Prof. Ratna Kumar Annabattula

0:43:25

Lecture 21 - Introduction to Fracture Mechanics, Griffith's Analysis of a Cracked Body

0:06:39

Introduction - Basics of Material Engineering

0:33:10

Lecture 1 Part 1 - Introduction

0:39:53

Lecture 23 - Fatigue Failure of Materials (Introduction, Historical Events, S-N Diagram)

0:26:51

Lecture 27 Part 2 - Fatigue Failure of Materials (Fatigue Crack Growth, Paris' law)

0:19:37

Lecture 1 Part 2 - Material Property Landscape

0:41:19

Lecture 33 Part 2 - Phase Diagrams (Iron-Iron Carbide Phase Diagram)

0:20:44

Lecture 22 Part 2 - Fracture Mechanics (Crack Resistance, Stress Intensity Factor)

0:25:24

Lecture 37 - Heat Treatment of Steels (Annealing and Normalizing)

1:36:51

LIVE - Basics of Materials Engineering

0:27:18

Lecture 16 - Static Failure Theories (Introduction, Definition of Failure)

0:21:39

Lecture 27 Part 1 - Fatigue Failure of Materials (Fatigue Stress Concentration Factor)

0:06:50

Lecture 6 Part 2 - Defects in Crystalline Materials - 1 (Point Defects)

1:15:32

Basics of Materials Engineering

0:12:40

Lecture 28 Part 1 - Phase Diagrams (Introduction)

0:25:44

Lecture 22 Part 1 - Fracture Mechanics (Energy Release Rate)

0:25:24

Lecture 24 Part 2 - Fatigue Failure of Materials (High Cycle Fatigue, Low Cycle Fatigue)

1:25:22

LIVE - Basics of Materials Engineering

0:37:51

Lecture 36 - Martensite Transformation, C-C-T Diagram

0:40:13

Lecture 14 - Mechanical Properties (Tension Test - Plastic Deformation)

0:20:48

Lecture 15 - Mechanical Properties (Hardness Test)

0:25:34

Lecture 7 Part 2 - Defects in Crystalline Materials - 2 (Point Defects and Solid Solutions)

0:07:28

Lecture 19 Part 2 - Static Failure Theories (Failure of Brittle Materials)

0:33:22

Lecture 35 - Isothermal Transformation Diagram