Magnetic Shape Memory Alloys Chris Ziegler ENMA490 September 10, 2002.

Slides:

Advertisements

Similar presentations

Magnetostrictive Materials for X-Ray Optics

Advertisements

Teaching Modern & Smart Materials in Design & Technology A practical look at materials presented by TEP at the DATA Millennium conference Chris Rice Director.

Shape Memory Alloys.

SHAPE MEMORY ALLOY I.i.t. Indore R.r.c.a.t. indore

1 Kinetics – time dependence of transformation rate.

Applications of Shape Memory Alloys to MEMS MAE 268 Greg Jarmer and Garrett Uyema.

Chapter 5 Ferrous Alloys.

Engr. Abbas Abbasi Behavior of Ferromagnetic Materials Saturation and Hysteresis.

Latching Shape Memory Alloy Microactuator ENMA490, Fall 2002 S. Cabrera, N. Harrison, D. Lunking, R. Tang, C. Ziegler, T. Valentine.

Chang Liu MASS UIUC Micromachined Piezoelectric Devices Chang Liu Micro Actuators, Sensors, Systems Group University of Illinois at Urbana-Champaign.

Seth R. Hills ECE5320 Mechatronics Assignment #1

E 3 AEROSPACE ENGINEERING RESEARCH SHAPE MEMORY ALLOYS (SMA S ) ¡ E3 Teacher Summer Research Program Aerospace Engineering Texas A & M University By Moses.

Shape memory Topic 11.

Dimitris C.Lagoudas Shape Memory Alloy Research Team Aerospace Engineering Department Texas A&M University Intelligent Systems Laboratory An Introduction.

PY3090 Preparation of Materials Lecture 3 Colm Stephens School of Physics.

Shape Memory Alloy Cantilever Beam Mike Hilldoerfer Numerical Analysis for Engineers April 10, 2001.

Compensation of residual stress in welds using phase transformation.

Heat Treatment of Metals

Thermal Processing of Metal Alloys

Physics 87N Elaine Zelby Kevin Bird Amit Patel Δ

Figure 2. Mechanical coupling between magnetostrictive coating and substrate that is exposed to a magnetic field. 1. Introduction/Background The use of.

Smart Materials in System Sensing and Control Dr. M. Sunar Mechanical Engineering Department King Fahd University of Petroleum & Minerals.

Smart Materials.

WELCOME TO THE PRESENTATION ON SMART MATERIALS (SMA)

HIGH PERFORMANCE MATERIALS Developments Synthetic rubber. Polyvinyl chloride (PVC). New molding and extrusion techniques for plastics. Polystyrene.

Magnetic domain characterization  Lorentz transmission electron microscopy (LTEM) imaging techniques are used to image the magnetic domain structure of.

Sensors and sensor system Graduated, Yeungnam university

Smart Materials A smart fluid developed in labs at the Michigan Institute of Technology. Source: MEMS/sma_mems/smrt.html.

Ni-Ti AND Ni-Mn-Ga NANOCRYSTALLINE SHAPE MEMORY ALLOYS AND COMPOSITES FOR NEXT GENERATION SENSORS AND ACTUATORS Teodor M. Breczko Lab of Functional Materials.

Recap of 11/26/ /3.40J/22.71J Physical Metallurgy 12/03/2013 Intak Jeon Department of Materials Science and Engineering Massachusetts Institute.

Fabrication and Properties of MSMA Thin Films Hierarchical Manufacturing and Modeling for Phase Transforming Active Nanostructures D.C. Lagoudas a, K.

Jianwei Dong, J. Q. Xie, J. Lu, C. Adelmann, A. Ranjan, S. McKernan

A study of Thin Film Shape Memory Alloys By Rajlakshmi Purkayastha Metallurgical and Materials Science IIT Bombay.

Shape Memory Alloys Theresa Valentine ENMA490 Fall 2002.

Technical Seminar Presentation 2004 Presented by - PRIYANKA MISHRA EI SHAPE MEMORY ALLOYS Technical Seminar Report On “SHAPE MEMORY ALLOYS” under.

Presented by Gokul R 7th semester Mechanical

Annealing, Normalizing, and Quenching of Metals

Classes of Magnetic Materials. Magnetic susceptibility quantitative measure of the extent to which a material may be magnetized in relation to a given.

Presented by: Nicholas S. Garcia Mentor: Dr. Constantin Ciocanel Northern Arizona University Mechanical Engineering.

ENHANCEMENT OF HIGHLY MAGNEOSTRICTIVE COBALT FERRITE FOR ADVANCED SENSOR AND ACTUATOR APPLICATIONS I. C Nlebedim Wolfson Centre for Magnetics, Cardiff.

SHAPE MEMORY ALLOYS Presented by Afsal.f S 7 Mechanical.

Magnets and Magnetic Fields Magnetic Forces. Is the force a magnet exerts on another magnet, on iron or a similar metal, or on moving charges. - acts.

NOVEL NiTi SHAPE MEMORY ALLOY FILMS Manfred Wuttig Manfred Wuttig  Tel  Fax  CONTENTS OF PRESENTATION.

Shape Memory Alloys Nickel Titanium By Richard Cordero II.

