Your search keyword '"Bo-Xiang Liao"' showing total 4 results

1. Perpendicular magnetic anisotropy induced by 6p atomic layers: Crucial role of interface structural order

Author

Bo-Xiang Liao, Yen-Ling Hsu, Tzu-Hung Chuang, Ming-Shian Tsai, Der-Hsin Wei, Bo-Yao Wang, Yen-Ming Lai, and Chun-Yao Hsu

Subjects

Metal, Materials science, Valence (chemistry), Ferromagnetism, Atomic orbital, Condensed matter physics, Orbital hybridisation, visual_art, Principal quantum number, visual_art.visual_art_medium, Layer (electronics), Wetting layer

Abstract

Two-dimensional atomic layers composed of metallic atoms with a high principal quantum number in valence shells are promising materials for applications in state-of-the-art magnetic devices due to the presence of a strong spin-orbit coupling. In this work we experimentally explored the effects of triggering perpendicular magnetic anisotropy (PMA) of ferromagnetic (FM) films by applying a series of $6p$-Pb, Bi and $4d$-Pd (reference) atomic layers with high-level atomic orbital and low-level lattice strain. Our research indicates that, compared with Pd atoms, Pb and Bi atoms can produce higher-strength PMA on adjacent FM films through orbital hybridization at the interface. Moreover, we demonstrate that the PMA induced by Pb and Bi atoms is highly sensitive to the ordering degree of the wetting layer which is determined by the interplay of surface free, cohesive, and strain energies within the grown materials; the Pb(Bi) atoms added on the wetting layer can enhance the PMA of the adjacent FM film only when the wetting layer maintains an ordered structure. This work clarifies the critical interface effects of $6p$-HMs on the FM layer, thus providing important clues to increase control over the spin-orbit interaction engendered by HMs through the interface.

Published

2021

2. Perpendicular magnetic anisotropy induced by NiMn-based antiferromagnetic films with in-plane spin orientations: Roles of interfacial and volume antiferromagnetic moments

Author

Tzu-Hsin Li, Bo-Yao Wang, Yen-Ling Hsu, Bo-Xiang Liao, Chun-Yao Hsu, Chung-Hsuan Hsiao, Yen-Ming Lai, Der-Hsin Wei, Tzu-Hung Chuang, and Ming-Shian Tsai

Subjects

Condensed Matter::Materials Science, Magnetic anisotropy, Tetragonal crystal system, Materials science, Condensed matter physics, Ferromagnetism, Antiferromagnetism, Condensed Matter::Strongly Correlated Electrons, Heterojunction, Thin film, Anisotropy, Coupling (probability)

Abstract

Antiferromagnetic (AFM) thin films are promising materials for engineering the magnetic anisotropy of adjacent ferromagnetic (FM) films. In this work, we explored the effects of triggering perpendicular magnetic anisotropy (PMA) of FM films by applying a series of NiMn-based AFM films with in-plane-oriented spin structures. The vertically expanded face-centered tetragonal ${\mathrm{Ni}}_{50}{\mathrm{Mn}}_{50}$ films alone could not induce PMA in Co/Ni films. By contrast, PMA was triggered through the application of Mn-rich NiMn alloy films or ${\mathrm{Ni}}_{50}{\mathrm{Mn}}_{50}/1$-monolayer Mn $(\mathrm{Mn}/1\text{\ensuremath{-}}\mathrm{ML} {\mathrm{Ni}}_{50}{\mathrm{Mn}}_{50})$ heterostructures. Detailed analyses of a series of samples indicated that two criteria must be met for a NiMn-based AFM film to trigger PMA in a neighboring FM film: (1) perpendicular interface crystalline anisotropy of interfacial uncompensated Mn moments must be established, and (2) strengthened lateral exchange coupling to volume AFM moments must be made. This paper clarifies how NiMn-based AFM films with in-plane-oriented AFM spin structures trigger the PMA of FM films, thus identifying a pathway to increase control over antiferromagnet-induced PMA through the interface/volume magnetic engineering of AFM layers.

Published

2021

3. Optimal generation expansion planning strategy for the utility with IPPs participation and considering Green House gas mitigation

Author

Shi-Jaw Chen, Ming-Tong Tsay, Meei-Song Kang, Tung-Sheng Zhan, Bo-Xiang Liao, and Jong-Ian Tsai

Subjects

Competition (economics), Reduction (complexity), Engineering, Electricity generation, business.industry, Reliability (computer networking), Greenhouse gas, Crossover, Environmental engineering, Greenhouse, Thermal power station, Environmental economics, business

Abstract

Thermal power plants dominate electric power generation in Taiwan, which are also the major contributor to Green House gases (GHG). CO2 is the most important greenhouse gas that cause global warming and sea-level rising. This paper pierces the relationship between GHG reduction and power generation expansion planning (GEP) problem for the utility. Refined Immune Algorithm (RIA) is presented to determine the generation expansion planning strategy of the utility with independent power providers (IPPs). The utility has to take both the IPPs' participation and environment impact into account when a new generation unit is expanded. This problem also takes into account the GHG reduction and reliability issues, while satisfying all electrical constraints simultaneously from view of supply side. RIA was conducted by an improved crossover and mutation mechanism with a competition and auto-adjust scheme to avoid prematurity. Testing results shows that RIA can offer an efficient way in determining the generation expansion planning.

Published

2009

4. Optimal generation expansion planning strategy for the utility with IPPs participation and considering Green House gas mitigation.

Author

Tung-Sheng Zhan, Shi-Jaw Chen, Ming-Tong Tsay, Meei-Song Kang, Jong-Ian Tsai, and Bo-Xiang Liao

Published

2009