Chemical, Structural, and Electronic Characterization of the (010) Surface of Single Crystalline Bismuth Vanadate

Favaro, Marco; Uecker, R.; Nappini, Silvia; Píš, Igor; Magnano, Elena; Bluhm, Hendrik; Krol, Roel van de; Starr, David E.

doi:10.1021/acs.jpcc.8b09016

Cited by 30 publications

(87 citation statements)

References 78 publications

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“…To further conrm this explanation, we calculated the extent of band bending in our BiVO 4 lms, assuming the core level peak position values of the BiVO 4 single crystal as those of the bulk (159.3 eV for Bi 4f 7/2 and 516.9 eV for V 2p 3/2 ). 48 The values for BiVO 4 lms with various MnO x thicknesses are listed in Table S1; † the values calculated using the Bi 4f 7/2 peak position agree very well with those calculated using V 2p 3/2 . Indeed, the extent of band bending increases with the increasing lm thickness.…”

Section: Resultsmentioning

confidence: 52%

The role of ultra-thin MnO_x co-catalysts on the photoelectrochemical properties of BiVO₄ photoanodes

et al. 2020

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confidence: 52%

The role of ultra-thin MnO_x co-catalysts on the photoelectrochemical properties of BiVO₄ photoanodes

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“…We provide the analysis and comparison of these spectra with existing literature on un‐doped and doped Mo‐BiVO 4 , as well as V 2 O 5 . [ 2b,12 ] While in V 2 O 5 the coordination geometry of the oxygen ligands is octahedral, in Mo‐BiVO 4 is tetrahedral. In detail, the V spectrum comprises the L 3 ‐ (515–520 eV) and L 2 ‐edge (521–528 eV), which are separated by ≈6.8 eV due to the spin‐orbit coupling of the 2p core hole.…”

Section: Resultsmentioning

confidence: 99%

“…In detail, the V spectrum comprises the L 3 ‐ (515–520 eV) and L 2 ‐edge (521–528 eV), which are separated by ≈6.8 eV due to the spin‐orbit coupling of the 2p core hole. [ 2b,12 ] The L 3 ‐edge arises from dipole‐allowed transition from V 2p 3/2 core levels to the unoccupied V 3d states of the conduction band (CB). Within the V L 3 ‐region, three main peaks are discernable at 516.3 eV (t 2 , Peak 2), 517.3 eV (Peak 3), and 518.5 eV (e, Peak 4) originating from the ligand field splitting of V 3d states.…”

Section: Resultsmentioning

confidence: 99%

“…Within the V L 3 ‐region, three main peaks are discernable at 516.3 eV (t 2 , Peak 2), 517.3 eV (Peak 3), and 518.5 eV (e, Peak 4) originating from the ligand field splitting of V 3d states. [ 2b,12 ] Specifically, the peak at 516.3 eV (Peak 2) is composed of V 3

d_{z^{2}}

and 3

d_{x^{2} - y^{2}}

states, and the peak at 518.5 eV (Peak 4) of V 3d xy , 3d yz , and 3d zx states. [ 13 ] A small shoulder is observed at a photon energy of ≈515.3 eV (Peak 1), which can be attributed to core hole exciton or to excitation of an electron into a small polaronic state at V 4+ sites generated by Mo‐doping.…”

Section: Resultsmentioning

confidence: 99%

“…[ 13 ] A small shoulder is observed at a photon energy of ≈515.3 eV (Peak 1), which can be attributed to core hole exciton or to excitation of an electron into a small polaronic state at V 4+ sites generated by Mo‐doping. [ 12,14 ] An additional feature at 519.7 eV (Peak 5) is a consequence of mixing of anisotropic Bi 6p states with O 2p states. [ 12 ] The V L 2 ‐region corresponds to excitation from 2p 1/2 core levels to unoccupied CB V 3d states, which is further split into two peaks at 523.5 eV (Peak 6) and 525.3 eV (Peak 7) corresponding to t 2 and e states, respectively.…”

