Name: Battery Electrode
Author: bjzgcai

Battery Electrode Analysis

Computational workflows for battery electrode characterization: voltage profiles, ion transport, and electrochemical stability.

Sub-Skills

Sub-Skill	Directory	Description
Intercalation Voltage	`intercalation-voltage/`	Average and step voltage profiles for intercalation cathodes/anodes. Convex hull of Li_xMO compositions. Methods: ASE+MACE (screening) or QE DFT+U (publication).
Ion Diffusion	`ion-diffusion/`	Li-ion (or Na, K, Mg) diffusion coefficients and migration barriers. AIMD with Arrhenius analysis or NEB for single-barrier. Methods: ASE+MACE MD or ASE+MACE NEB.

Method Decision Guide

What electrode property do you need?

Voltage profile (average V, step V, capacity)?
  --> intercalation-voltage/
  Quick screening --> ASE + MACE
  Publication quality --> QE DFT+U

Ion transport (diffusion coefficient, migration barrier, activation energy)?
  --> ion-diffusion/
  Single migration barrier --> NEB (Method B in ion-diffusion/)
  Full diffusion coefficient D(T) and Ea --> AIMD + Arrhenius (Method A in ion-diffusion/)

Both voltage and transport for a new cathode material?
  --> Run intercalation-voltage/ first to confirm electrochemical viability,
      then ion-diffusion/ for rate capability assessment.

Battery Electrode Analysis

Computational workflows for battery electrode characterization: voltage profiles, ion transport, and electrochemical stability.

Sub-Skills

Sub-Skill	Directory	Description
Intercalation Voltage	`intercalation-voltage/`	Average and step voltage profiles for intercalation cathodes/anodes. Convex hull of Li_xMO compositions. Methods: ASE+MACE (screening) or QE DFT+U (publication).
Ion Diffusion	`ion-diffusion/`	Li-ion (or Na, K, Mg) diffusion coefficients and migration barriers. AIMD with Arrhenius analysis or NEB for single-barrier. Methods: ASE+MACE MD or ASE+MACE NEB.

Method Decision Guide

What electrode property do you need?

Voltage profile (average V, step V, capacity)?
  --> intercalation-voltage/
  Quick screening --> ASE + MACE
  Publication quality --> QE DFT+U

Ion transport (diffusion coefficient, migration barrier, activation energy)?
  --> ion-diffusion/
  Single migration barrier --> NEB (Method B in ion-diffusion/)
  Full diffusion coefficient D(T) and Ea --> AIMD + Arrhenius (Method A in ion-diffusion/)

Both voltage and transport for a new cathode material?
  --> Run intercalation-voltage/ first to confirm electrochemical viability,
      then ion-diffusion/ for rate capability assessment.

Material	Working Ion	Voltage vs Li/Li+ (V)	Capacity (mAh/g)
LiCoO2 (LCO)	Li	3.7 -- 4.2	~140
LiFePO4 (LFP)	Li	~3.4 (flat)	~170
LiMn2O4 (LMO)	Li	3.9 -- 4.1	~120
LiNi0.33Mn0.33Co0.33O2 (NMC111)	Li	3.6 -- 4.3	~160
LiNi0.8Mn0.1Co0.1O2 (NMC811)	Li	3.6 -- 4.3	~200
Li4Ti5O12 (LTO, anode)	Li	~1.55 (flat)	~175
Graphite (anode)	Li	0.01 -- 0.2	~372

Battery Electrode

Battery Electrode Analysis

Sub-Skills

Method Decision Guide

Battery Electrode

Battery Electrode Analysis

Sub-Skills

Method Decision Guide

Common Prerequisites

Typical Voltage Ranges for Common Cathodes

Continuous Learning V2

Continuous Learning V2

Continuous Learning V2

Continuous Learning

Continuous Learning

Pytorch Patterns