Welcome to all of the Future Engineers. DAY-1 Introduction about your Syllabus.

Slides:



Advertisements
Similar presentations
These aren’t really ‘properties’ – more like definitions that relate to what’s happening microscopically. The goal here is to relate structure to properties.
Advertisements

NANOTECHNOLOGY.
Introduction to Mechatronics and Mechatronics in Real Life Mariya Popovchenko 3 April 2006 JASS 2006, St. Petersburg.
Illustrations In this chapter we describe a general process for designing a control system. A control system consisting of interconnected components is.
Composite Materials A novel interesting field Rui Zhang
Energy efficient scientific methods Materials Engineering By Drs J. Whitty and B. Henderson.
Nanotechnology is receiving a lot of attention of late across the globe. The term nano originates etymologically from the Greek, and it means.
Next Generation Science Standards
MEMs Fabrication Alek Mintz 22 April 2015 Abstract
Design for Engineering Unit 8 Material Science and Engineering
EKT314/4 Electronic Instrumentation
Exploring materials. Polymers and composites Carbon chains- straight chains, branched chains, rings. Most polymers and composites consists of these three.
MECE 1101 Introduction to Mechanical Engineering
Course Name : Material Science
1 Chapter Two Electrical & Computer Engineering Specialization.
Design For Engineering Materials Science 2006 Greg Heitkamp This material is based upon work supported by the National Science Foundation under Grant No.
Copyright ©2011 by Pearson Education, Inc. publishing as Pearson [imprint] Introductory Circuit Analysis, 12/e Boylestad Chapter 21 Decibels, Filters,
Week 1 INTRODUCTION Materials Science
An Introduction to Physics
What's materials science?
Introduction to… Introduction to Engineering. Twenty Reasons to Become an Engineer 1.Engineering allows you to put your creativity to the test every day.
Manufacturing materials – IE251 Chapter 1 Chapter 1, Slide 1 IE 251 Manufacturing materials l Instructor: Dr. Mohamed Ali Eissa Saleh s Room: …………....
Introduction Composite and Nanocomposite Materials
What is Chemistry? The study of the composition, structure, and properties of matter, the processes that matter undergoes and the energy changes that accompany.
Fundamentals of Material Science and Engineering - Introduction Engr. Lina D. dela Cruz Chemical Engineering Department Technological Institute of the.
Background Materials are used in transportation, housing, clothing, communication, recreation, food production. Early materials: Stone, Wood, Clay, etc.
An Introduction to Materials Technology Foundations of Technology Unit 3.10.
Applications of Quantum Physics
Composite Part-2. We have already discussed, Composites include multiphase metal alloys, ceramics and polymers. A composite is considered to be any multiphase.
Introduction to Engineering and Technology Concepts Unit Two Chapter Six – Types of Materials.
Crosscutting Concepts Next Generation Science Standards.
Light. Questions ??? What is light? What is light? Why can we see objects in the presence of light? Why can we see objects in the presence of light? How.
Design for Engineering Ten Major Branches of Engineering Technology Education 660 Unit 1 14 April, Greg Heitkamp This material is based upon.
Chapter Outline 1.1 What is Materials Science and Engineering?
MATERIALS SCIENCE WEEK 1 INTRODUCTION. MATERIAL SCIENCE & ENGINEERING Material -> something tangible that goes into the makeup of a physical object. Material.
Solid-state physics Gorbachenko Vasyl. What is it? Solid-state physics is the study of rigid matter, or solids, through methods such as quantum mechanics,
MECHATRONICS Lecture 02 Slovak University of Technology Faculty of Material Science and Technology in Trnava.
CE 241 MATERIALS SCIENCE Introduction
THE MICROSCOPE Chapter 7. Introduction A microscope is an optical instrument that uses a lens or a combination of lenses to magnify and resolve the fine.
© 2011 Cengage Learning Engineering. All Rights Reserved Chapter 1: Introduction to Materials Science and Engineering Chapter 1: Introduction to.
Engineering Materials
AEM 338 Engineered Materials Testing Introduction to Materials Technology Sergio Sgro Eastern Kentucky University.
Manufacturing Unit 5, Lesson 2 Explanation Presentation © 2011 International Technology and Engineering Educators Association, STEM  Center for.
Chapter 1: Introduction to Control Systems Objectives
Engineering Materials Haseeb Ullah Khan Jatoi Department of Chemical Engineering University of Engg. & Technology Lahore.
Science and Technology through Materials ASM Materials Education Foundation.
Using Technology to Study Cellular and Molecular Biology.
1 Engineering Materials Chapter 3. 2 INTRODUCTION Within the last couple of decades, very rapid development of engineering materials has taken place,
Members ; Siti Sarah Bt Azhar ( ) Nur Marjan Bt Suhaimi ( ) Nurul Afifah Bt Fauzi ( ) Amiera Firzana Bt Mohammad ( ) Alia Syahera.
UNIT PLAN: FROM ATOMS TO POLYMERS Father Judge High School Grade 9 Physical Science Mr. A. Gutzler.
Presented by: Kumar Magi. ( 2MM07EC016 ). Contents Introduction Definition Sensor & Its Evolution Sensor Principle Multi Sensor Fusion & Integration Application.
HISTORICAL PERSPECTIVE  Materials are probably more deep-seated in our culture than most of us realize. Transportation, housing, clothing, communication,
B.V.M. Engineering College MSM Level of structure & Structure Property correlationship : Adodariya Shyam : Amit Chaudhary
Chapter 1. Introduction <Objectives>
CERAMICS. Introduction ~ keramikos - burnt stuff in Greek. ~ Ceramics are inorganic and non-metallic materials that are commonly electrical and thermal.
DLD - DECODER 1 NAMEENROLLMENT NO. PARMAR STANY PATEL ARJUN PATEL KAMAL PATEL KRUNAL GUIDED BY: PROF. R.R.PATEL.
بسم الله الرحمن الرحيم وبه نستعين
ENGINEERING MATERIALS
CHAPTER 1: INTRODUCTION
Chapter Outline 1.1 What is Materials Science and Engineering?
Materials Engineering
© 2016 Cengage Learning Engineering. All Rights Reserved.
EME 201 Materials Science INTRODUCTION.
Accepted Students Program
Prepared by Dr Diane Aston, IOM3
Atomic Structure and Interatomic Bonding
MENG286: INTRODUCTION TO MATERIALS SCIENCE & ENGINEERING
Engineering Materials 26
PDT 153 Materials Structure And Properties
Engineering Materials 23
Presentation transcript:

