Introduction to Thermoelectricity L1.3: Theory - Seebeck Coefficient
Introduction to Thermoelectricity L1.1: Theory - Introduction
Introduction to Thermoelectricity L1.6: Theory - Figure of Merit
Introduction to Thermoelectricity L1.4: Theory - Peltier Coefficient
Introduction to Thermoelectricity L1.2: Theory - Electrical Conductivity
nanoHUB-U Thermoelectricity L1.3: Bottom-up Approach: A Novel View on Hall Effect
Introduction to Thermoelectricity L1.7: Theory - Summary
Lecture 4: Bottom-up Approach to Thermoelectricity
Thermoelectric Transport 1: BTE Charge Flux Formulation
nanoHUB-U Biodesign L1.3: Introduction - The Cell as a Machine - Power Consumption
nanoHUB-U Thermoelectricity L3.0: Nano/Macroscale Characterization - Introduction and Motivation
Introduction to Thermoelectricity L2.1: Systems - Importance of ZT (material figure-of-merit)
nanoHUB-U Thermoelectricity L3.1: Nano/Macroscale Characterization - Temperature Measurement I
nanoHUB-U Thermoelectricity L1.1: Bottom Up Approach: Landauer Formalism
nanoHUB-U Thermoelectricity L1.4: Bottom-up Approach: Heat Current
nanoHUB-U Thermoelectricity L2.0: Thermoelectric Transport Parameters - Short Introduction
Introduction to Thermoelectricity L2.7: Systems - Summary
Thermoelectric Effects 3: Thermoelectric Transport Coefficients
Introduction to Thermoelectricity L2.3: Systems - Thermoelectrics for Power Generation Applications
Mercouri Kanatzidis, Nanostructured Thermoelectrics
nanoHUB-U Thermoelectricity L3.6: Nano/Macroscale Characterization - Summary of Week 3
nanoHUB-U Thermoelectricity L2.1: Thermoelectric Transport Parameters - Landauer-Boltzmann Approach
Thermoelectric Properties in Cool (and Hot) Materials
nanoHUB-U Thermoelectricity: Scientific Overview Shakouri-Datta-Lundstrom
nanoHUB-U Thermoelectricity L3.3: Nano/Macroscale Characterization - Thermoreflectance
