CME 8373 Student Contributions(Spring 2015)

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*Contribution 3: [[3140 Steel|3140 Steel Stress-Strain Curve]]
 
*Contribution 3: [[3140 Steel|3140 Steel Stress-Strain Curve]]
 
*Contribution 4: [[3140 Steel|3140 Steel Fatigue-life Curves]]
 
*Contribution 4: [[3140 Steel|3140 Steel Fatigue-life Curves]]
*Contribution 5:
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*Contribution 5: [[Microstructure-based multistage fatigue modeling of a cast AE44 magnesium alloy]]
 
*ICME Slide: [[Multi-Scale Modeling of Copper Electrochemical Catalyst]]
 
*ICME Slide: [[Multi-Scale Modeling of Copper Electrochemical Catalyst]]
  

Revision as of 10:17, 5 May 2015

< ICME 2015 Overview

Contents

Overview

To demonstrate your understanding of the cyberinfrastructure and ICME you must complete a total of five (5) contributions to the ICME site as well as add a page related to the topic you have chosen to investigate using ICME methods. As you complete each of these contributions remember to categorize each page you create as well as link that page to the appropriate length scale for the material and/or material model that you are working with.

Once you have obtained your login credentials and are able to edit pages you should visit the Editing ICME page to better understand the methods for creating and editing pages required for your contributions. Another helpful tip is to click on the Edit tab at the top of the page or in a particular section to view how others have formatted pages and sections.

Maintaining the format from previous classes, there are "Student #" sections available that are to be claimed by the student. You will place a brief description and any relevant links for each of your contributions in the "Student #" section you choose. Email the "Student #" you have chosen to Shane Brauer. DO NOT list your name on this page!

Details for each contribution to be made are given in the subsequent sections. DO NOT WAIT UNTIL THE LAST WEEK OF CLASS TO COMPLETE THESE!!

Contribution 1

Add a page or pages to the site related to an area of research that you are an expert in.

An example for this contribution is experimental testing of a metal using an Instron machine. In this example the page for Instron testing machines was first created then populated with information pertaining to several of their machines. Next, several machines housed at CAVS were listed and briefly described. After creating those sections cross-linking was performed to ensure that people looking for equipment at CAVS were directed to the correct page. A section for performing compression tests was then created to briefly describe the setup and execution of a single test. The last item addressed was categorizing the page created. Categorizing pages is an additional step that helps identify other pages that may be of interest to someone, but do not have a direct association with the page they are currently on.

The following excerpt was used for completing the experimental method of compression tests.


Here you would describe the methodology for testing the material as well as the Instron machine. 
* Are you using cylindrical samples? 
* Compression or tension? 
* Why should you use an extensometer? 
* Do you have images to contribute to this section (say an image of the machine or the setup of the test)?

There are several other contributions that could be made on this example page just related to testing a metal.

Subjects that could use attention:

  • Testing machinery available at CAVS -- What is it? Why/how is it used?
  • Experimental methods for those machines -- Compression, tension, torsion, etc.; Metals, polymers, biomaterials, etc.;
  • Experimental techniques for viewing and quantifying microstructures -- Mounting, polishing, etching, etc.
  • Examples for running simulations
  • Tutorials for quantifying microstructures -- There are various softwares used for this. (e.g. Using ImageJ to find the grain size, void size, volume fractions, etc.). A tutorial can come in the form of a written tutorial or video tutorial.

There are countless other areas that are related to your research that have yet to make their way onto the ICME site. Remember that although some of these subjects may seem trivial to you, others may not find them so simple, and for that reason it is extremely important to be thorough in describing the machines, methods, etc. that you are contributing too.

If you feel that you are not an expert in any one area, or you cannot contribute to the subjects mentioned above, please speak with Dr. Horstemeyer or Dr. Shelton about a topic for contribution.

Contribution 2

To improve the robustness of the ICME website you will be tasked with cross-linking and categorizing pages that have already been populated. You are to find a minimum of two (2) pages that need to be cross-linked and/or categorized appropriately. Once you have completed your contribution list the pages that were updated along with the specific corrections that you made. Cross-linking of pages will take place in a similar fashion as discussed in Contribution 1. Proper categorization is defined as having a minimum of three (3) categories to describe a page.