Welcome to all of the Future Engineers

DAY-1

Introduction about your Syllabus

Science behind Materials Materials- Basic Concepts

Materials ? Everything that we make is based on materials in one form or another and they highlight just about every modern technological development. Everything we use to manufacture everyday objects from cars to bridges, toys to aeroplanes. Materials have literally shaped our society, from everyday plastics through to the advanced superalloys used in jet engines and functional ceramics that form the backbone of our electronic components.

Provide an in-depth knowledge of what things are made of, how they are made and why. Provides a great opportunity to use science and maths skills in a practical way across every industrial sector. Provides a new idea for the development and improvement of new and existing materials by investigating their structure, processing and properties and how they can be used to design and make new and improved products. Why study Materials science?

Materials

Materials science “Oldest forms of engineering and applied science”. A major breakthrough in the understanding of materials Occurred in the late 19th century, when the American scientist Josiah Willard Gibbs demonstrated that the thermodynamic properties related to atomic structure in various phases are related to the physical properties of a material. Materials science has driven, and been driven by, the development of revolutionary technologies such as plastics, semiconductors, and biomaterials.

Materials science, also commonly known as materials engineering, is an interdisciplinary field applying the properties of matter to various areas of science and engineering. This relatively new scientific field investigates the relationship between the structure of materials at atomic or molecular scales and their macroscopic properties.

Role of Materials Science in Society Materials science and engineering plays a vital role in this modern age of science and technology.  Various kinds of materials are used in industry, housing, agriculture, transportation, etc. to meet the plant and individual requirements.  The rapid developments in the field of quantum theory of solids have opened vast opportunities for better understanding and utilization of various materials.  The amazing success in the field of space is primarily due to the rapid advances in high-temperature and high-strength materials.

