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nanoHUB-U Rechargeable Batteries T4.1: Interfacial Reactions - Homework Solution - Thermodynamics

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Uploaded on May 8, 2014

Table of Contents:
00:09 Introduction to the Materials Science of Rechargeable Batteries
00:15 1. Thermodynamic Radius of Nucleation
05:55 2. Critical Radius
06:39 3. Critical Free Energy
07:25 4.1 Dendrite Radius: flat surface, non-zero overpotential
11:15 4.2 Dendrite Radius: flat surface, non-zero overpotential
12:01 4.3 Dendrite Radius: flat surface, zero overpotential
14:36 4.4 Dendrite Radius: flat surface, zero overpotential

This video is part of the nanoHUB-U course "Introduction to the Materials Science of Rechargeable Batteries" (http://nanohub.org/courses/imsb)

This course will provide an introduction to the fundamentals behind the equilibrium and time-dependent response of existing and emerging chemistries of Li-ion battery materials. Effects of material selection and processing on the performance and reliability are presented as a means to develop conceptual guidelines to understand and improve battery designs. Example applications such as intercalation, SEI, and dendrite growth are presented. Integration of experimental microstructural aspects to coarse-graining measured properties, such as porosity, tortuosity and its associated reactivity, and classic and emerging battery architectures are presented. Principles summarizing the response of battery architectures are formulated and applied to propose battery design guidelines, to review existing porous electrode theory descriptions, and to summarize the current state-of-the-art of battery technology and its associated metrology.

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