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Semiconductor Metasurfaces, Part 1

Innbundet / 2024 / Engelsk

Produktdetaljer

ISBN
9780443296864
Publisert
2024-10-30
Utgiver
Vendor
Academic Press Inc
Vekt
450 gr
Høyde
229 mm
Bredde
152 mm
Aldersnivå
P, 06
Språk
Product language
Engelsk
Format
Product format
Innbundet
Antall sider
196

Om bidragsyterne

Dr. Martin Hafermann is a research associate at Friedrich Schiller University Jena where he explores the use of ion beams to modify various material platforms for enhanced optical applications. He earned his PhD in 2021 at FSU Jena investigating ion-beam modified phase-change materials for metasurfaces. Dr. Sarah Walden is a lecturer at Griffith University investigating tuneable nanophotonic devices using stimuli-responsive materials. In 2017 Sarah completed a PhD at the Queensland University of Technology (QUT), investigating the nonlinear optical properties of semiconductor nanoparticles. After her PhD, she became a Postdoctoral Fellow jointly between the Soft Matter Materials Laboratory at QUT and the Karlsruhe Institute of Technology (KIT), investigating new materials for photolithography. In 2022, Sarah commenced a Zukunfts Fellowship at the Friedrich Schiller University Jena, where she applied stimuli-responsive polymers for tuneable metasurface devices.

Semiconductor Metasurfaces, Part 1

Innbundet / 2024 / Engelsk
Innbundet / 2024 / Engelsk
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Semiconductor Metamaterials: Part One, Volume 116 in a two-part series surveys the state-of-the-art in material platforms for optical metasurfaces. Chapters cover Metasurfaces from materials with 2nd-order nonlinearity, Light Emitting Metasurfaces based on Direct Bandgap Semiconductors, Tunable Metasurfaces enabled by Phase-Change Materials, Phase-Transition Materials for Thermal Tuning of Metasurfaces, Tunable Metasurface Devices based on Soft Matter, Infrared Metasurfaces, Polarization Sensing Platforms, UV/ Visible Metasurfaces, and Metasurfaces for Catalysis & Chemistry.
Les mer
Generate 1. Metasurfaces from materials with 2nd-order nonlinearity Frank Setzpfandt, Anna Fedotova Fedotova, Maximilian Weißflog and Sina Saravi 2. Light Emitting Metasurfaces based on Direct Bandgap Semiconductors Tuomas Haggren, Matthew Brian Parry and Wei Wen Wong Tuning 3. Tunable Metasurfaces enabled by Phase-Change Materials Martin Hafermann 4. Phase-Transition Materials for Thermal Tuning of Metasurfaces Carsten Ronning 5. Tunable Metasurface Devices based on Soft Matter Sarah Walden, Yana Izdebskaya and Ilya Shadrivov Detect 6. Infrared Metasurfaces Joseph Talghader, Avijit Das, Merlin Mah and John Hunt 7. Polarization Sensing Platforms Jer-Shing Huang and Lin Zhan-Hong 8. UV/ Visible Metasurfaces Kun Huang 9. Metasurfaces for Catalysis & Chemistry Fiona J. Beck, Christin David, Zelio Fusco, Ning Lyu and Anjalie Edirisooriya
Les mer
Helps readers understand how to design a metasurface, including everything a readers needs to know about semiconductor metasurfaces
Provides the most important aspects of the semiconductor materials platforms that are used for optical metasurfaces Considers both static and dynamic metasurfaces Covers the entire EM spectrum, from UV to visible and IR light
Les mer

Relaterte produkter

Semiconductor Metamaterials: Part One, Volume 116 in a two-part series surveys the state-of-the-art in material platforms for optical metasurfaces. Chapters cover Metasurfaces from materials with 2nd-order nonlinearity, Light Emitting Metasurfaces based on Direct Bandgap Semiconductors, Tunable Metasurfaces enabled by Phase-Change Materials, Phase-Transition Materials for Thermal Tuning of Metasurfaces, Tunable Metasurface Devices based on Soft Matter, Infrared Metasurfaces, Polarization Sensing Platforms, UV/ Visible Metasurfaces, and Metasurfaces for Catalysis & Chemistry.
Les mer
Generate 1. Metasurfaces from materials with 2nd-order nonlinearity Frank Setzpfandt, Anna Fedotova Fedotova, Maximilian Weißflog and Sina Saravi 2. Light Emitting Metasurfaces based on Direct Bandgap Semiconductors Tuomas Haggren, Matthew Brian Parry and Wei Wen Wong Tuning 3. Tunable Metasurfaces enabled by Phase-Change Materials Martin Hafermann 4. Phase-Transition Materials for Thermal Tuning of Metasurfaces Carsten Ronning 5. Tunable Metasurface Devices based on Soft Matter Sarah Walden, Yana Izdebskaya and Ilya Shadrivov Detect 6. Infrared Metasurfaces Joseph Talghader, Avijit Das, Merlin Mah and John Hunt 7. Polarization Sensing Platforms Jer-Shing Huang and Lin Zhan-Hong 8. UV/ Visible Metasurfaces Kun Huang 9. Metasurfaces for Catalysis & Chemistry Fiona J. Beck, Christin David, Zelio Fusco, Ning Lyu and Anjalie Edirisooriya
Les mer
Helps readers understand how to design a metasurface, including everything a readers needs to know about semiconductor metasurfaces
Provides the most important aspects of the semiconductor materials platforms that are used for optical metasurfaces Considers both static and dynamic metasurfaces Covers the entire EM spectrum, from UV to visible and IR light
Les mer

Produktdetaljer

ISBN
9780443296864
Publisert
2024-10-30
Utgiver
Vendor
Academic Press Inc
Vekt
450 gr
Høyde
229 mm
Bredde
152 mm
Aldersnivå
P, 06
Språk
Product language
Engelsk
Format
Product format
Innbundet
Antall sider
196

Om bidragsyterne

Dr. Martin Hafermann is a research associate at Friedrich Schiller University Jena where he explores the use of ion beams to modify various material platforms for enhanced optical applications. He earned his PhD in 2021 at FSU Jena investigating ion-beam modified phase-change materials for metasurfaces. Dr. Sarah Walden is a lecturer at Griffith University investigating tuneable nanophotonic devices using stimuli-responsive materials. In 2017 Sarah completed a PhD at the Queensland University of Technology (QUT), investigating the nonlinear optical properties of semiconductor nanoparticles. After her PhD, she became a Postdoctoral Fellow jointly between the Soft Matter Materials Laboratory at QUT and the Karlsruhe Institute of Technology (KIT), investigating new materials for photolithography. In 2022, Sarah commenced a Zukunfts Fellowship at the Friedrich Schiller University Jena, where she applied stimuli-responsive polymers for tuneable metasurface devices.

Relaterte produkter