CHAPTER 11: PHASE TRANSFORMATIONS

© 2002 by the Regents of the University of Minnesota AEM Research on Solid Mechanics and Materials Science Richard James Department of Aerospace Engineering.

Magnetostrictive properties of nanocellulose Terfenol-D film composite for actuation and sensing applications Aleksey Yermakov EMC and Optics Laboratories.

March 28, 2008 New Materials from Mathematics – Real and Imagined Richard James University of Minnesota Thanks: John Ball, Kaushik Bhattacharya, Jun Cui,

An Introduction to Ferrous Metallurgy TSM 233 Unit 13.

MAGNETRON SPUTTERING OF NI-TI THIN FILM SIMULATION BY USING EMBEDDED ATOM MODEL *Ajit Behera, M. Gupta, S. Aich and S. Ghosh Department of Metallurgical.

SEMINAR ON SHAPE MEMORY ALLOYS

Physical analysis of the electroactive morphing effects around a supercritical wing at high Reynolds number by means of High-Speed PIV Supervised by: Prof.

Simulation of Phase transformation behavior of NiTi doped with Cu during loading using classical molecular dynamics S. Aich, A. Behera and S. Ghosh Department.

Nitinol Copyright © 2012 Board of Trustees, University of Illinois. All rights reserved.

SMART MATERIALS. Introduction:- Nature is full of magic materials. Nature is full of magic materials. Smart materials can sense, stimulate, process and.

INTRODUCTION TO SMART MATERIALS

What are shape memory alloys? Shape Memory Alloys A shape-memory alloy is an alloy that "remembers" its original, cold-forged shape: returning the pre-deformed.

Seminar On Smart material

Vadodara Institute of Engineering

HEAT TREATMENT PROCESS

Multiferroics as Data Storage Elements

SHAPE MEMORY ALLOYS Presented by

SMART MATERIALS GOPINATH.M M.Tech Istyr AUTOMOTIVE COMPENENTS

Combinatorial study of magnetic metallic alloys

Modern Engineering Materials

BY SYNDICATE NO 2.

Haluk E. Karaca Research Interests: Processing-microstructure-mechanical property relationships in metals, (ferro)magnetic and conventional.

Smart Materials.

Dr. Wuttig’s Research on SMAs and MEMS A Brief Summary

Presentation transcript:

Magnetic Shape Memory Alloys Chris Ziegler ENMA490 September 10, 2002

Shape Memory Alloys -General Description of how they work -Twinning Combinatorial Approach -Cantilever Fabrication -Deposition -Rapid Analysis Magnetic Shape Memory Alloys -Similar functionality to SMA -Magnetostriction -Applications and downfalls

Shape Memory Alloys -Austenite-Martensite Transformation Austenite Cooling Polydomain Martensite Applied Stress Single-domain Martensite Re-heating Austenite -Twinning- Formation of symmetrical, inter-grown crystals -Shape Memory Alloys (NiTi, NiMnGa) are used in switches, actuators, airplane components, and other applications.

The Combinatorial Approach to finding new Shape Memory Alloys Capacitance Measurement -Change in capacitance as a function of cantilever deflection -1 Composition at a time! Optical Measurement -Cantilever Library Fabricated -Sputter Deposition of composition spread -Optical Measurement -Shape Memory Effect seen by eye Combinatorial Science = Rapid Characterization of a spread of material V

Composition Spread x x guns spread profile distance between guns & substrate Raising and lowering the stage in which the sample rests results in different composition gradients across wafer surface. Picture of the 3 sputtering guns, each capable of holding a different “target”

Rapid Detection of Martensitic Transformation

Magnetic Shape Memory Alloys: What are they? -An alloy that demonstrates the Austenite to Martensite phase transformation (Shape Memory Effect) -An alloy that is ferromagnetic (possibly a need for Iron, Cobalt, or Nickel in the alloy) -The most well known “MSMA” is NiMnGa -Nickel Manganese Gallium has an L 21 crystal structure

How do they work? Magnetic Moments without applied magnetic Field Parallel Alignment of Magnetic Moments within the twins with applied field Redistribution of twin “variants”

Magnetostriction Definition: Spontaneous deformation of a solid in response to its magnetization (James and Wuttig) -Discovered in 1842 by James Joule while experimenting with nickel (a ferromagnetic material) -examples: Terfenol-D, Alloys including Iron, Cobalt, or Nickel, PZT, etc… -If martensitic material is ferromagnetic there is a possibility that application of a magnetic field will rearrange the martensite variants! This results in strains one order of magnitude or higher than that of Giant Magnetostrictive materials.

Thin Film Applications for Magnetic Shape Memory Alloys -Switches and Actuators that are both more responsive and more cost-efficient. -Microwrapper – used for controlling micro- organisms and even tumor removal in the medical industry -Metal MSMA more responsive and less brittle than Terfenol-D -Associated Large-Energy Density for MEMS use html

Summary -MSMA’s exist due to their ferromagnetic and phase transformation characteristics -Metal Alloys such as NiMnGa exhibit strains on the order of 6% as compared to the.2% exhibited by Terfenol-D -Actuation by application of a magnetic field is inexpensive, very sensitive, and requires less time than the heating required for general SMA’s -Very few MSMA’s well known at this point paving the way for Combinatorial Discovery

QUESTIONS? Football is good!