Advances in nanostructured materials and nanopatterning technologies

Advances in Nanostructured Materials and Nanopatterning Technologies: Applications for Healthcare, Environment and Energy demonstrates how to apply micro- and nanofabrication and bioextrusion based systems for cell printing, electrophoretic deposition, antimicrobial applications, and nanoparticles t...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Formato: Electrónico eBook
Idioma:Inglés
Publicado: [Place of publication not identified] ELSEVIER, 2020.
Colección:Advanced Nanomaterials Ser.
Temas:
Nanostructured materials > Technological innovations.
Nanolithography > Technological innovations.
Nanomat�eriaux > Innovations.
Nanolithographie > Innovations.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Front Cover
  • Advances in Nanostructured Materials and Nanopatterning Technologies
  • Advances in Nanostructured Materials and Nanopatterning Technologies: Applications for Healthcare, Environmental and Energy
  • Copyright
  • Contents
  • Contributors
  • 1
  • General topics
  • 1
  • From nanocomposites to nanostructured materials
  • 1. Introduction: why nano?
  • 2. Nanocomposites
  • 2.1 Classifications
  • 2.2 Structure and processing methodologies
  • 2.3 Applications
  • 2.3.1 Nanocomposites for energy applications
  • 2.3.2 Nanocomposites for environmental applications
  • 2.3.3 Biomedical applications
  • 3. Nanofabrication
  • 4. Nanoscale surface modification
  • 4.1 The importance of surface science and nanoscale surfaces
  • 4.2 Main techniques for nanoscale surface modification
  • 4.3 Examples of nanoscale surface modifications and applications
  • References
  • Further reading
  • 2
  • Manufacturing at nanoscale: from molecular machines to transducers
  • 1. Introduction
  • 2. Basic concepts
  • 2.1 The molecular bottom-up approach
  • 2.2 Terms and definitions
  • 2.3 Energy supply
  • 2.4 Mechanically interlocked molecules as nanoscale machines
  • 3. Prototypical examples
  • 3.1 Linear movements: molecular shuttles, muscles, and elevators
  • 3.2 Molecular rotary motors
  • 4. Towards applications
  • 4.1 Molecular factories
  • 4.2 Macroscopic actuation with artificial molecule-based muscles
  • 4.3 Nanovalves for molecular delivery
  • 5. Conclusion
  • References
  • 3
  • Subtracting technologies: Unconventional Nanolithography
  • 1. Introduction
  • 1.1 General aspects of the subtractive process
  • 2. Optical methods
  • 2.1 Direct fabrication of 2D/3D structures
  • 2.2 Refinement of prefabricated structures
  • 2.3 Mask fabrication
  • 3. Scanning probe methods
  • 3.1 Optical-based scanning probe lithography
  • 3.2 Mechanical-based scanning probe lithography
  • 4. Stamp-based methods
  • 4.1 Direct reverse stamping
  • 4.2 Reverse stamping by dewetting
  • 4.3 Spatially controlled chemical reaction
  • 5. Conclusions
  • References
  • 2
  • Healthcare
  • 4
  • Biomimetic routes to micro/nanofabrication: morphogenetically active high-energy inorganic polyphosphate nano/m ...
  • 1. Introduction
  • 2. Inorganic polyP: chemistry
  • 3. Inorganic polyP: biology
  • 4. The model in nature: physiologically occurring polyP nano/microparticles
  • 5. Biomimetic fabrication of amorphous polyP nano/microparticles
  • 6. Formation of coacervate complexes from polyP nano/microparticles
  • 7. Biological properties: high-energy storage and release
  • 8. Biological properties: morphogenetic activity
  • 9. Biohybrid formation with hydrogel forming polymers and additive manufacturing
  • 10. Biomedical applications
  • 11. Safety assessment
  • 12. Future strategies
  • References
  • 5
  • Nanostructured coatings for antimicrobial applications
  • 1. Arthroplasty
  • 1.1 Prosthesis fixation options

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