molecular beam epi...
Identification of the active sites in heterogeneous catalysis is important for a mechanistic underst...
© The formation of metal-oxide interfaces in catalytic systems exhibits a synergistic phenomenon bet...
In Situ Oxidation Study of Pt(110) and Its Interaction with COMany interesting structures have been ...
Bimetallic catalysts are widely used in many heterogeneous catalytic processes. With rational design...
Utilizing ambient pressure X-ray photoelectron spectroscopy (AP-XPS), the surface segregation and ox...
We present here a first principles density functional theory investigation of the reactivity of Pt(1...
Active oxide nanolayers can be stabilized on noble metal surfaces through interface confinement effe...
Segregation induced formation of oxide/metal interfaces can significantly influence the catalytic ac...
To determine the optimal structure and size of a cluster suitable for modeling chemical processes on...
Identification of structures of active sites of catalysts under realistic conditions is key for unde...
Supported Au-Ni nanocatalysts consisting of Au nanoparticies decorated with Ni/NiO nanostructures we...
© 2019 Elsevier B.V.The formation of interfacial metal–oxide structures on the Pt3Ni(111)bimetallic ...
Synergetic effect of surface and subsurface Ni species at Pt-Ni bimetallic catalysts for CO oxidatio...
Bimetallic catalysts are widely used in many heterogeneous catalytic processes. With rational design...
Various Ni-Pt(111) model surfaces were constructed in a well-defined way by using molecular beam epi...
Identification of the active sites in heterogeneous catalysis is important for a mechanistic underst...
© The formation of metal-oxide interfaces in catalytic systems exhibits a synergistic phenomenon bet...
In Situ Oxidation Study of Pt(110) and Its Interaction with COMany interesting structures have been ...
Bimetallic catalysts are widely used in many heterogeneous catalytic processes. With rational design...
Utilizing ambient pressure X-ray photoelectron spectroscopy (AP-XPS), the surface segregation and ox...
We present here a first principles density functional theory investigation of the reactivity of Pt(1...
Active oxide nanolayers can be stabilized on noble metal surfaces through interface confinement effe...
Segregation induced formation of oxide/metal interfaces can significantly influence the catalytic ac...
To determine the optimal structure and size of a cluster suitable for modeling chemical processes on...
Identification of structures of active sites of catalysts under realistic conditions is key for unde...
Supported Au-Ni nanocatalysts consisting of Au nanoparticies decorated with Ni/NiO nanostructures we...