Combined Experimental and Periodic DFT Study of the Size Dependence of Adsorption Properties of Oxide‐Supported Metal Nanoclusters: A Case of NO on Ni/Al<sub>2</sub>O<sub>3</sub>-Reference-Cited by-同舟云学术

Combined Experimental and Periodic DFT Study of the Size Dependence of Adsorption Properties of Oxide‐Supported Metal Nanoclusters: A Case of NO on Ni/Al₂O₃

Published:2024-08-21 Issue: Volume: Page:
ISSN:0142-2421
Container-title:Surface and Interface Analysis
language:en
Short-container-title:Surface & Interface Analysis

Author:

Magkoev Tamerlan T.¹^ORCID,Men Yong²,Behjatmanesh‐Ardakani Reza³,Elahifard Mohammadreza⁴,Abaev Vladimir T.¹⁵,Chalikidi Petrakis¹,Magkoev Taymuraz T.¹,Ashkhotov Oleg G.⁶

Affiliation:

1. Laboratory of Adsorption Phenomena, Department of Condensed Matter Physics North Ossetian State University Vladikavkaz Russian Federation

2. School of Chemistry and Chemical Engineering Shanghai University of Engineering Science Shanghai China

3. Department of Chemical Engineering, Faculty of Engineering Ardakan University Ardakan Iran

4. Division of Atmospheric Sciences Desert Research Institute Reno Nevada USA

5. Department of Chemistry North Caucasus Federal University Stavropol Russian Federation

6. Institute of Informatics, Electronics and Robotics Kabardino‐Balkarian State University Nal'chik Russian Federation

Abstract

ABSTRACTIt is demonstrated by means of ultra high vacuum (UHV) surface‐sensitive techniques and periodic density functional theory (DFT) calculations that the electronic and NO− adsorption properties of nanosized Ni clusters deposited onto the α‐Al2O3 (0001) surface significantly depend upon the size of the cluster. The properties of the Ni cluster of the size of 2 nm and lower are predominantly determined by the formation of the Ni/Al2O3 interface bond notably polarized towards the oxide. As a result, the metal cluster acquires a net positive charge manifested by the bond strengthening of adsorbed NO compared to the bulk Ni substrate. With the increasing size of the cluster, the Ni/Al2O3 interfacial bond depolarizes due to the growing of lateral Ni–Ni interaction. With a mean coverage of Ni on the alumina surface exceeding 0.25 equivalent monolayers, their properties in terms of adsorption behavior of NO resemble those that are characteristic for the bulk Ni substrate. Such a size dependence offers an opportunity to tune the properties of metal clusters and the metal/oxide system as a whole, for example, to achieve the required electronic and adsorption‐reaction properties.

Funder

Ministry of Science and Higher Education of the Russian Federation

Publisher

Wiley

Reference49 articles.

1. Surface chemistry of hot electron and metal-oxide interfaces

2. Modification of interfacial spin-orbit torque in Co/Pt/oxide hybrid structures

3. Precision defect engineering of metal/insulator/metal diodes using atomic layer deposition to localize Ni impurities in Al2O3 tunnel barriers

4. Reactive metal–oxide interfaces: A microscopic view