The basis of materials science involves relating the desired properties and relative performance of a material in a certain application to the structure of the atoms and phases in that material through characterization. The major determinants of the structure of a material and thus of its properties are its constituent chemical elements and the way in which it has been processed into its final form

Classification of Materials Common engineering materials that falls within the scope of material science and engineering may be classified into one of the following six groups:  Metals and alloys  Ceramics  Organic Polymers ( plastics and synthetic rubbers which are termed as organic polymers)  Composites  Semi-conductors  Biomaterials ( Leather, limestone, bone, horn, wax, wood etc. )  Advanced Materials

Advanced Materials The materials that are utilized in high-technology (or high-tech) applications are sometimes called advanced materials. By high technology we mean a device or product that operates or functions using relatively complicated and sophisticated principles; for example: electronic equipment (VCRs, CD players, etc.), computers, fiber optic systems, spacecraft, aircraft and military rocketry. These advanced materials are typically either traditional materials whose properties have been enhanced or newly developed high performance materials. Furthermore, advanced materials may be of all material types (e.g., metals, ceramics, polymers) and are normally relatively expensive. Example, materials that are used for lasers, ICs, magnetic information storage, liquid crystal displays (LCDs), fiber optics, and the thermal projection system for the space shuttle orbiter.

Smart Materials: Materials for Future The adjective “smart” implies that these materials are able to sense changes in their environments and then respond to these changes in predetermined manners. Smart or intelligent materials related with a group of new and state-of- the art materials Important influence on many of our latest technologies

The field of smart materials attempts to combine the sensor (that detects an input signal), actuator (that performs a responsive and adaptive function) and the control circuit on as one integrated unit. Actuators may be called upon to change shape, position, natural frequency, or mechanical characteristics in response to changes in temperature, electric fields, and/or magnetic fields. The concept of smart materials is a complete difficult systems that consist of both smart and traditional materials.

A biological system : The combined system of sensor, actuator and control circuit on as one IC unit, emulates Examples of smart sensors Microsystem technology (MST) or microelectromechanical systems (MEMS). Materials/devices employed as sensors include optical fibers, piezoelectric materials (including some polymers), and MEMS.

Applications of Smart systems Used in helicopters to reduce aero-dynamic cockpit noise that is created by the rotating rotor blades. Piezoelectric sensors inserted into the blades to monitor blade stresses and deformations; feedback signals from these sensors are fed into a computer controlled adaptive device, which generates noise cancelling antidose.

OK Lets Discuss about some more Materials and its Basics

One can examine and observe the internal structure of a material at various levels of observation. The degree of magnification required to study a material by various methods is called a measure of the level of observation. While considering the structures at various levels we may find it is useful to have some concept of relative sizes, and the so-called “logarithmic scale of universe” provides one method of size comparison Level of Materials Structure: Examination and Observation

In recent years, the number and variety of materials, which are of particular interest to an engineer have increased tremendously. Each type of material has a specific composition possessing specific properties for a specific use. It is not possible for one to explain the properties of all types of these materials. A knowledge of the structure of the material helps students and engineers to study the properties of the material. Material structure can be classified as:  macrostructure,  microstructure,  substructure,  crystal structure,  electronic structure  and  nuclear structure. Material Structure

(a)Macrostructure Macrostructure of a material is examined by low-power magnification or naked eye. It deals with the shape, size and atomic arrangement in a crystalline material. Macrostructure may be observed directly on a fracture surface or on a forging specimen. Macrostructure can expose defects, segregations, cracks etc. by using proper techniques and one can save much expenses by rejecting defective materials at an early stage.

(b) Micro Structure This generally refers to the structure of the material observed under optical microscope. Optical microscopes can magnify a structure about 1500 to 3000 times linear, without loss of resolution of details of the material structure. We may note that optical microscopes can resolve two lines separately when their difference of separation is 10 –7 m (= 0.1 m). Cracks, porosity, non-metallic insclutions within materials can be exposed by examining them under powerful optical microscope.

(c) Sub Structure When crystal imperfections such as displacement in a structure are to be examined, a special microscope having higher magnification and resolution than the optical microscope is used. Electron microscope with magnifications 10 5 are used for this purpose. Another important modern microscope is field ion microscope, which can produce images of individual atoms as well as defects in atomic arrangements.

d) Crystal Structure This reveals the atomic arrangement within a crystal. X-ray diffraction techniques and electron diffraction method are commonly used for studying crystal structure. It is usually sufficient to study the arrangement of atoms within a unit cell. The crystal is formed by a very large number of unit cells forming regularly repeating patterns in space. (e) Electronic Structure This refers to the electrons in the outermost shells of individual atoms that form the solid. Spectroscopic techniques are commonly used for determining the electronic structure. (f) Nuclear Structure This is studied by nuclear spectroscopic techniques, e.g., nuclear magnetic resonance (NMR).

Thanks