Part I: Theory for nanoscale thermal behavior and composites/suspensions 1. Underlying Physics and Basic Approaches to Thermal Transport in Solids 2. Effective Medium Theory for Predictions of the Thermal Conductivity of Multiphase Carbon-based Nanocomposites: Methodologies and Applications
Part II: Experimental methods to investigate heat transfer in nanoscale 3. Characterization of Thermal Conductivity, Diffusivity, Specific Heat, and Interface Thermal Resistance of Carbon Nanostructures
Part III: Computational methods 4. Computational Method of Thermal Transport Property 5. Multiscale Simulation Methods: Molecular Dynamics and Dissipative Particle Dynamics Techniques 6. Modelling Heat Transport in Nano-Composites through Multiple Length Scales 7. Computational Methodologies for Estimating Thermal Boundary Resistance and Effective Thermal Conductivity of Nanocomposites 8. An Unintrusive Approach for Computation of Derivatives: Applications in Nanoscale Thermal Transport
Part IV: Applications 9. Advanced Thermal Properties of Carbon-Based Aerogels 10. Graphene-based thermal nanocomposites: fundamentals and application 11. Thermal Conductivity of Polymer Nanocomposites: Applications of Molecular Dynamics Simulations 12. Photothermal Therapy Using Carbon Nanotubes for Treating Cancer