The book deals with physical properties at the nanoscale due to non-local effects introduced by extended irreversible thermodynamics (EIT). The book provides for a systematic approach to understand the behavior of thermal, thermoelectric, photovoltaic and viscous fluid properties as a function of size and other parameters in nanosystems.
The book deals with physical properties at the nanoscale due to non-local effects introduced by extended irreversible thermodynamics (EIT). The book provides for a systematic approach to understand the behavior of thermal, thermoelectric, photovoltaic and viscous fluid properties as a function of size and other parameters in nanosystems.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Hatim Machrafi obtained his PhD from the Pierre and Marie Curie University (Paris 6), Paris, France. He has been working as a senior researcher at the University of Liège (ULiège), Liège, Belgium, and as visiting researcher at the free University of Brussels (ULB), Brussels, Belgium, specializing in non-equilibrium thermodynamics, nanotechnology applied to energetics and nanomedicine, and advanced materials. Recently, he is also active at the Sorbonne University, Paris, France, in the field of microfluidics and renewable energy.
Inhaltsangabe
1. Extended Non-Equilibrium Thermodynamics: constitutive equations at small length scales and high. 2. Heat transfer in nanomaterials. 3. Heat conduction in nanocomposites. 4. Thermal rectifier efficiency of various bulk-nanoporous silicon devices. 5. Thermoelectric devices. 6. Enhancement of the thermal conductivity in nanofluids and the role of viscosity. 7. Nanoporous flow and permeability. 8. Opto-thermo-electric coupling for photovoltaic energy. 9. Optimal enhancement of photovoltaic energy by coupling to a cooled nanocomposite thermoelectric hybrid system. 10. Nanomedicine: permeation of drug delivery through cell membrane. 11. Self-assembled nanostructures as building blocks for nanomedicine carriers: thermal and electrical conductance.
1. Extended Non-Equilibrium Thermodynamics: constitutive equations at small length scales and high. 2. Heat transfer in nanomaterials. 3. Heat conduction in nanocomposites. 4. Thermal rectifier efficiency of various bulk-nanoporous silicon devices. 5. Thermoelectric devices. 6. Enhancement of the thermal conductivity in nanofluids and the role of viscosity. 7. Nanoporous flow and permeability. 8. Opto-thermo-electric coupling for photovoltaic energy. 9. Optimal enhancement of photovoltaic energy by coupling to a cooled nanocomposite thermoelectric hybrid system. 10. Nanomedicine: permeation of drug delivery through cell membrane. 11. Self-assembled nanostructures as building blocks for nanomedicine carriers: thermal and electrical conductance.
1. Extended Non-Equilibrium Thermodynamics: constitutive equations at small length scales and high. 2. Heat transfer in nanomaterials. 3. Heat conduction in nanocomposites. 4. Thermal rectifier efficiency of various bulk-nanoporous silicon devices. 5. Thermoelectric devices. 6. Enhancement of the thermal conductivity in nanofluids and the role of viscosity. 7. Nanoporous flow and permeability. 8. Opto-thermo-electric coupling for photovoltaic energy. 9. Optimal enhancement of photovoltaic energy by coupling to a cooled nanocomposite thermoelectric hybrid system. 10. Nanomedicine: permeation of drug delivery through cell membrane. 11. Self-assembled nanostructures as building blocks for nanomedicine carriers: thermal and electrical conductance.
1. Extended Non-Equilibrium Thermodynamics: constitutive equations at small length scales and high. 2. Heat transfer in nanomaterials. 3. Heat conduction in nanocomposites. 4. Thermal rectifier efficiency of various bulk-nanoporous silicon devices. 5. Thermoelectric devices. 6. Enhancement of the thermal conductivity in nanofluids and the role of viscosity. 7. Nanoporous flow and permeability. 8. Opto-thermo-electric coupling for photovoltaic energy. 9. Optimal enhancement of photovoltaic energy by coupling to a cooled nanocomposite thermoelectric hybrid system. 10. Nanomedicine: permeation of drug delivery through cell membrane. 11. Self-assembled nanostructures as building blocks for nanomedicine carriers: thermal and electrical conductance.
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