Keep in mind the saying "all roads lead to Rome" for this contribution as you are browsing the site i.e. Macroscale experiments, models, data, etc. should all be accessible from the Macroscale category page and should link back to the appropriate Macroscale page.

This site is accessed from all over the world directly and indirectly. These people may come to a dead-end page that has no categories nor links to additional pages, which could turn them away from continued use of the ICME site. We can prevent that from happening by adding the appropriate categories and cross-linking.

Excellent places to start are dead-end pages and uncategorized pages. These pages do not link to other pages on the site and are typically not categorized (note that some of these pages are spam and can be ignored).

Contribution 3

Each student will add stress-strain data pertaining to a material of their choice.
A few suggestions for data you should be searching for are (but are not limited to):

  • Compression, Tension, and Torsion
    • Various strain rates (i.e. 10-3 s-1, 10-1 s-1, and 103 s-1)
    • Various temperatures (i.e. 4140 steel tested at 293 K and 600 K)

You will then create a single page for the material you have chosen, and upload all of the data you have gathered to the created page. Please give a brief description of each figure as well as the reference from which the figure was obtained.

The following list of materials is first-come, first-serve. Once you have chosen your material place your "Student #" next to that material in the table.

Material Student # Material Student #
301 SS Student 7 316 SS Student 17
440 SS Dual Phase (DP) Steel Student 1
Transformation Induced Plasticity (TRIP) Steels Twinning Induced Plasticity (TWIP) Steels Student 5
HT9 RHA
AS41 ZE41 Student 9
AZ61 Student 3 ZE20 Student 3
HK31 HM21
Al 2024-T3 Student 10 Al 2024-T6 Student 2
Al 6063-T6 Al 7150-T7751 Student 4
Al 7475-T7351 Student 21 Nodular Cast Iron Student 6
White Cast Iron IF Steel
1010 Steel 3140 Steel Student 20
4130 Steel Student 11 4140 Steel Student 8
B-1900 Ni Student 12 Inconel 718 Student 15
Inconel 600 Student 14 MA 6000 Ni
CP-Ti Student 18 Ti-13V-11Cr-3Al
Ti-3Al-2.5V Ti-10V-2Fe-3Al

Contribution 4

Each student will add a fatigue-life curve for the material they have chosen in the previous contribution. If a fatigue-life curve does not exist for the material previously chosen then choose a second material for this contribution. You will upload this figure to the same page created for Contribution 3, and give a brief description of the figure. Include the reference from which you obtained this figure.

Contribution 5

Add a journal article that you have authored or co-authored to the site. Use the format demonstrated by Dr. Tschopp for completing this contribution.

If you have not authored or co-authored a journal article, contact Shane Brauer for an article that you can use.

ICME Slide/Lit Review

Along with the five (5) previous contributions you are to create a page that includes the slide pertaining to the ICME topic you chose and a summarized description of your literature review. This page should reflect any comments/criticism that you received for your slide as well as your literature review. Excellent examples are found here and here.

Student Contributions

Student 1

Contribution 1: Rigaku SmartLab X-ray Diffraction System Operating Manual

Contribution 2: Cross linking for ICME overview for Paddlefish Rostrum

                1. Add Category to Page - "Macroscale"
                2. Add Category to Page - "Mesoscale"
                3. Add Category to Page - "Microscale"
                4. Add Category to Page - "Nanoscale"
                5. Add Category to Page - "Electronic Scale"
                6. Add Category to Page - "Biomaterials"
                7. Cross Link - "electronic scale" to "Category:Electronic Scale"
                8. Cross Link - "atomistic scale" to "Category:Nanoscale"
                9. Cross Link - "microscale" to "Category:Microscale"
               10. Cross Link - "mesoscale" to "Category:Mesoscale"
               11. Cross Link - "macroscale" to "Category:Macroscale"
               12. Cross Link - "Dislocation Mobility" - Dislocation Mobility ICME page
               13. External Link - "Density Functional Theory" - wikipedia.org

Contribution 3: Dual Phase (DP) Steel: Stress-Strain data

Contribution 4: Dual Phase (DP) Steel: Fatigue Life data

Contribution 5: Journal Article: Three-point bending behavior of a ZEK100 Mg alloy at room temperature

