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Material Science

✴ To make any engineered device, structure or product you need the right material. Materials Science and En...

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✴ To make any engineered device, structure or product you need the right material.
Materials Science and Engineering is the study of all materials, from those we see and use everyday such as a glass or a piece of sport equipment to those used in aerospace and medicine.✴

Materials Scientists or Engineers, through understanding how materials work, can create new materials for new applications as well as develop existing materials to improve performance. They can control the structure of a material, from an atomic level up, so that its properties, for example strength, can be tailored to suit a particular application.✦

❰❰ In This App we have elaborated All basic to Advanced concepts on Material science. ❱❱

Few Topics Covered in this App are Listed Below】

Material Science Introduction

Importance of Materials

Historical Perspective

Why Study Materials Science and Engineering?

Classification of Materials

Advanced Materials

Modern Material's Needs

Thomson atomic model

Rutherford model

Bohr model

Modern concept of atomic model

Primary Interatomic Bonds - Ionic Bonding

Covalent Bonding

Metallic Bonding

Secondary Bonding (Van der Waals)

Crystallography

Bravais lattices

Metallic Crystal Structures

Crystalline and Non-crystalline materials

Miller Indices

Imperfections in Solids

⇢ X-RAY DIFFRACTION

Elastic deformation

Plastic deformation

Tensile Properties

True Stress and Strain

Mohs Hardness Scale

The Brinell Hardness Test

Rockwell Hardness Test

Vickers Hardness Test

⇢ Micro-hardness Test

The Scleroscope Hardness Test

The Durometer

Failure - Fundamentals of Fracture

Ductile Fracture

Brittle Fracture

Impact Fracture

Ductile brittle transition

Fatigue

Crack Initiation and Propagation

Creep

Stress and Temperature Effects

Dislocations and Strengthening Mechanisms

Plastic Deformation

Mechanisms of Strengthening in Metals

Strengthening by Grain Size Reduction

⇢ Solid-Solution Strengthening

Strain Hardening

⇢ Non-Destructive testing (NDT)

Ultrasonic Test

⇢ Liquid-Penetration test

Microstructural Exam

Grain size determination

Phase Diagrams

Interpretation of phase diagrams

Eutectoid and Peritectic Reactions

Precipitation reactions

Kinetics of nucleation and growth

Solid Solutions

The Iron–Carbon Diagram

Critical temperatures

Various types of carbon steel

Alloy steel

Cast iron

Grey cast iron

White cast iron

Malleable cast iron

Ductile cast iron

Cast Iron Uses

Heat Treatment

Full annealing

Normalizing

Process Annealing

Stress Relief Anneal

Spheroidization

Tempering

Hardening

Quench Media

Case Hardening

Carburizing

Cyaniding

Nitriding

Flame Hardening

Diffusion

Copper Alloys

Aluminum

Zinc

Chromium

Brasses & Bronzes

Dielectric Materials

Dielectric strength

Intrinsic dielectric strength

Magnetic Properties

Ferromagnetism

Antiferromagnetism

Hard Magnetic Materials

Soft Magnetic Materials

Magnetic Tapes

Magnetic Disks

Electrical Properties

Electrical Resistivity of Metals

Semiconductivity

Semiconductor Devices

Conduction in Ionic Materials

Superconductivity

Meissner Effect & Superconductor Types

Ceramics (Applications and Processing)

Types and applications of ceramics

Portland Cement

Processing of Plastics

COMPOSITES

Smart materials

Nano - Materials

FRACTURE

FATIGUE

Crack Initiation and Propagation

Corrosion of Ceramics

Last update

Jan. 19, 2020

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