Metallurgy Guru: Sustainable Metallurgy and Green Metals - A Green Metallurgy Introduction
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- čas přidán 9. 06. 2020
- This is an introductory class about sustainable metals and metallurgy, a field that is also referred to as green metallurgy.
Engineering materials and particularly metallic alloys have enabled technological progress over millenia.
Metallic materials have a historic and enduring importance in our society. They have paved the path of human civilization with load-bearing applications that can be used under the harshest environmental conditions, from the Bronze Age onwards. Only metallic materials encompass such diverse features as strength, hardness, workability, damage tolerance, joinability, ductility and toughness, often combined with functional properties such as corrosion resistance, thermal and electric conductivity and magnetism.
The high and accelerating demand for load-bearing (structural) and functional metallic alloys in key sectors such as energy, construction, safety and transportation is resulting in predicted production growth rates of up to 200 per cent until 2050. Yet most of these metallic materials, specifically steel, aluminium, nickel and titanium, require a lot of energy when extracted and manufactured and these processes emit large amounts of greenhouse gases and pollution.
The huge success of metallic products and industries also means that they has an important role in addressing the current environmental crisis.
The availability of metals (most of the elements used in structural alloys are among the most abundant), efficient mass producibility, low price and amenability to large-scale industrial production (from extraction to the metal alloy) and manufacturing (downstream operations after solidification) have become a substantial environmental burden: worldwide production of metals leads to a total energy consumption of about 53 exajoules (10^18 J) (8% of the global energy used) and almost 30% of industrial CO2-equivalent emissions (4.4 gigatons of carbon dioxide equivalent, Gt CO2eq) when counting only steels and aluminium alloys (the largest fraction of metal use by volume)
This lecture gives an introductory overview of methods for improving the direct sustainability of structural metals, in areas including reduced-carbon-dioxide primary production, recycling, scrap-compatible alloy design, contaminant tolerance of alloys and improved alloy longevity, for instance throgh better corrosion resistance. The lecture also discusses the effectiveness and technological readiness of individual measures and also show how novel structural materials enable improved energy efficiency through their reduced mass, higher thermal stability and better mechanical properties than currently available alloys. - Věda a technologie
A hidden gem! Thank you so much for sharing it on youtube.
Thanks Prof. Raabe. Enjoyed it!
Well, can't say I like the robotic delivery, but at least you did explain it, and you pronounced "metallurgy" right, so I give props for that.
Professor, I think you're going to be incredible when you grow up.
Nice to see you on CZcams Prof. Raabe, looking forward to see the lecture series.
Thank you for taking the time ill definitely add this information to my notes.
Vital information, just the beginning of a major shift in energy management.
Looking forward to the next lectures in this series!
Thanks Prof. Raabe, this is very cool and inspiring!
Some structure, such as table of contents and division into chapters/sections would be helpful. One gets lost pretty quickly tbh.
Thanks Prof. Raabe! It's really nice and helpful lecture!
Amazing video. Very insightful. Thanks a lot for your efforts and this initiative, Prof. Raabe :)
Great initiative Prof. Raabe. Very timely. You and me seem to be following the same metallurgical interest journey :D
Danke für die Vorlesung. ich finde das Thema auch sehr wichtig und aktuell. Ich und meine Arbeitskollegen müssen die Nachhaltigkeitskriterien in jedes Projekt einbauen. Leider ist es noch nicht immer so.
Nice initiative Professor!!
Prof. Raabe, when is the next lecture scheduled to be out? Thanks!
Let's face it. The massive amounts of carbon steel used to make wind turbines can only be made with coal!