Active Plasmonics: Principles, Structures, and Applications
2018-02-10
org.kosen.entty.User@25ba823d
육종설(jsyuk)
행사&학회소개
1. Introduction
2. Principles of Active Plasmon Control
2.1. Control of Incident Light
2.2. Variation of the Dielectric Function of the Surrounding Medium
2.3. Change of the Charge Density and Dielectric Function of Plasmonic Materials
2.4. Control of the Interparticle Gap Distance
2.5. Control of the Symmetry of Plasmonic Nanostructures
2.6. Evaluation of the Performance of Active Plasmon Control
2.6.1. Spectral Response
2.6.2. Switching Time
2.6.3. Cycling Ability and Long-Term Stability
3. Active Plasmonic Structures
3.1. Plasmonic Structures in Tunable Dielectric Surroundings
3.1.1. Optically Active Materials
3.1.2. Thermocontrolled Materials
3.1.3. Electrically Controlled Materials
3.1.4. Electrochemically Controlled Materials
3.1.5. Magnetically Controlled Materials
3.1.6. Chemically Controlled Materials
3.2. Plasmonic Structures with Tunable Gap Distances
3.2.1. Dispersion in Solutions
3.2.2. Dispersion in or on Solid Matrices
3.3. Self-Tunable Plasmonic Structures
3.3.1. Metals
3.3.2. Inorganic Semiconductors
3.3.3. Graphene
3.3.4. Polycyclic Aromatic Hydrocarbons
3.4. Comparison
4. Applications of Active Plasmonic Structures
4.1. Plasmonic Sensing
4.2. Tunable Surface-Enhanced Raman Scattering
4.3. Active Plasmonic Components
4.4. Electrochromic Smart Windows
5. Summary and Perspectives
2. Principles of Active Plasmon Control
2.1. Control of Incident Light
2.2. Variation of the Dielectric Function of the Surrounding Medium
2.3. Change of the Charge Density and Dielectric Function of Plasmonic Materials
2.4. Control of the Interparticle Gap Distance
2.5. Control of the Symmetry of Plasmonic Nanostructures
2.6. Evaluation of the Performance of Active Plasmon Control
2.6.1. Spectral Response
2.6.2. Switching Time
2.6.3. Cycling Ability and Long-Term Stability
3. Active Plasmonic Structures
3.1. Plasmonic Structures in Tunable Dielectric Surroundings
3.1.1. Optically Active Materials
3.1.2. Thermocontrolled Materials
3.1.3. Electrically Controlled Materials
3.1.4. Electrochemically Controlled Materials
3.1.5. Magnetically Controlled Materials
3.1.6. Chemically Controlled Materials
3.2. Plasmonic Structures with Tunable Gap Distances
3.2.1. Dispersion in Solutions
3.2.2. Dispersion in or on Solid Matrices
3.3. Self-Tunable Plasmonic Structures
3.3.1. Metals
3.3.2. Inorganic Semiconductors
3.3.3. Graphene
3.3.4. Polycyclic Aromatic Hydrocarbons
3.4. Comparison
4. Applications of Active Plasmonic Structures
4.1. Plasmonic Sensing
4.2. Tunable Surface-Enhanced Raman Scattering
4.3. Active Plasmonic Components
4.4. Electrochromic Smart Windows
5. Summary and Perspectives
보고서작성신청
활성 플라즈몬은 급격히 성장하는플라즈몬의 하위 연구분야이다. 표면 플라스몬 공명의 활성 제어를 이용하며, 이 리뷰에서는 표면 플라즈몬 공명과 활성 플라즈몬 제어의 기초를 형성하는 영향 인자 사이의 이론적 관계에 대한 심층적인 설명이 제시 되었다. 튜닝 가능한 유전체 주변의 플라즈몬 구조, 가변 간격 거리를 갖는 플라즈몬 구조, 자기 조정 가능한 플라즈몬 구조로 구성된 활성 플라즈몬 구조의 3 가지 범주가 변조 메커니즘의 관점에서 제안 되었다. 본 리뷰 논문은 활성 플라즈모닉스에 대한 미래의 도전과 전망에 대한 섹션으로 결론 지어져 관련 연구자들에게 유용한 정보를 제공하고 있다.