Engineering
Lithium-Ion Batteries
100%
Battery (Electrochemical Energy Engineering)
53%
Nickel Manganese Cobalt
40%
Reliability Assessment
32%
Failure Model
30%
Crack Propagation
22%
Aging Effect
21%
Battery Capacity
20%
Thermal Resistance
19%
Interconnects
18%
Failure Mechanism
18%
Physical Model
18%
Joints (Structural Components)
16%
Thermal Characteristic
16%
Power Device
16%
Interface Layer
16%
Coupled Model
16%
Solid Electrolyte Interface
16%
Single Event Upset
16%
Life Prediction
16%
Electrical Contact
16%
Feature Extraction
16%
Crack Formation
16%
Energy Engineering
16%
Multiscale Modeling
16%
Maximum Entropy
16%
Storage Life
16%
Microstructural Evolution
16%
Liquid Metal
16%
Active Material
16%
Coefficient of Thermal Expansion
16%
Primary Factor
16%
Heterojunctions
16%
Visual Inspection
16%
Material Interface
16%
Scanning Acoustic Microscopy
16%
Failure Mode
16%
Delamination
16%
Module Design
16%
Wide Bandgap Semiconductor
16%
Failure Analysis
16%
Performance Degradation
16%
Solid Electrolyte Interphase
16%
Current Profile
14%
Internal Resistance
12%
Mechanical Stress
12%
Finite Element Simulation
11%
Experimental Result
8%
Sampling Process
8%
Macroscale
8%
Material Science
Lithium Ion Battery
81%
Battery (Electrochemical Energy Engineering)
69%
Cobalt
32%
Manganese
32%
Oxide Compound
32%
Lithium
30%
Scanning Electron Microscopy
22%
Plating
22%
Finite Element Methods
21%
Crack Propagation
18%
Anode
17%
Density
16%
Silver
16%
Microstructural Evolution
16%
Elasticity
16%
Liquid Metal
16%
Solid Electrolyte
16%
Crack Formation
16%
Thermal Fatigue
16%
Thermal Cycling
16%
Solid Electrolyte
16%
State-of-Charge
12%
Heat Resistance
11%
Electrochemical Reaction
9%
Sintering Temperature
8%
Weibull Distribution
8%
Young's Modulus
8%
Poisson Ratio
8%
Heterojunction
8%
Interface (Material)
8%
Electron Mobility
8%
Wide Bandgap Semiconductor
8%
Delamination
8%
Scanning Acoustic Microscopy
8%
Transistor
8%
Interface Fracture
8%
Thermal Expansion
8%
Elastic Moduli
5%
Thermal Shock
5%
Keyphrases
Degradation Behavior
20%
Lithium-ion Battery
20%
Physics-informed Machine Learning
18%
Silver Joints
16%
Maximum Entropy Bootstrap
16%
Multiscale Modeling Method
16%
Sintered Joint
16%
Electromagnetic Relay
16%
Pressureless
16%
PC Operation
16%
Solid Electrolyte Interface Layer
16%
Mechanism Consistency
16%
Metal Interconnect
16%
Degradation Diagnosis
16%
Mixed Inputs
16%
Mechanism Degradation
16%
Evolution of Aging
16%
Loss Scenarios
16%
Capacity Loss
16%
Nickel Manganese Cobalt Oxide
16%
Battery Aging
16%
Digital Twin
16%
Aging Modes
16%
Fast-charging Protocol
16%
SEI Growth
14%
Equivalent Cycles
13%
SEI Layer Growth
10%
Lithium Plating
9%
Accelerated Storage
8%
Temperature Protocol
8%
Charging History
8%
Charging Protocol
6%
Physical Foundations
6%
Effective Elastic Modulus
5%
Test-taking
5%
Macro Properties
5%
Silver Sintering
5%
Microscopic Void
5%
Representative Element
5%
Macroscopic Performance
5%
Equivalent Poisson's Ratio
5%
Right-skewed
5%
Preferred Models
5%
Cyclic Aging Tests
5%
Evolution Law
5%
Current Motivation
5%
Electrochemical Model
5%
Lithium-ion Battery Applications
5%
Basic Physics
5%
Pie Chart
5%