ICME Slide/Literature Review: Multistage Modeling of Zn Coated Steel

Student 2

Claimed

Contribution 1: MTEX Tutorial

Contribution 2: Cross linking pages for Sheet Forming

                1. Cross Link - "aluminum" to "Category:Aluminum"
                2. Cross Link - "copper" to "Category:Copper"
                3. Cross Link - "steel" to "Category:Steel"
                4. Cross Link - "nickel" to "Category:Nickel"
                5. Cross Link - "titanium" to "Category:Titanium"
                6. Cross Link - "iron" to "Category:Iron"
                7. Cross Link - "304" to "304L SS alloy"
                8. External Link - 304 SS properties - matweb.com
                9. External Link - 316 SS properties - matweb.com
               10. External Link - 410 SS properties - matweb.com
               11. Cross Link - "1100-H14" to "SSC Aluminum: Al  1100 alloy"
               12. External Link - Al 1100-H14 properties - matweb.com
               13. External Link - Al 3003-H14 properties - matweb.com
               14. External Link - Al 5052-H32 properties - matweb.com
               15. Cross Link - "6061-T6" to " SSC Aluminum: Al 6061-T651 alloy"
               16. External Link - Al 6061-T6 properties - matweb.com
               17. External Link - "Curling(metalworking)" wikipedia.org
               18. External Link - "Decambering" wikipedia.org
               19. External Link - "Drawing (manufacturing)" wikipedia.org
               20. External Link - "Sheet Metal - Expanding" wikipedia.org
               21. External Link - "Incremental sheet forming" wikipedia.org
               22. External Link - "Sheet Metal - Press brake forming" wikipedia.org
               23. External Link - "Punching" wikipedia.org
               24. External Link - "Roll forming" wikipedia.org
               25. External Link - "Metal Spinning" wikipedia.org
               26. External Link - "Stamping (metalworking)" wikipedia.org


Contribution 3: Al 2024-T6 Stress-Strain Data

Contribution 4: 4130 Steel Fatigue Life Data

Contribution 5: Void Growth and Interaction Experiments

Contribution 6: A Multi-Length Scale Approach to Capturing the Effects of Shear Deformation for a Ductile Crystalline Material.

Student 3

Contribution 1: added polishing methods to the Equipment page

Contribution 2: Cross-linked Metals page to Equipment and Characterization to equipment

Contribution 3: ZE20: Stress-Strain data in Tension and Compression

Contribution 4: AZ61: Fatigue Life data

Contribution 5: Journal Article: Twin-like domains and fracture in deformed magnesium

ICME Slide/Literature Review: Multiscale Modeling of ZE20 Mg Extrusion Alloy

Student 4

Contribution 1: Helmholtz Energy Equations of State

Contribution 2: Added categories Script Electronic Scale LAMMPS to the following pages

AlMg.dump.meam

AlMg.in.meam

AlMg.library.meam

AlMg.log.lammps

AlMg.meam

Contribution 3: Al 7150-T7751 Stress-Strain Data

Contribution 4: Al 7150-T7751 Fatigue Life Data

Contribution 5: On the driving force for fatigue crack formation from inclusions and voids in a cast A356 aluminum alloy

ICME Slide/Literature Review: Multiscale Modeling of Pressure Vessel Failure

Student 5

Contribution 1: Phase Field Modeling

Contribution 2: Cross-link pages

  • MDDP Post Processing page: Added Category "Dislocation Dynamics", "MDDP", and "Microscale"
  • Mesoscale page: linked "Phase Field Modeling" to Phase Field Modeling page
  • Mesoscale page: Linked "FCC", "BCC", and "HCP" to their respective pages
  • Powder Metallurgy page: Added category "Metals"
  • Metals page: Added category "Material Models"
  • Material Models page: Linked Thermoplastics section to "Thermoplastic Models" page

Contribution 3: Stress-Strain Plot for TWIP steels

Contribution 4: Fatigue-life Plot for TWIP steels

Contribution 5: Void growth and coalescence in single crystal nickel

ICME Slide/Lit Review: ICME Overview of Tetragonal Zirconia Polycrystals (TZP)

Student 6

Contribution 1: LAMMPS reactive deformation of a single polyethylene chain

Contribution 2:

