Lecture 1 - Introduction to nanomaterials and nanotechnology
Lecture 2 - Classification of Nanomaterials
Lecture 3 - Need of nanomaterials
Lecture 4 - Application of nanomaterials
Lecture 5 - Concept and Quantum Mechanical Explanation of Electron Confinement
Lecture 6 - Energy Band Diagram in Solid State Materials
Lecture 7 - Crystal Structures and Phase Transitions in Nanomaterials
Lecture 8 - Dimensionality Effects on the Electrical properties
Lecture 9 - Introduction to Synthesis Methods for Nanomaterials
Lecture 10 - Kinetically and Thermodynamically Controlled Routes
Lecture 11 - Top Down and Bottom Up Synthesis Routes - 1
Lecture 12 - Top Down and Bottom Up Synthesis Routes - 2
Lecture 13 - Low Dimensional Structures - Quantum Wells, Wires and Dots; Conduction Electrons and Dimensionality
Lecture 14 - Fermi Gas and Density of States
Lecture 15 - Fermi Gas and Density of States
Lecture 16 - Coulomb Potential and Single Electron Tunnelling
Lecture 17 - Metal Nanoclusters
Lecture 18 - Semiconducting Nanoparticle Clusters
Lecture 19 - Molecular Clusters
Lecture 20 - Quantum Devices - Infrared Detectors and Quantum Dot lasers
Lecture 21 - Application of carbon nanotubes
Lecture 22 - Carbon clusters and nanotubes
Lecture 23 - Electrical, Vibrational and Mechanical Properties of Carbon Nanotubes
Lecture 24 - Application of carbon nanotubes
Lecture 25 - Magnetism at Nanoscale
Lecture 26 - Nanostructured Magnetic Materials
Lecture 27 - Dynamics of Nanomagnets - I
Lecture 28 - Dynamics of Nanomagnets - II
Lecture 29 - Giant Magnetoresistance
Lecture 30 - Colossal Magnetoresistance
Lecture 31 - Nanocarbon Ferromagnets
Lecture 32 - Superparamagnetism and ferrofluids
Lecture 33 - Self Assembly and Catalysis
Lecture 34 - Process of Self Assembly
Lecture 35 - Monolayers and Porous Materials
Lecture 36 - Nature of Catalysis,Pillard Clays and Colloids
Lecture 37 - Nanomaterials for Energy Devices
Lecture 38 - Secondary Batteries
Lecture 39 - Supercapacitors
Lecture 40 - Porous Silicon, Photoluminescence and Photovoltaics
Lecture 41 - Introduction to useful various techniques
Lecture 42 - Particle size determination
Lecture 43 - Phase Transition Using X-ray Diffraction
Lecture 44 - Strain Estimation
Lecture 45 - TEM and SEM
Lecture 46 - Infrared and Raman Spectroscopy
Lecture 47 - Porosity and Specific Surface Areas
Lecture 48 - Infrared and Raman Spectroscopy
