The physical properties of organic monolayers /

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This text provides a fundamental physical picture of various phenomena occurring in organic monolayers, dealing with dielectric, elastic and electronic properties. The dielectric properties are discussed in terms of orientational order parameters, which are used to interpret the dielectric spectrum...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Iwamoto, Mitsumasa
Otros Autores: Wu, Chen-Xu
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Singapore ; River Edge, NJ : World Scientific, 2001.
Temas:
Monomolecular films.
Organic compounds.
Thin films.
Surface chemistry.
Organic Chemicals
Couches monomoléculaires.
Chimie des surfaces.
Composés organiques.
Couches minces.
organic compounds.
SCIENCE > Physics > General.
SCIENCE > Mechanics > General.
SCIENCE > Energy.
Monomolecular films
Organic compounds
Surface chemistry
Thin films
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Ch. 1. Introduction. 1.1. Monolayer structure and monolayer properties. 1.2. Surface pressure/area isotherm. 1.3. Maxwell displacement current measurement technique 31.4. Molecular dynamics of monolayer films. References
  • ch. 2. Polarization and dielectric constant for 2D media. 2.1. Polarization. 2.2. Spontaneous polarization. 2.3. First order polarization and dielectric constant. 2.4. Nonlinear polarization. 2.5. Summary. References
  • ch. 3. Maxwell displacement current method. 3.1. Maxwell displacement current. 3.2. Maxwell displacement current by monolayer compression. 3.3. MDC generated across organic monolayers consisting of molecules with dielectric anisotropy. 3.4. Phase transition of chiral phospholipid monolayers by maxwell displacement current measurement. 3.5. Maxwell displacement current by photoirradiation. 3.6. Evaluation of liquid crystal alignment using MDC technique. 3.7. Summary. References
  • ch. 4. Monolayers viewed as polar liquid crystals. 4.1. Model and internal electric fields. 4.2. Polar orientational phase transition in smectic monolayers. 4.3. Change of orientational order parameter at the critical point. 4.4. Dielectric properties influenced by the orientational phase transition. 4.5. Summary. References.
  • Ch. 5. Dielectric relaxation phenomena. 5.1. Rotational Debye Brownian motion model. 5.2. Relaxation process at an air-water interface. 5.3. Determination of dielectric relaxation time. 5.4. Summary. References
  • ch. 6. Chiral phase separation. 6.1. Elastic energy and Bragg-Williams mixing energy. 6.2. Chiral phase separation. 6.3. Discrete one-dimensional CPS solution. 6.4. Summary. 6.5. Appendix. References
  • ch. 7. Nonlinear effects. 7.1. SOS in orientational order parameters for C[symbol] monolayers. 7.2. Chirality representation. 7.3. SHG-CD effect. 7.4. SHG-MDC measuring system. 7.5. Quantum mechanical analysis of photoisomerization. 7.6. Summary. References
  • ch. 8. Thermally-stimulated current. 8.1. Thermally-stimulated current. 8.2. Depolarization due to thermal stimulation. 8.3. TSC experiment. 8.4. Phase transition. 8.5. Thermodynamics approach to monolayers. 8.6. Summary. References
  • ch. 9. Electronic properties at MIM interfaces. 9.1. Tunneling current and electronic device applications. 9.2. Nanometric interfacial electrostatic phenomena in ultrathin films. 9.3. I-V characteristic. 9.4. Summary. References.

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