Contribution 3: Stress-strain data for Nodular Cast Iron

Contribution 4: Fatigue stress-life data for Nodular Cast Iron

Contribution 5: Geometric effects on stress wave propagation

ICME Slide/Literature Review: Multiscale Modeling of the Fracture Behavior in Semicrystaline Polymers

Student 7

Position Claimed

Contribution 1: Post-processing with Tecplot

Contribution 2: Categorized: MATLAB Basics , MATLAB Basics 2, MATLAB Import Data, MATLAB Export Data, Corrosion Behaviour of Extruded AM30 Magnesium Alloy

Contribution 3: Stress-strain data for 301 SS

Contribution 4: Fatigue stress-life data for 301 SS

Contribution 5: Journal Article: Modeling stress state dependent damage evolution in a cast Al-Si-Mg aluminum alloy

ICME Proposal: ICME overview of shear thickening fluids in body armor

Student 8

Contribution 1: Element deletion in Abaqus

Contribution 2: Cross-link/categorize pages

Contribution 3: Stress-strain data for 4140 Steel

Contribution 4: Fatigue-life curves for 4140 Steel

Contribution 5: Torsion/Simple Shear of Single Crystal Copper

ICME Topic Proposal: Modeling a projectile penetrating a steel plate

Student 9

Contribution 1
Preliminaries to Studying Non-Euclidean Geometry
Contribution 2
Contribution 3
Material Properties of ZE41 Magnesium Alloy#Stress-Strain_Data
Contribution 4
Material Properties of ZE41 Magnesium Alloy#Fatigue_Life_Data
Contribution 5
Stochastic uncertainty analysis of damage evolution computed through microstructure-property relations
Literature Review Report
Modeling the Orbital Evolution of the Moon-Earth System

Student 10

Contribution 1: Construction & Utilization of a Beowulf Cluster or a High-Performance Computing Cluster (HPCC) as we call them now. This is a little dated, from the early days of LINUX clusters. I helped bring the first cluster to Stennis Space Center in 2000. Moore's Law works for HPCCs. One compute node on the cluster we have today has more computing power than the entire 50 node cluster from 2000 (and the cost for nodes today is of the same order of magnitude as it was in 2000).

Contribution 2:

a) Added Category Aeroacoustics

b) Added Category Validation

c) Added External Link to Wikipedia Article on Aeroacoustics.

d) Added External Link to "NASA STANDARD FOR MODELS AND SIMULATIONS"

e) Linked categories Aluminum, Fatigue, Materials, and Metals to Aluminum 2024-T3 Stress-Strain and Fatigue Life Data

f) Linked categories Aeroacoustics, Validation, and Research Paper to Aero-Acoustic Analyses and Experimental Validation

g) Linked categories Steel, Fatigue, Materials, and Metals to AISI 4130 Steel

h) Linked categories Steel, Fatigue, Materials, and Metals to 316 Stainless Steel

i) Linked categories Aluminum, Materials, and Metals to Aluminum Extrusion

j) Linked categories Aluminum, Materials, and Metals to Aluminum Preparation

k) Linked categories Aluminum, Fatigue, Materials, and Metals to Al 7150-T7751 Fatigue Life Data

l) Linked categories Aluminum, Materials, and Metals to Al 7150-T7751 Stress-Strain Data

m) Linked categories Aluminum, Materials, and Metals to Al 2024-T6

n) Linked categories Biomaterials‏‎, Human Tissue Research, and Animal Tissue Research to Bio-inspired

o) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_1060-T0_alloy

p) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_1100_alloy

q) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_2024-T0_alloy

r) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_2024-T351_alloy

s) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_2024-T4_alloy

t) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_6061-T0_alloy

u) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_6061-T651_alloy

v) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_7039_alloy

w) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_7075-T0_alloy

x) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_7075-T651_alloy

y) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_7075-T6_alloy

z) Linked categories Aluminum, Materials, and Metals to SSC_Aluminum:_Al_99%_pure_alloy

Contribution 3: Aluminum 2024-T3 Stress-Strain Data

Contribution 4: Aluminum 2024-T3 Fatigue-Life Data

Contribution 5: Aero-Acoustic Analyses and Experimental Validation

Allgood, D.C., Woods, J.L., Graham, J.S., Langford, L.L., “Computational Analyses in Support of Sub-scale Diffuser Testing for the A-3 Facility – Part 3: Aero-Acoustic Analyses and Experimental Validation”, AIAA Joint Propulsion Conference, 2009.

