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Thom Cochell
United States
Приєднався 12 бер 2020
MSE 201 S21 Lecture 39 - Module 4 - Precipitation Hardening, Revisited
MSE 201 S21 Lecture 39 - Module 4 - Precipitation Hardening, Revisited
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Відео
MSE 201 S21 Lecture 39 - Module 2 - Properties of Steel Microstructures
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MSE 201 S21 Lecture 39 - Module 2 - Properties of Steel Microstructures
MSE 201 S21 Lecture 39 - Module 5 - Precipitation Hardening Example
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MSE 201 S21 Lecture 39 - Module 5 - Precipitation Hardening Example
MSE 201 S21 Lecture 39 - Module 3 - Properties of Steel Microstructures Example
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MSE 201 S21 Lecture 39 - Module 3 - Properties of Steel Microstructures Example
MSE 201 S21 Lecture 39 - Module 1 - Continuous-Cooling Example
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MSE 201 S21 Lecture 39 - Module 1 - Continuous-Cooling Example
MSE 201 S21 Lecture 38 - Module 3 - Continuous-Cooling Diagrams
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MSE 201 S21 Lecture 38 - Module 3 - Continuous-Cooling Diagrams
MSE 201 S21 Lecture 38 - Module 2 - Isothermal Transformation Example
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MSE 201 S21 Lecture 38 - Module 2 - Isothermal Transformation Example
MSE 201 S21 Lecture 38 - Module 1 - Isothermal Transformation Diagrams
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MSE 201 S21 Lecture 38 - Module 1 - Isothermal Transformation Diagrams
MSE 201 S21 Lecture 37 - Module 2 - Nucleation Example
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MSE 201 S21 Lecture 37 - Module 2 - Nucleation Example
MSE 201 S21 Lecture 37 - Module 4 - Avrami Curves
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MSE 201 S21 Lecture 37 - Module 4 - Avrami Curves
MSE 201 S21 Lecture 37 - Module 3 - Transformation Rate
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MSE 201 S21 Lecture 37 - Module 3 - Transformation Rate
MSE 201 S21 Lecture 37 - Module 1 - Free Energy of Nucleation
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MSE 201 S21 Lecture 37 - Module 1 - Free Energy of Nucleation
MSE 201 S21 Lecture 36 - Module 3 - Steel Phase Diagram Example
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MSE 201 S21 Lecture 36 - Module 3 - Steel Phase Diagram Example
MSE 201 S21 Lecture 36 - Module 4 - Supercooling
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MSE 201 S21 Lecture 36 - Module 4 - Supercooling
MSE 201 S21 Lecture 36 - Module 1 - Iron-Carbon System
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Look's at the iron-iron carbide (cementite) phase diagram.
MSE 201 S21 Lecture 36 - Module 2 - Hypo- & Hyper-eutectoid Steel
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MSE 201 S21 Lecture 36 - Module 2 - Hypo- & Hyper-eutectoid Steel
MSE 201 S21 Lecture 35 - Module 2 - Gibbs Phase Rule
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MSE 201 S21 Lecture 35 - Module 2 - Gibbs Phase Rule
MSE 201 S21 Lecture 35 - Module 3 - Gibbs Phase Rule Example
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MSE 201 S21 Lecture 35 - Module 3 - Gibbs Phase Rule Example
MSE 201 S21 Lecture 35 - Module 1 - Intermediate Phases & Reactions
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MSE 201 S21 Lecture 35 - Module 1 - Intermediate Phases & Reactions
MSE 201 S21 Lecture 35 - Module 5 - Labeling Phase Fields Example
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MSE 201 S21 Lecture 35 - Module 5 - Labeling Phase Fields Example
MSE 201 S21 Lecture 35 - Module 4 - Labeling Phase Fields
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MSE 201 S21 Lecture 35 - Module 4 - Labeling Phase Fields
MSE 201 S21 Lecture 34 - Module 3 - Eutectic Examples
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MSE 201 S21 Lecture 34 - Module 3 - Eutectic Examples
MSE 201 S21 Lecture 34 - Module 2 - Binary Eutectic Phase Diagrams Part 2
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MSE 201 S21 Lecture 34 - Module 2 - Binary Eutectic Phase Diagrams Part 2
MSE 201 S21 Lecture 34 - Module 1 - Binary Eutectic Phase Diagrams Part 1
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MSE 201 S21 Lecture 34 - Module 1 - Binary Eutectic Phase Diagrams Part 1
MSE 201 S21 Lecture 33 - Module 4 - Lever Rule Example
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MSE 201 S21 Lecture 33 - Module 4 - Lever Rule Example
MSE 201 S21 Lecture 33 - Module 3 - Lever Rule
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MSE 201 S21 Lecture 33 - Module 3 - Lever Rule
MSE 201 S21 Lecture 33 - Module 2 - Phases Present & Composition Example
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MSE 201 S21 Lecture 33 - Module 2 - Phases Present & Composition Example
MSE 201 S21 Lecture 33 - Module 5 - Equilibrium vs. Rapid Cooling
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MSE 201 S21 Lecture 33 - Module 5 - Equilibrium vs. Rapid Cooling
MSE 201 S21 Lecture 32 - Module 2 - What is a Phase?
