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1. Crotonaldehyde Adsorption on Cu-Pt Surface Alloys: A Quantum Mechanics Study

   https://doi.org/10.3390/chemistry5010034  

   Ruvalcaba, Ricardo; Guerrero-Sanchez, Jonathan; Takeuchi, Noboru; Zaera, Francisco (March 2023, Chemistry)

   The adsorption of crotonaldehyde on Cu-Pt alloy surfaces was characterized by density functional theory (DFT). Two surfaces were considered: Cu2Pt/Cu(111) and Cu3Pt/Cu(111). It was determined that the presence of Pt on the surface, even when isolated as single atoms fully surrounded by Cu, provides additional stability for the adsorbates, increasing the magnitude of the adsorption energy by as much as 40 kJ/mol. The preferred bonding on both surfaces is via multiple coordination, with the most stable configuration being a cis arrangement with di-σ bonding of the C=O bond across a Cu–Cu bridge and an additional π bonding to a Pt atom. The fact that Pt significantly affects the adsorption of unsaturated aldehydes such as crotonaldehyde explains why the kinetics of their hydrogenation using single-atom alloy (SAA) catalysts vary with alloy composition, as we previously reported, and brings into question the simple model in which the role of Pt is only to promote the dissociation of H2. 

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2. Structural anisotropy in Sb thin films

   https://doi.org/10.1063/5.0159670  

   Adhikari, Pradip; Wijesinghe, Anuradha; Rathore, Anjali; Yoo, Timothy Jinsoo; Kim, Gyehyeon; Yeom, Sinchul; Lee, Hyoung-Taek; Mazza, Alessandro R; Sohn, Changhee; Park, Hyeong-Ryeol; et al (January 2024, APL Materials)

   Sb thin films have attracted wide interest due to their tunable band structure, topological phases, high electron mobility, and thermoelectric properties. We successfully grow epitaxial Sb thin films on a closely lattice-matched GaSb(001) surface by molecular beam epitaxy. We find a novel anisotropic directional dependence on their structural, morphological, and electronic properties. The origin of the anisotropic features is elucidated using first-principles density functional theory (DFT) calculations. The growth regime of crystalline and amorphous Sb thin films was determined by mapping the surface reconstruction phase diagram of the GaSb(001) surface under Sb2 flux, with confirmation of structural characterizations. Crystalline Sb thin films show a rhombohedral crystal structure along the rhombohedral (211) surface orientation parallel to the cubic (001) surface orientation of the GaSb substrate. At this coherent interface, Sb atoms are aligned with the GaSb lattice along the [1̄10] crystallographic direction but are not aligned well along the [110] crystallographic direction, which results in anisotropic features in reflection of high-energy electron diffraction patterns, misfit dislocation formation, surface morphology, and transport properties. Our DFT calculations show that the preferential orientation of the rhombohedral Sb (211) plane may originate from the GaSb surface, where Sb atoms align with the Ga and Sb atoms on the reconstructed surface. The formation energy calculations confirm the stability of the experimentally observed structures. Our results provide optimal film growth conditions for further studies of novel properties of Bi1−xSbx thin films with similar lattice parameters and an identical crystal structure, as well as functional heterostructures of them with III–V semiconductor layers along the (001) surface orientation, supported by a theoretical understanding of the anisotropic film orientation. 

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3. Surface dependence of electronic growth of Cu(111) on MoS2

   https://doi.org/10.1063/5.0215887  

   Harms, Haley A; Cunningham, Connor J; Kidd, Timothy E; Stollenwerk, Andrew J (August 2024, Applied Physics Letters)