ICME Topic Proposal: ICME Analysis of Fatigue Crack Growth through a Weld in SA-516 Grade 70 Plate

Student 11

Contribution 1: Computational Fluid Dynamics (CFD) simulation using Abaqus

Contribution 2: Cross-link/Categorize pages

Cross linking pages for Biomaterials

  • Biomaterials page: linked "nanoscale" from materials page to Nanoscale in Material Models page.
  • Biomaterials page: linked "macroscale" from materials page to Macroscale in Material Models page.
  • Biomaterials page: created an external link "velcro" from materials page to external link.
  • Biomaterials page: created an external link "burrs" from materials page to external link.

Contribution 3: Stress Strain data-4130 Steel

Contribution 4: Fatigue-life curve-4130 Steel

Contribution 5: Properties of Polystyrene and Polymethyl Methacrylate Copolymers of Polyhedral Oligomeric Silsesquioxanes: A Molecular Dynamics Study

ICME Slide/Literature Review: Bio-Inspired Energy Dissipation System

Student 12

Contribution 1: Created Page ICME_Pole_Figure_Plot_Function

Contribution 2: Cross-linked pages:

FCC_Runscript

LAMMPS_Stacking_Fault_Energy

created category Dislocation Dynamics and associated Code: microMegas and MDDP with it

Contribution 3 & 4: B-1900 Ni Superalloy

Contribution 5: Microstructure and damage evolution during tensile loading in a wrought magnesium alloy

ICME Slide/Literature Review: Multiscale modeling of armor fragmentation due to the impact of an explosively formed projectile

Student 13

Contribution 1:

Contribution 2: added Category:Stress Strain Curves: Titanium

cross-linked:

Contribution 3:

Contribution 4:

Contribution 5:

Student 14

Contribution 1: add page or pages

Contribution 2:

  • Crosslinked: "A Mechanistic Study for Strain Rate Sensitivity of Rabbit Patellar Tendon" to: Animal Tissue Research, Research Paper and Biomaterials.
  • Crosslinked: "LAMMPS Interstitial Formation Energy" to: LAMMPS, Tutorial, Metals.
  • Crosslinked: "Finite Element Modeling of Strain Rate Experiment for Soft Biological Materials" to: Biomaterials, ABAQUS, Internal State Variable
  • Crosslinked:

Contribution 3:

Contribution 4:

Contribution 5: Journal Article

Student 15

Contribution 1:

Contribution 2:

Contribution 3: Inconel 718 Stress-Strain Data

Contribution 4: Inconel 718 Fatigue Life Curve

Contribution 5: Cyclic plasticity at pores and inclusions in cast Al-Si alloys

Inconel 718 chemical and mechanical properties

Student 16

Student 17

Contribution 1: Muffle Furnaces

Contribution 2: Cross-linking
Linked MSF, Material Models to 4. Fatigue Tests and Predictions of the Shock Tower
Linked Overview to About EVOCD
Linked Research Paper to Adsola
Linked Tutorial, Experiments to Aluminum Preparation
Linked Tungsten, Metals, Materials to Bcc
Linked LAMMPS, Nanoscale to Code: GTA
Linked LAMMPS to Code: LAMMPS history
Linked Research Paper, Silicon, Aluminum, ICME Class to Research Paper
Linked Steel, Metals, Materials, ICME Class to ICME approach to develop 3rd Generation of Advanced High Strength Steel
Linked Magnesium, Tutorial, Experiments, Metals, Materials to Magnesium Preparation
Linked Steel, Tutorial, Experiments, Metals, Materials to Steel Preparation
Linked Tutorial, Experiments, Metals, Materials, Equipment, ICME Class to Muffle Furnaces

Contribution 3: Stress-Strain Data for 316 SS

Contribution 4: Fatigue life curves for 316 SS

Contribution 5: Research Paper

ICME Slide/Lit Review

Student 18

Student 19

Student 20

Student 21

Contribution 1: Add something in your area of expertise

Contribution 2

Contribution 3

Contribution 4

Contribution 5: Lattice Orientation Effects on Void Growth and Coalescence in FCC Single Crystals

ICME Slide/Lit Review

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