Dislocation Structures: Grain Boundaries and Cell Walls Dislocations organize into patterns Copper crystal l- ectors_corner/vft/mi4a.htm.

Slides:



Advertisements
Similar presentations
Stress, strain and more on peak broadening
Advertisements

DISLOCATIONS Edge dislocation Screw dislocation.
Lecture 1. How to model: physical grounds
Measurement of Dislocation Creep Based on: Low-Stress High-Temperature Creep in Olivine Single Crystals D.L. Kohlstedt and C. Goetze, 1974 Picture from.
PLASTICITY.
What are dislocations? Recap of 3.14/3.40 Lecture on 9/27/2012 Sangtae Kim Oct/2/2012.
Solid State Physics Yuanxu Wang School of Physics and Electronics Henan University 双语教学示范课程 1.
Plasticity, Ductility 4/15/2017 4/15/2017 1
CHE 333 Class 14 Plastic Deformation of Metals and Recrystallization.
Crackling Noise JPS, Shekhawat, Papanikolaou, Bierbaum, …, Dahmen, Myers, Durin, Zapperi Jan March Oct Dec Month Magnitude 7 8 Hiroshimas Earthquakes:
Grain Boundaries.
ASE324: Aerospace Materials Laboratory Instructor: Rui Huang Dept of Aerospace Engineering and Engineering Mechanics The University of Texas at Austin.
Deformation Micromechanics DUCTILE DEFORMATION AND BRITTLE-DUCTILE TRANSITION.
Deriving Plasticity from Physics? Sethna, Markus Rauscher, Jean-Philippe Bouchaud, Yor Limkumnerd Yield Stress Work Hardening Cell Structures Pattern Formation.
Deformation and Strengthening Mechanisms
What is it? What is it? (Quiz)
PY3090 Preparation of Materials Lecture 3 Colm Stephens School of Physics.
Dislocations and Strengthening
Dislocations zBasic concepts yedge dislocation yscrew dislocation zCharacteristics of Dislocations ylattice strains zSlip Systems yslip in single crystals.
CHE 333 Class 12 Defects in Crystals.. Perfect Structure Perfect Structure for FCC, BCC and HCP crystals – all atom sites filled with an atom. Reality.
Anandh Subramaniam & Kantesh Balani
DISLOCATION MOVEMENT.
Discussion Notes Farzana Ansari Feb 14 & 16, 2012.
3 Physical Properties of Biomaterials CHAPTER
Interfaces in Solids. Coherent without strain Schematics of strain free coherent interfaces Same crystal structure (& lattice spacing) but different composition.
Stress Fields and Energies of Dislocation. Stress Field Around Dislocations Dislocations are defects; hence, they introduce stresses and strains in the.
Lecture 3.0 Structural Defects Mechanical Properties of Solids.
Anandh Subramaniam & Kantesh Balani
How and why things crackle We expect that there ought to be a simple, underlying reason that earthquakes occur on all different sizes. The very small earthquake.
J. L. Bassani and V. Racherla Mechanical Engineering and Applied Mechanics V. Vitek and R. Groger Materials Science and Engineering University of Pennsylvania.
1 Strength and Ductility. 2 Determining Tensile Strength from the stress-strain curve is easy. Just locate the highest point on the curve. TS = 82 ksi.
Bin Wen and Nicholas Zabaras
IMPERFECTIONS IN SOLIDS
OBSTACLES IN DISLOCATION MOTION
STRUCTURAL IMPERFECTIONS (DEFECTS) IN CRYSTALLINE SOLIDS
Lecture 22: The mechanism of plastic deformation, part 2
Plastic Deformation Permanent, unrecovered mechanical deformation  = F/A stress Deformation by dislocation motion, “glide” or “slip” Dislocations –Edge,
Deformation and Strengthening Mechanisms of Materials
PLASTIC DEFORMATION Dislocations and their role in plastic deformation.
Interactions of Quasiparticles
Objectives of Chapter 4 Introduce the three basic types of imperfections: point defects, line defects (or dislocations), and surface defects. Explore.
© 2009 Al-Abdallat Properties of Eng. Material 1 (3) Interfacial defects Interfacial defects: Types: External surfaces, Grain boundaries, Twin boundaries.
Lectures 7 and 8 Dislocations: Foundations of Plastic Deformation ME 330 Engineering Materials Please read Chapters 4 and 7 Dislocation definitions Dislocation.
Friday 12:00 Geology Seminar Dr. Lucy Flesch, Purdue University “Integration of Plate Boundary Observatory and USArray Data to Quantify the Forces Driving.
Nanomechanics Simulation Tool- Dislocations Make or Break Materials Michael Sakano, Mitchell Wood, David Johnson, Alejandro Strachan Department of Biomedical.
Technology for a better society 1 Imaging Dislocations.
Grain Boundary Cohesive Laws as a Function of Geometry Valerie R. Coffman, James P. Sethna Cornell University.
Materials Science Metals and alloys.
3. Crystal interfaces and microstructure
Theoretical shear strength of a solid
Chapter 3: Contributions to Strength
Dislocation Interactions
Imperfections in the Atomic and Ionic Arrangements
Chapter 26 IMAGING STRAIN FIELDS
Dislocations and Strengthening
Engineering materials lecture #12
Plastic Deformation Permanent, unrecovered mechanical deformation
Lecture 9/2: Dislocations
Lecture 8: Dislocations
THE NATURE OF MATERIALS
Ductility and strengthening in crystalline solids
The Ohio State University
Dislocations Dislocations Dislocations
Plastic Deformation of Metals and Recrystallization
Fundamental concepts of metals science
Fundamental concepts of metals science
Plastic Deformation of Metals and Recrystallization
CRYSTAL IMPERFECTIONS
PLASTIC DEFORMATION & DISLOCATIONS
Presentation transcript:

