Thank you so much for these important informations Professor Spark and Professor Falkowski. I hope one day I can be your student at University of Utah 😊
Excelent! Its necessary more content like this in social media. Im a materials engineer and this is excelent for excercising my english lol. Love it! Thanks
Great podcast! I'd love to see my thermodynamics professor on a podcast like this. He has such a deep understanding of thermodynamics so much that he relates thermodynamics to the dynamics of politics.
@@TaylorSparks Dr. Guna Selvaduray from San Jose State University in California. Once you get him started on Thermodynamics it makes for a great conversation.
great job guys! lots to think about there - iron and steel innovations really big part of history complete with drama Bessemer Mushet Kelly and open hearth furnaces - thanks again
People who like this will probably also enjoy “Jernets Danmarkshistorie” (History of Denmark of the Iron - it works better in Danish) by Vagn Fabritius Buchwald. It’s in Danish so there are about 20 million people who can read it.
Seems like he’s not a fan of microalloying. He heard niobium and basically said “LISTEN bro I told you IM NOT GAY!” None of that fancy molybdenum carbide chromium nitride get outta hear. Nah fr very enlightening. I would’ve like to learn more about how cold rolling and hot rolling create different properties. Also, this swings into the microalloy part but pushing the boundary between steels and carbides welded into an iron matrix, where that line is on something like T15, where there’s less than 65%, what the future is with these types of highly refined particle metals using hot isostatic pressing of powdered metal to produce martensitic steels with remarkable wear resistance and toughness that greatly exceeds what would be possible. How grain refinement works as well. What role different elements have in grain growth, he covered part of it. Also these matrix steels that deliberately keep the alloying components forming carbides, but improving the hardness and strength of the matrix. Way off topic but i would love to hear from him or maybe someone closer to the topic but what advances are being made on improving the process for making amorphous random packed steel glass. Now that it’s fairly common knowledge now and demand for it will surge. How metals can be in a completely molten state and be cooled too quickly for crystallization to occur. The TTT of this process and how it can be optimized. Also would like to hear more about failure modes. How and why steel fails. And unusual alloying elements like hafnium, tantalum, zirconium, yttrium, scandium. I mean if I could I would personally make some ingots and find out but I’m not really set up for that at the moment.
Thank you so much for these important informations Professor Spark and Professor Falkowski. I hope one day I can be your student at University of Utah 😊
I hope you'll apply
As a materials science engineer i seem to have struck gold here.
👊🏻 you know it! We have over thirty episodes to enjoy so far!
that is what I think, too
Excelent! Its necessary more content like this in social media. Im a materials engineer and this is excelent for excercising my english lol. Love it! Thanks
Gracias che! Es un placer :)
Yes great and thank you
Great podcast! I'd love to see my thermodynamics professor on a podcast like this. He has such a deep understanding of thermodynamics so much that he relates thermodynamics to the dynamics of politics.
Really?? Who is he?
@@TaylorSparks Dr. Guna Selvaduray from San Jose State University in California. Once you get him started on Thermodynamics it makes for a great conversation.
awsome. Learning English and materials with us.
Thanks for listening! 👊🏻
great job guys! lots to think about there - iron and steel innovations really big part of history complete with drama Bessemer Mushet Kelly and open hearth furnaces - thanks again
Glad you enjoyed it!
I never thought that something like this could exist ,and im glad that it does
@@kyu-qx1ew Happy to provide a great resource, I hope
This seems pretty sweet as someone who's prepping to apply for MSE PhD.
Steel is the origin of our field, anyways
@@krishnajayaswal6051 Good luck with your PhD. This was our very first episode. We have now done 93! Enjoy listening through the catalog :)
Nice podcast and very interesting topic. It helps for excerising english listening in materials fields, I will recommend to my students too...
Epic podcast
@@bobbobby1576 💪🏻💪🏻💪🏻
Looks interesting!
Give it a listen! Steel has a fascinating backstory.
Hey there Professor Sparks,
Where can I get the show notes from?
video description ;)
People who like this will probably also enjoy “Jernets Danmarkshistorie” (History of Denmark of the Iron - it works better in Danish) by Vagn Fabritius Buchwald. It’s in Danish so there are about 20 million people who can read it.
@@peterfireflylund thanks for sharing. Any particular reason you think it's good?
Why has the algorithm waited 4 years to show me this
@@aedanmckee8698 right??? It really took off on this episode.
really liked the first episode!
the thing about iron having lower density in solid state seems to be wrong though :/
Crazy right!? It's true
Seems like he’s not a fan of microalloying. He heard niobium and basically said “LISTEN bro I told you IM NOT GAY!” None of that fancy molybdenum carbide chromium nitride get outta hear. Nah fr very enlightening. I would’ve like to learn more about how cold rolling and hot rolling create different properties. Also, this swings into the microalloy part but pushing the boundary between steels and carbides welded into an iron matrix, where that line is on something like T15, where there’s less than 65%, what the future is with these types of highly refined particle metals using hot isostatic pressing of powdered metal to produce martensitic steels with remarkable wear resistance and toughness that greatly exceeds what would be possible. How grain refinement works as well. What role different elements have in grain growth, he covered part of it. Also these matrix steels that deliberately keep the alloying components forming carbides, but improving the hardness and strength of the matrix. Way off topic but i would love to hear from him or maybe someone closer to the topic but what advances are being made on improving the process for making amorphous random packed steel glass. Now that it’s fairly common knowledge now and demand for it will surge. How metals can be in a completely molten state and be cooled too quickly for crystallization to occur. The TTT of this process and how it can be optimized.
Also would like to hear more about failure modes. How and why steel fails.
And unusual alloying elements like hafnium, tantalum, zirconium, yttrium, scandium. I mean if I could I would personally make some ingots and find out but I’m not really set up for that at the moment.