   Scanning tunneling microscopy shows that copper deposited at room temperature onto a freshly exfoliated MoS2 surface forms Cu(111) clusters with periodic preferred heights of 5, 8, and 11 atomic layers. These height intervals correlate with Fermi nesting regions along the necks of the bulk Cu Fermi surface, indicating a connection between physical and electronic structures. Density functional theory calculations of freestanding Cu(111) films support this as well, predicting a lower density of states at the Fermi level for these preferred heights. This is consistent with other noble metals deposited on MoS2 that exhibit electronic growth, in which the metal films self-assemble as nanostructures minimizing quantum electronic energies. Here, we have discovered that it is critical for the metal deposition to begin on a clean MoS2 surface. If copper is deposited onto an already Cu coated surface, even if the original film displays electronic growth, the resulting Cu film lacks quantization. Instead, the preferred heights of the Cu clusters simply increase linearly with the amount of Cu deposited upon the surface. We believe this is due to different bonding conditions during the initial stages of growth. Newly deposited copper would bond strongly to the already present copper clusters, rather than the weak bonding, which exists to the van der Waals terminated surface of MoS2. The stronger bonding with previously deposited clusters hinders additional Cu atoms from reaching their lowest quantum energy state. The interface characteristics of the van der Waals surface enable surface engineering of self-assembled structures to achieve different applications. 

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4. Preadsorbed SO3 Inhibits Oxygen Atom Activity for Mercury Adsorption on Cu/Mn Doped CeO2(110) Surface

   https://doi.org/10.1021/acs.energyfuels.9b04508  

   Wang, Tao; Yang, Yihuan; Wang, Jiawei; Sajjadi, Baharak; Chen, Wei-Yin; Zhang, Yongsheng; Pan, Wei-Ping (March 2020, Energy & Fuels)

   The coadsorption of Hg0 and SO3 on pure and Cu/Mn doped CeO2(110) surfaces were investigated using the Density Functional Theory (DFT) method. A p (2 × 2) supercell periodic slab model with seven atomic layers was constructed to represent the CeO2(110) surface. The results indicated that Hg0 physically adsorbed on the CeO2(110) surface, while Hg0 chemically adsorbed on the Cu/Mn doped CeO2(110) surface, which agree well with the experimental results that Cu and Mn doped CeO2 greatly improved the Hg0 adsorption capacity of the adsorbent. The calculated results suggested that SO3 more easily adsorbs on the above three surfaces than Hg0 due to the higher adsorption energy. The adsorption configurations and electronic structures indicated SO3 reacted with O atoms of the surface to form SO42− species. Hence, SO3 inhibits Hg0 adsorption on the CeO2(110) surface by competing with Hg0 for surface lattice oxygen. In addition, SO3 decreased the activity of the surface O atoms, which directly caused the negative effect on Hg0 adsorption. 

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5. The dehydrogenative oxidation of aryl methanols using an oxygen bridged [Cu–O–Se] bimetallic catalyst

   https://doi.org/10.1039/d1nj00712b  

   Choudhury, Prabhupada; Behera, Pradyota Kumar; Bisoyi, Tanmayee; Sahu, Santosh Kumar; Sahu, Rashmi Ranjan; Prusty, Smruti Ranjita; Stitgen, Abigail; Scanlon, Joseph; Kar, Manoranjan; Rout, Laxmidhar (April 2021, New Journal of Chemistry)

   null (Ed.)

   Herein, we report a new protocol for the dehydrogenative oxidation of aryl methanols using the cheap and commercially available catalyst CuSeO 3 ·2H 2 O. Oxygen-bridged [Cu–O–Se] bimetallic catalysts are not only less expensive than other catalysts used for the dehydrogenative oxidation of aryl alcohols, but they are also effective under mild conditions and at low concentrations. The title reaction proceeds with a variety of aromatic and heteroaromatic methanol examples, obtaining the corresponding carbonyls in high yields. This is the first example using an oxygen-bridged copper-based bimetallic catalyst [Cu–O–Se] for dehydrogenative benzylic oxidation. Computational DFT studies reveal simultaneous H-transfer and Cu–O bond breaking, with a transition-state barrier height of 29.3 kcal mol −1 . 

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