Electronic Structure of Unsaturated V2O5(001) and (100) Surfaces: Ab Initio Density Functional Theory Studies

Hejduk, Pawel; Witko, Małgorzata; Hermann, Klaus

doi:10.1007/s11244-009-9250-0

Cited by 19 publications

(15 citation statements)

References 58 publications

(49 reference statements)

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“…These surfaces have been studied with DFT before, and the surface energy, 23 the electronic structure, 24 oxygen-vacancy formation energy, 25 and the adsorption energy of hydrogen, 25 water, 26 and ammonia 27 have been calculated. Those calculations were based on a surface structure with bulk periodicity, and as a result the surface geometry was very similar to that of the bulk.…”

Section: Introductionmentioning

confidence: 99%

Reconstruction of Low-Index α-V₂O₅ Surfaces

Kristoffersen

Metiu

2015

J. Phys. Chem. C

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Section: Introductionmentioning

confidence: 99%

Reconstruction of Low-Index α-V₂O₅ Surfaces

Kristoffersen

Metiu

2015

J. Phys. Chem. C

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“…The α-phase of V 2 O 5 has a layered structure, illustrated in Figure 1. The bonds within the layers are strong while the interlayer binding is long-ranged and weaker and for this reason the material is easy to cleave in the plane perpendicular to c. O 5 has previously been studied with DFT by a number of groups using GGA [4,5,6,7,8,9] or by adding (semi-)empirical vdW-terms to GGA calculations [9]. Here our focus is on the vdW-DF method rather than on the material V 2 O 5 itself.…”

Section: Introductionmentioning

confidence: 99%

Vanadium pentoxide (V2O5): A van der Waals density functional study

Londero

Schröder

2011

Computer Physics Communications

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The past few years has brought renewed focus on the physics behind the class of materials characterized by long-range interactions and wide regions of low electron density, sparse matter. There is now much work on developing the appropriate algorithms and codes able to correctly describe this class of materials within a parameter-free quantum physical description. In particular, van der Waals (vdW) forces play a major role in building up material cohesion in sparse matter. This work presents an application to the vanadium pentoxide (V 2 O 5 ) bulk structure of two versions of the vdW-DF method, a first-principles procedure for the inclusion of vdW interactions in the context of density functional theory (DFT). In addition to showing improvement compared to traditional semilocal calculations of DFT, we discuss the choice of various exchange functionals and point out issues that may arise when treating systems with large amounts of vacuum.

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“…(It should be mentioned in passing that surface reduction can also occur at vanadium pentoxide surfaces which are terminated along directions other than (010) and result in electronically unsaturated local regions considered previously. 35,75 ) Overall, most of the reactants, hydrogen, nitrogen, NO, NH, and NH 2 , bind quite strongly near all surface oxygen vacancy sites of the V 2 O 5 (010) substrate where they stabilize in positions formerly occupied by the oxygen. This substitutional adsorption geometry results in local surface relaxation where, due to binding with the adsorbate, the vanadium and oxygen atoms near the oxygen vacancy move towards their initial positions at the surface before the vacancy was created.…”

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confidence: 99%

Elementary steps of the catalytic NOx reduction with NH3: Cluster studies on reactant adsorption at vanadium oxide substrate

Gruber

Hermann

2013

The Journal of Chemical Physics

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Extended cluster models together with density-functional theory are used to evaluate geometric, energetic, and electronic properties of different adsorbate species that can occur at a vanadium oxide surface where the selective catalytic reduction (SCR) of NO in the presence of ammonia proceeds. Here, we focus on atomic hydrogen, nitrogen, and oxygen, as well as molecular NO and NHx, x = 1, 4, adsorption at a model V2O5(010) surface. Binding sites, oxygen and vanadium, at both the perfect and reduced surface are considered where reduction is modeled by (sub-) surface oxygen vacancies. The reactants are found to bind overall more strongly at oxygen vacancy sites of the reduced surface where they stabilize in positions formerly occupied by the oxygen (substitutional adsorption) compared with weaker binding at the perfect surface. In particular, ammonia, which interacts only weakly with vanadium at the perfect surface, binds quite strongly near surface oxygen vacancies. In contrast, surface binding of the NH4 adsorbate species differs only little between the perfect and the reduced surface which is explained by the dominantly electrostatic nature of the adsorbate interaction. The theoretical results are consistent with experimental findings and confirm the importance of surface reduction for the reactant adsorption forming elementary steps of the SCR process.

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Electronic Structure of Unsaturated V2O5(001) and (100) Surfaces: Ab Initio Density Functional Theory Studies

Cited by 19 publications

References 58 publications

Reconstruction of Low-Index α-V₂O₅ Surfaces

Reconstruction of Low-Index α-V₂O₅ Surfaces

Vanadium pentoxide (V2O5): A van der Waals density functional study

Elementary steps of the catalytic NOx reduction with NH3: Cluster studies on reactant adsorption at vanadium oxide substrate

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Electronic Structure of Unsaturated V2O5(001) and (100) Surfaces: Ab Initio Density Functional Theory Studies

Cited by 19 publications

References 58 publications

Reconstruction of Low-Index α-V2O5 Surfaces

Reconstruction of Low-Index α-V2O5 Surfaces

Vanadium pentoxide (V2O5): A van der Waals density functional study

Elementary steps of the catalytic NOx reduction with NH3: Cluster studies on reactant adsorption at vanadium oxide substrate

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Product

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Reconstruction of Low-Index α-V₂O₅ Surfaces

Reconstruction of Low-Index α-V₂O₅ Surfaces