Your search keyword '"Kyunghwa Yoo"' showing total 2 results

1. Ferroelastic-Ferroelectric Multiferroicity in van der Waals Rhenium Dichalcogenides

Author

Jaehun Jeong, Hyeon‐Sik Kim, Gihyeon Kwon, Kwangsik Jeong, Hyangsook Lee, Ji Hye Lee, Myunguk Park, Changjun Lee, Sanghyuck Yu, Heegoo Kim, Seongil Im, Kyunghwa Yoo, Eunha Lee, and Mann‐Ho Cho

Subjects

Mechanics of Materials, Mechanical Engineering, General Materials Science

Abstract

2D multiferroics with combined ferroic orders have gained attention owing to their novel functionality and underlying science. Intrinsic ferroelastic-ferroelectric multiferroicity in single-crystalline van der Waals rhenium dichalcogenides, whose symmetries are broken by the Peierls distortion and layer-stacking order, is demonstrated. Ferroelastic switching of the domain orientation and accompanying anisotropic properties is achieved with 1% uniaxial strain using the polymer encapsulation method. Based on the electron localization function and bond dissociation energy of the Re-Re bonds, the change in bond configuration during the evolution of the domain wall and the preferred switching between the two specific orientation states are explained. Furthermore, the ferroelastic switching of ferroelectric polarization is confirmed using the photovoltaic effect. The study provides insights into the reversible bond-switching process and potential applications based on 2D multiferroicity.

Published

2022

2. Density Functional Study on the C-H Bond Cleavage of Aldimine by a Rhodium(I) Catalyst

Author

Kyunghwa Yoo, Eunji Sim, Cheol Ho Choi, and Chul Ho Jun

Subjects

chemistry.chemical_classification, Aldimine, Reaction mechanism, Chemistry, chemistry.chemical_element, General Chemistry, Photochemistry, Catalysis, Rhodium, chemistry.chemical_compound, Crystallography, Transition metal, Organic synthesis, Bond cleavage, Organometallic chemistry

Abstract

We investigated the C-H bond activation mechanism of aldimine by the [RhCl] model catalyst using DFT B3LYP//SBKJC/6-31G*/6-31G on GAMESS. Due to their potential utility in organic synthesis, C-H bond activation is one of the most active research fields in organic and organometallic chemistry. C-H bond activation by a transition metal catalyst can be classified into two types of mechanisms: direct C-H bond cleavage by the metal catalyst or a multi-step mechanism via a tetrahedral transition state. There are three structural isomers of [RhCl] coordinated aldimine that differ in the position of chloride with respect to the molecular plane. By comparing activation energies of the overall reaction pathways that the three isomeric structures follow in each mechanism, we found that the C-H bond activation of aldimine by the [RhCl] catalyst occurs through the tetrahedral intermediate.