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Horizons in world physics. Volume 291 / Albert Reimer, editor.

Contributor(s): Material type: TextTextPublisher: New York : Nova Science Publishers, Inc., [2017]Copyright date: ©2017Description: 1 online resourceContent type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9781536110203
  • 1536110205
Subject(s): Genre/Form: DDC classification:
  • 530 23
LOC classification:
  • QC21.3
Online resources:
Contents:
Preface; Chapter 1; Progress in Quantum Spectral Imaging Research; Abstract; 1. Research Status of Spectral Imaging; 1.1. Spectral Imaging Instrument Analysis; 1.2. The Historical Development of Spectral Imaging Analysis; 1.3. Spectral Imaging Technology; 1.4. Quantum Spectroscopy Study; 2. The Background of Quantum Spectral Imaging; 3. Concepts and Methods of Quantum Spectral Imaging; 3.1. Basic Concepts; 3.2. Research Objectives; 3.3. Research Connotations; 4. Comparison of Quantum Spectral Imaging with Traditional Spectral Imaging; 4.1. Differences in Basic Theory
4.2. Different Research Scales4.3. Characteristics of Quantum Spectral Imaging; 5. Research on the Fundamental Theory of Quantum Spectra; 5.1. Energy Distribution Representation in the Quantum Spectrum; 5.2. Energy Distribution Features in the Quantum Spectrum; 5.3. Energy Distribution Mechanism in the Quantum Spectrum; 6. Experimental Study of Quantum Spectral Imaging; 7. Quantum Spectral Imaging Technology Research; 8. Quantum Spectral Imaging Study of Application Prospects; 8.1. Significance; 8.2. Application Prospects; (1) National Defense Security; (2) Lunar Exploration
(3) Remote Sensing ApplicationsReferences; Chapter 2; Resonant Interaction of Acoustic Phonons with Localized Vibrational Modes in Superlattices; Abstract; 1. Introduction; 2. Transfer Matrix Method; 2.1. Transfer Matrix; 2.2. Frequency Band and Bandgap; 2.3. Transmission and Reflection; 3. Phonons Localized at a Defect Layer; 3.1. Resonant Transmission of Phonons through a Double Barrier Structure for Phonons; 3.2. Phonons Localized at a Defect-Layer Embedded in an Infinite SL; 3.3. Equivalent Tight-Binding Chain; 4. Phonons Localized at a Surface
5. Phonons Localized at a SL-Liquid Interface5.1. Resonant Transmission through a SL-Liquid Interface; 5.2. Mathematical Analysis of the Resonant Transmission; 6. Phase Time and Phonon Propagation; 6.1. Surface Localized Mode and Phase Time; 6.2. Tunneling Time; 7. Mode Conversion and Resonance; 7.1. Intramode and Intermode Bragg Reflections; 7.2. Phonons Localized at a Defect Layer; 7.3. Phonons Localized at a Surface; 8. Solid-Fluid Superlattices; Conclusion; Acknowledgment; References; Chapter 3; Amorphous Organic Superlattices; Abstract; 1. Introduction
1.1. Amorphous and Polycrystalline Superlattices1.2. Tricolor Superlattices; 2. Fabrication and Functions of Organic Tricolor Superlattices; 2.1. Amorphous Organic Tricolor Superlattices with Photoresponsive Mechanical Functions; 2.2. Apparatus to Fabricate Organic Tri-Color Superlattice; 2.3. Synthesis of PU Film by Alternating Deposition; 2.4. Characterization of the PU Thin Film; 3. Photoresponsive Piezoelectric Effect Using Tri-Color Superlattice; 3.1. Fabrication of Tri-Color Superlattice Composed of NPB, Alq3, and PU; 3.2. Characterization of NPB/Alq3/PU Superlattice; Conclusion
Holdings
Item type Current library Collection Call number Status Date due Barcode Item holds
eBook eBook e-Library EBSCO Science Available
Total holds: 0

Includes bibliographical references and index.

Online resource; title from PDF title page (EBSCO, viewed June 9, 2017).

Preface; Chapter 1; Progress in Quantum Spectral Imaging Research; Abstract; 1. Research Status of Spectral Imaging; 1.1. Spectral Imaging Instrument Analysis; 1.2. The Historical Development of Spectral Imaging Analysis; 1.3. Spectral Imaging Technology; 1.4. Quantum Spectroscopy Study; 2. The Background of Quantum Spectral Imaging; 3. Concepts and Methods of Quantum Spectral Imaging; 3.1. Basic Concepts; 3.2. Research Objectives; 3.3. Research Connotations; 4. Comparison of Quantum Spectral Imaging with Traditional Spectral Imaging; 4.1. Differences in Basic Theory

4.2. Different Research Scales4.3. Characteristics of Quantum Spectral Imaging; 5. Research on the Fundamental Theory of Quantum Spectra; 5.1. Energy Distribution Representation in the Quantum Spectrum; 5.2. Energy Distribution Features in the Quantum Spectrum; 5.3. Energy Distribution Mechanism in the Quantum Spectrum; 6. Experimental Study of Quantum Spectral Imaging; 7. Quantum Spectral Imaging Technology Research; 8. Quantum Spectral Imaging Study of Application Prospects; 8.1. Significance; 8.2. Application Prospects; (1) National Defense Security; (2) Lunar Exploration

(3) Remote Sensing ApplicationsReferences; Chapter 2; Resonant Interaction of Acoustic Phonons with Localized Vibrational Modes in Superlattices; Abstract; 1. Introduction; 2. Transfer Matrix Method; 2.1. Transfer Matrix; 2.2. Frequency Band and Bandgap; 2.3. Transmission and Reflection; 3. Phonons Localized at a Defect Layer; 3.1. Resonant Transmission of Phonons through a Double Barrier Structure for Phonons; 3.2. Phonons Localized at a Defect-Layer Embedded in an Infinite SL; 3.3. Equivalent Tight-Binding Chain; 4. Phonons Localized at a Surface

5. Phonons Localized at a SL-Liquid Interface5.1. Resonant Transmission through a SL-Liquid Interface; 5.2. Mathematical Analysis of the Resonant Transmission; 6. Phase Time and Phonon Propagation; 6.1. Surface Localized Mode and Phase Time; 6.2. Tunneling Time; 7. Mode Conversion and Resonance; 7.1. Intramode and Intermode Bragg Reflections; 7.2. Phonons Localized at a Defect Layer; 7.3. Phonons Localized at a Surface; 8. Solid-Fluid Superlattices; Conclusion; Acknowledgment; References; Chapter 3; Amorphous Organic Superlattices; Abstract; 1. Introduction

1.1. Amorphous and Polycrystalline Superlattices1.2. Tricolor Superlattices; 2. Fabrication and Functions of Organic Tricolor Superlattices; 2.1. Amorphous Organic Tricolor Superlattices with Photoresponsive Mechanical Functions; 2.2. Apparatus to Fabricate Organic Tri-Color Superlattice; 2.3. Synthesis of PU Film by Alternating Deposition; 2.4. Characterization of the PU Thin Film; 3. Photoresponsive Piezoelectric Effect Using Tri-Color Superlattice; 3.1. Fabrication of Tri-Color Superlattice Composed of NPB, Alq3, and PU; 3.2. Characterization of NPB/Alq3/PU Superlattice; Conclusion

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