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by Alec Feinberg
Thermodynamic Degradation Science
Cover
Title Page
List of Figures
List of Tables
About the Author
Preface
1 Equilibrium Thermodynamic Degradation Science
1.1 Introduction to a New Science
1.2 Categorizing Physics of Failure Mechanisms
1.3 Entropy Damage Concept
1.4 Thermodynamic Work
1.5 Thermodynamic State Variables and their Characteristics
1.6 Thermodynamic Second Law in Terms of System Entropy Damage
1.7 Work, Resistance, Generated Entropy, and the Second Law
1.8 Thermodynamic Catastrophic and Parametric Failure
1.9 Repair Entropy
References
2 Applications of Equilibrium Thermodynamic Degradation to Complex and Simple Systems: Entropy Damage, Vibration, Temperature, Noise Analysis, and Thermodynamic Potentials
2.1 Cumulative Entropy Damage Approach in Physics of Failure
2.2 Measuring Entropy Damage Processes
2.3 Intermediate Thermodynamic Aging States and Sampling
2.4 Measures for System-Level Entropy Damage
2.5 Measuring Randomness due to System Entropy Damage with Mesoscopic Noise Analysis in an Operating System
2.6 How System Entropy Damage Leads to Random Processes
2.7 Example 2.8: Human Heart Rate Noise Degradation
2.8 Entropy Damage Noise Assessment Using Autocorrelation and the Power Spectral Density
2.9 Noise Detection Measurement System
2.10 Entropy Maximize Principle: Combined First and Second Law
2.11 Thermodynamic Potentials and Energy States
References
3 NE Thermodynamic Degradation Science Assessment Using the Work Concept
3.1 Equilibrium versus Non-Equilibrium Aging Approach
3.2 Application to Cyclic Work and Cumulative Damage
3.3 Cyclic Work Process, Heat Engines, and the Carnot Cycle
3.4 Example 3.1: Cyclic Engine Damage Quantified Using Efficiency
3.5 The Thermodynamic Damage Ratio Method for Tracking Degradation
3.6 Acceleration Factors from the Damage Ratio Principle
References
4 Applications of NE Thermodynamic Degradation Science to Mechanical Systems
4.1 Thermodynamic Work Approach to Physics of Failure Problems
4.2 Example 4.1: Miner’s Rule
4.3 Assessing Thermodynamic Damage in Mechanical Systems
4.4 Cumulative Damage Accelerated Stress Test Goal: Environmental Profiling and Cumulative Accelerated Stress Test (CAST) Equations
4.5 Fatigue Damage Spectrum Analysis for Vibration Accelerated Testing
References
5 Corrosion Applications in NE Thermodynamic Degradation
5.1 Corrosion Damage in Electrochemistry
5.2 Example 5.2: Chemical Corrosion Processes
5.3 Corrosion Current in Primary Batteries
5.4 Corrosion Rate in Microelectronics
References
6 Thermal Activation Free Energy Approach
6.1 Free Energy Roller Coaster
6.2 Thermally Activated Time-Dependent (TAT) Degradation Model
6.3 Free Energy Use in Parametric Degradation and the Partition Function
6.4 Parametric Aging at End of Life Due to the Arrhenius Mechanism: Large Parametric Change
References
7 TAT Model Applications: Wear, Creep, and Transistor Aging
7.1 Solving Physics of Failure Problems with the TAT Model
7.2 Example 7.1: Activation Wear
7.3 Example 7.2: Activation Creep Model
7.4 Transistor Aging
References
8 Diffusion
8.1 The Diffusion Process
8.2 Example 8.1: Describing Diffusion Using Equilibrium Thermodynamics
8.3 Describing Diffusion Using Probability
8.4 Diffusion Acceleration Factor with and without Temperature Dependence
8.5 Diffusion Entropy Damage
8.6 General Form of the Diffusion Equation
Reference
9 How Aging Laws Influence Parametric and Catastrophic Reliability Distributions
9.1 Physics of Failure Influence on Reliability Distributions
9.2 Log Time Aging (or Power Aging Laws) and the Lognormal Distribution
9.3 Aging Power Laws and the Weibull Distribution: Influence on Beta
9.4 Stress and Life Distributions
9.5 Time- (or Stress-) Dependent Standard Deviation
References
10 The Theory of Organization
Special Topics A
A.1 Introduction
A.2 The Key Reliability Functions
A.3 More Information on the Failure Rate
A.4 The Bathtub Curve and Reliability Distributions
A.5 Confidence Interval for Normal Parametric Analysis
A.6 Central Limit Theorem and Cpk Analysis
A.7 Catastrophic Analysis
A.8 Reliability Objectives and Confidence Testing
A.9 Comprehensive Accelerated Test Planning
References
Special Topics B
B.1 Introduction
B.2 Power Law Acceleration Factors
B.3 Temperature–Humidity Life Test Model
B.4 Temperature Cycle Testing
B.5 Vibration Acceleration
B.6 Multiple-Stress Accelerated Test Plans for Demonstrating Reliability
B.7 Cumulative Accelerated Stress Test (CAST) Goals and Equations Usage in Environmental Profiling
References
Special Topics C
C.1 Spontaneous Negative Entropy: Growth and Repair
C.2 The Perfect Human Engine: How to Live Longer
C.3 Growth and Self-Repair Part of the Human Engine
C.4 Act of Spontaneous Negative Entropy
References
Overview of New Terms, Equations, and Concepts
Key Words
New Terms, Equations, and Concepts
Please Do Cite the Author
Index
End User License Agreement
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