Section: Resultsmentioning

confidence: 99%

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Revealing Nanoscale Chemical Heterogeneities in Polycrystalline Mo‐BiVO₄ Thin Films

Eichhorn

Reyes‐Lillo

Roychoudhury

et al. 2020

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The activity of polycrystalline thin film photoelectrodes is impacted by local variations of the material properties due to the exposure of different crystal facets and the presence of grain/domain boundaries. Here a multi‐modal approach is applied to correlate nanoscale heterogeneities in chemical composition and electronic structure with nanoscale morphology in polycrystalline Mo‐BiVO4. By using scanning transmission X‐ray microscopy, the characteristic structure of polycrystalline film is used to disentangle the different X‐ray absorption spectra corresponding to grain centers and grain boundaries. Comparing both spectra reveals phase segregation of V2O5 at grain boundaries of Mo‐BiVO4 thin films, which is further supported by X‐ray photoelectron spectroscopy and many‐body density functional theory calculations. Theoretical calculations also enable to predict the X‐ray absorption spectral fingerprint of polarons in Mo‐BiVO4. After photo‐electrochemical operation, the degraded Mo‐BiVO4 films show similar grain center and grain boundary spectra indicating V2O5 dissolution in the course of the reaction. Overall, these findings provide valuable insights into the degradation mechanism and the impact of material heterogeneities on the material performance and stability of polycrystalline photoelectrodes.

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Electronic Properties of W’ Twin Walls in Ferroelastic BiVO₄

Xu,

Sharma,

Wen

et al. 2024

Adv Funct Materials

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Topological defects in ferroic materials can exhibit intrinsic properties that differ from the bulk. Here， structural and electronic variations of non‐prominent (W’) ferroelastic twin domain walls are investigated in BiVO4, a widely investigated photocatalytic material. Using aberration‐corrected scanning transmission electron microscopy (STEM), a kink configuration of the sharp ferroelastic twin wall with an altered electronic structure is revealed. Nanoscale conductivity measurements by conductive atomic force microscopy (c‐AFM) show higher conductivity at twin walls compared to non‐conductive bulk domains. Electronic structure investigation by electron energy loss spectroscopy (EELS) shows a higher density of oxygen vacancies and possible polaron accumulation at the wall. These findings reveal the electronic properties of BiVO4 domain walls, which are interesting for nanoscale‐engineered catalytic concepts of BiVO4 and materials design for photochemistry‐relevant applications.

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Chemical, Structural, and Electronic Characterization of the (010) Surface of Single Crystalline Bismuth Vanadate

Cited by 30 publications

References 78 publications

The role of ultra-thin MnO_x co-catalysts on the photoelectrochemical properties of BiVO₄ photoanodes

The role of ultra-thin MnO_x co-catalysts on the photoelectrochemical properties of BiVO₄ photoanodes

Revealing Nanoscale Chemical Heterogeneities in Polycrystalline Mo‐BiVO₄ Thin Films

Electronic Properties of W’ Twin Walls in Ferroelastic BiVO₄

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Chemical, Structural, and Electronic Characterization of the (010) Surface of Single Crystalline Bismuth Vanadate

Cited by 30 publications

References 78 publications

The role of ultra-thin MnOx co-catalysts on the photoelectrochemical properties of BiVO4 photoanodes

The role of ultra-thin MnOx co-catalysts on the photoelectrochemical properties of BiVO4 photoanodes

Revealing Nanoscale Chemical Heterogeneities in Polycrystalline Mo‐BiVO4 Thin Films

Electronic Properties of W’ Twin Walls in Ferroelastic BiVO4

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Product

Resources

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The role of ultra-thin MnO_x co-catalysts on the photoelectrochemical properties of BiVO₄ photoanodes

The role of ultra-thin MnO_x co-catalysts on the photoelectrochemical properties of BiVO₄ photoanodes

Revealing Nanoscale Chemical Heterogeneities in Polycrystalline Mo‐BiVO₄ Thin Films

Electronic Properties of W’ Twin Walls in Ferroelastic BiVO₄