Dislocation Structures: Grain Boundaries and Cell Walls Dislocations organize into patterns Copper crystal l- ectors_corner/vft/mi4a.htm Polycrystal rotations expelled into sharp grain boundaries Plasticity Work Hardening Dislocation Tangles Cell Wall Structures

Crystals are weird No elegant, continuum explanation for wall formation Crystals have broken translational, orientational symmetries Translational wave: phonon, defect: dislocation Orientational wave, defect? Grain boundaries Continuous broken symmetries: magnets, superconductors, superfluids, dozens of liquid crystals, spin glasses, quantum Hall states, early universe vacuum states… Only crystals form walls* Why? *Smectic A focal conics, quasicrystals

Plasticity in Crystals 1 Plas-tic: adj [… fr. Gk. plastikos, fr. plassein to mold, form] … 2 a: capable of being molded or modeled (Webster’s) Bent Fork Metals are Polycrystals Crystals have Atoms in Rows How do Crystals Bend? Crystal Axis Orientation Varies between Grains

Crystals Broken Symmetry and Order Parameters Order Parameter Space is a Torus: U(x) maps physical space into order parameter space Crystals Break Translational Symmetry Order Parameter Labels Local Ground State: Displacement Field U(x) Residual lattice symmetry U(x)  U(x) + n v 1 + m v 2 Unit cell with periodic boundary micro

Dislocations Topology, Burger’s vector, tangling Burger’s vector: loop around defect, registry on lattice shifts (extra columns on top). Topological charge. Dislocation line: tangent t, Burger’s vector b Screw Edge Plastic Deformation: mediated by dislocation line motion, limited by dislocation entanglement climb glide

Crystals and Dislocations Missing Half-Plane of Atoms Dislocations in 3D are Lines (Screw, edge, junctions, tangles) Broken Symmetry, Order Parameters, Topological Defects At Dislocation, Order Parameter Winds Around Torus Winding Number =Topological Charge =Burgers Vector

Work hardening and dislocations 3D dislocations tangle up During plastic deformation under external stress, new dislocations form, tangle up. Harder to push through tangle – increases yield stress. Tangle ‘remembers’ previous maximum stress.

Grain boundaries and dislocations Dislocations form walls Low angle grain boundary wall of aligned dislocations, strength b, separated by d favored by dislocation interaction energy mediates rotation of crystal (  =b/d) strain field ~exp(-y/d) expelled from bulk energy~(b 2 /d)log(d/b) ~-b  log 

Cell Wall Structures Matt Bierbaum, Yong Chen, Woosong Choi, Stefanos Papanikolaou, Surachate Limkumnerd, JPS Dislocation tangles eventually organize also into ‘cell structures’ – fractal walls?

Cellular structures (Glide only) Plastic deformation, relaxing from random “dented” initial strain field DOE BES (Climb & Glide qualitatively sharper in 2D, but rather similar in 3D)

Avalanches when bending forks Small avalanches in Metal Micropillars Dislocation Tangle Structure Dislocation motion happens in bursts of all sizes Ice crackles when it is squeezed So, surprisingly, do other metals Avalanches at microscale Analogies to earthquakes Plasticity fractal in time and space? Kraft Stretch Avalanches in Ice Number Size /1000 cm

Dislocation Structures: Grain Boundaries and Cell Walls Dislocations organize into patterns Copper crystal l- ectors_corner/vft/mi4a.htm Polycrystal rotations expelled into sharp grain boundaries Plasticity Work Hardening Dislocation Tangles Cell Wall Structures

Power laws and scaling Renormalization-group predictions   R-R- Power law <  R   correlations cut off by initial random length scale  correlations ~ R   

Climb & Glide 2D Emergent scale invariance Self-similar in space; correlation functions Real-space rescaling Power law dependence of mean misorientations DOE BES Glide Only Climb & Glide 3D

Refinement Cell sizes decrease and misorientations increase RelaxedStrained Boundaries above  c Self-similar implies no characteristic scale! Size goes down as cutoff  c goes to zero. DOE BES

Compare with previous methods Fractal and non-fractal scaling analysis both realistic Fractal dimension d f ~1.5  0.1 (Hähner expt ) Refinement scaling collapses  av ~ 1/D av ~  0.26  0.14 (Hughes expt  0.5, 0.66 different function) DOE BES