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MSE 201 S21 Lecture 32 - Module 2 - What is a Phase?
MSE 201 S21 Lecture 33 - Module 1 - Phases Present & Composition
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MSE 201 S21 Lecture 33 - Module 1 - Phases Present & Composition
Hey Thom thanks for the tutorial. I have a question tho. What happens if the selected point is on the liquidus line(not above)? Does it still have the weight fraction of %100 liquid?or both phases are present (L+alpha(solid))
Sehr schon
which software you have used in this video pls
Best video 🙏🏻❤️
Great video. Thanks
there is something wrong... PD defn, no of atoms / area of the plane.. you mistakenly calculated area occupied by the atoms in the numerator.
Tolong dikasih terjemhan bahasa indonesia pak
This is a problem in my materials homework. Thanks you so much!!!
thx for saving my life
You're channel is a life saver 🙏
Thank you ❤
Dont you need to do baseline correction for the entire graph and normalize the graph to the weight of the sample. Also is there an option to convert watts to Joules
great work! do you have any example how to extract true stresses for the material type plastic (blue curve). It seems true stress calculation for those materials is not as same as conventional ductile materials and needs indeed further cares. any feedback will be great.
Why didn't we take also cold crystalliztion enthalpy into account while calculating crystallinity?
Great video!!!
Great 👍
thank you so much
Your teaching is so goood sir🎉🎉
short and sweet explanation. Thank you so much
why are your hands blue
Thank you so much for this video!
Very helpful thanks
11:00 ... the dislocation line motion in a screw dislocation is perpendicular to the shear force direction
Thanks a lot !!
great explanation
activation free energy decreases with increasing supercooling*******.
@Thom Cochell . Thank you for your great explanation on thermal transitions. Is there any references for polypropylene material with transition times?
Wow, short video & much Info Thanks Thom♥
well-understood-thank-you
Thank You!!
It took me so long to get to fully understand this concept. And I wouldn't be able to do it without your help. Thanks for making these videos. They were extraordinarily easy to follow but still the contents are solid. It has been really frustrating nowadays trying to apply the fundamental concept to the other cases even after reading lecture notes and textbooks over and over. Thanks to your video I was able to make my own explanation that makes sense and connects together in my head finally. Unlike the other days that I just judge myself that I'm not really efficient in learning compare to others, I've focused on learning this time. I've learned that I shouldn't limit the study materials when we are living in such a high-tech world to help our understandings.
Everything makes sense now. I've known about it way too partially. It was a really helpful video.
wow video
nice video
All great videos, but there’s so many. Do you have any other videos on grain size determination?
Precisely what I was looking for! Thank you the golden information❤️👏.
Thanks for clarifying 😌
Thank you dude
thank you much! really clear explanantion
for t i think u made a mistake
Wonderful
Thank you from Bangladesh
Awesome overview of resolved shear stress. Helped a lot!
Dear sir, I like your explanation. Is there any calculation based on the unit cell size (d), how the minimum scan step(/rate) should depend. Or can we determine the time to complete the whole experiment beforehand. I want to identify the time required for a mixed sample of Li2O, Al2O3, SiO2, SiC. Is it possible to identify the min step size so that peaks of all crystal formed at high temperature can be measured. Thank you!
Why is ruby listed as being made of mostly silicon oxide? I thought that was mostly aluminum oxide?
Thank you so much, hope this is on my exam tmr 😎
Thank you so much! It was very helpful
How do i predict the coordination for LaAlO3
Are the voids within the structure amorphous regions?
I ran into the same problem, for a copper dumbbell I'm getting a young's modulus of 11 GPa, which is nowhere near the (120 GPa) I found online. I got a column labelled "overall extension", I don't see what went wrong :(
Yeah and my dataset doesnt have that extra 'tensile strain' column either, idk what to do