Anneli Önsten scite author profile

High-resolution photoemission spectroscopy and scanning tunneling microscopy (STM) have been used to investigate defects on Cu 2 O(111) and their interaction with water and sulfur dioxide (SO 2 ). Two types of point defects, i.e., oxygen and copper vacancies, are identified. Copper vacancies are believed to be the most important defects in both water and SO 2 surface chemistry. Multiply coordinatively unsaturated oxygen anions (O MCUS ) such as oxygen anions adjacent to copper vacancies are believed to be adsorption sites for both water and SO 2 reaction products. Water adsorption at 150 K results in both molecular and dissociated water. Molecular water leaves the surface at 180 K. At 300 K and even more at 150 K, SO 2 interacts with oxygen sites at the surface forming SO 3 species. However, thermal treatment up to 280 K of Cu 2 O(111)/SO 2 prepared at 150 K renders only SO 4 on the surface.

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Water Adsorption on ZnO(0001): Transition from Triangular Surface Structures to a Disordered Hydroxyl Terminated phase

Önsten

Stoltz

Palmgren

et al. 2010

J. Phys. Chem. C

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We present room temperature scanning tunneling microscopy and photoemission spectroscopy studies of water adsorption on the Zn-terminated ZnO(0001) surface. Data indicates that the initial adsorption is dissociative leaving hydroxyl groups on the surface. At low water coverage, the adsorption occurs next to the oxygen-terminated step edges, where water is believed to bind to zinc cations leaving off hydrogen atoms to under-coordinated oxygen anions. When increasing the water dose, triangular terraces grow in size and pits diminish until the surface is covered with wide irregular terraces and a large number of small pits. Higher water exposure (20 Langmuir) results in a much more irregular surface. Hydrogen, which is produced in the dissociation reaction is believed to have an important role in the changed surface structure at high exposures. The fact that adsorbed water completely changes the structure of ZnO (0001) is an important finding toward the understanding of this surface at atmospheric conditions.

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The Surface Structure of Cu₂O(100)

Soldemo

Stenlid²,

Besharat

et al. 2016

J. Phys. Chem. C

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Despite the industrial importance of copper oxides, the nature of the (100) surface of Cu 2 O has remained poorly understood. The surface has previously been subject to several theoretical and experimental studies, but has until now not been investigated by atomically resolved microscopy or high-resolution photoelectron spectroscopy. Here we determine the atomic structure and electronic properties of Cu 2 O(100) by a combination of multiple experimental techniques and simulations within the framework of density functional theory (DFT). Low-energy electron diffraction (LEED) and scanning tunneling microscopy (STM) characterized the three ordered surface structures found. From DFT calculations, the structures are found to be energetically ordered as (3,0;1,1), c(2 × 2), and (1 × 1) under ultrahigh vacuum conditions. Increased oxygen pressures induce the formation of an oxygen terminated (1 × 1) surface structure. The most common termination of Cu 2 O(100) has previously been described by a (3√2 × √2)R45°unit cell exhibiting a LEED pattern with several missing spots. Through atomically resolved STM, we show that this structure instead is described by the matrix (3,0;1,1). Both simulated STM images and calculated photoemission core level shifts compare favorably with the experimental results.

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Dehydrogenation of methanol on Cu2O(100) and (111)

Besharat

Stenlid

Soldemo

et al. 2017

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Adsorption and desorption of methanol on the (111) and (100) surfaces of CuO have been studied using high-resolution photoelectron spectroscopy in the temperature range 120-620 K, in combination with density functional theory calculations and sum frequency generation spectroscopy. The bare (100) surface exhibits a (3,0; 1,1) reconstruction but restructures during the adsorption process into a Cu-dimer geometry stabilized by methoxy and hydrogen binding in Cu-bridge sites. During the restructuring process, oxygen atoms from the bulk that can host hydrogen appear on the surface. Heating transforms methoxy to formaldehyde, but further dehydrogenation is limited by the stability of the surface and the limited access to surface oxygen. The (√3 × √3)R30°-reconstructed (111) surface is based on ordered surface oxygen and copper ions and vacancies, which offers a palette of adsorption and reaction sites. Already at 140 K, a mixed layer of methoxy, formaldehyde, and CHO is formed. Heating to room temperature leaves OCH and CH. Thus both CH-bond breaking and CO-scission are active on this surface at low temperature. The higher ability to dehydrogenate methanol on (111) compared to (100) is explained by the multitude of adsorption sites and, in particular, the availability of surface oxygen.

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Anneli Önsten

Atomic structure of Cu2O(111)

Role of Defects in Surface Chemistry on Cu₂O(111)

Water Adsorption on ZnO(0001): Transition from Triangular Surface Structures to a Disordered Hydroxyl Terminated phase

The Surface Structure of Cu₂O(100)

Dehydrogenation of methanol on Cu2O(100) and (111)

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Resources

About

Anneli Önsten

Atomic structure of Cu2O(111)

Role of Defects in Surface Chemistry on Cu2O(111)

Water Adsorption on ZnO(0001): Transition from Triangular Surface Structures to a Disordered Hydroxyl Terminated phase

The Surface Structure of Cu2O(100)

Dehydrogenation of methanol on Cu2O(100) and (111)

Contact Info

Product

Resources

About

Role of Defects in Surface Chemistry on Cu₂O(111)

The Surface Structure of Cu₂O(100)