Understanding the Role of Aluminum in High Temperature Super Alloys

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The discussion centers on the metallurgy of nickel (Ni) and aluminum (Al) alloys, particularly how adding aluminum to nickel increases its melting point and enhances other properties. The peak melting temperature occurs at a 50-50 mole mixture of Ni and Al, resulting in a compound known as NiAl, which has a higher melting point than pure nickel despite aluminum's low melting point. This phenomenon is linked to the formation of intermetallic compounds and the complexities of phase changes during solidification. The conversation also touches on the significance of superalloys in metallurgy, referencing conferences organized by The Metallurgical Society (TMS) and the recent passing of key figure Ed Loria. The challenges of producing these alloys, such as the need for rapid solidification and hot pressing, are acknowledged, prompting further inquiry into the subject.
Pkruse
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Is anyone interested in starting a discussion on this topic? I use them in designs, but don't understand the metallurgy very well.

In particular, how does adding Al to Ni increase the melting point of Ni? It also improves a number of other desirable characteristics. The peak of the melting temperature curve on the phase diagram is at a 50-50 mixture. (Counting moles, not weight.) The resulting mixture is half aluminum, which we who work with refractory metals call "butter" due to its incredibly low melting point; yet the melting point of this mixture is much higher than pure Ni.
 
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Pkruse said:
Is anyone interested in starting a discussion on this topic? I use them in designs, but don't understand the metallurgy very well.

In particular, how does adding Al to Ni increase the melting point of Ni? It also improves a number of other desirable characteristics. The peak of the melting temperature curve on the phase diagram is at a 50-50 mixture. (Counting moles, not weight.) The resulting mixture is half aluminum, which we who work with refractory metals call "butter" due to its incredibly low melting point; yet the melting point of this mixture is much higher than pure Ni.
Superalloys is an extraordinarily interesting topic, and in fact TMS (The Metallurgical Society) has hosted a conference Superalloys on a three year period. One of the key editors of the series, Ed Loria, passed away recently (https://www.physicsforums.com/showthread.php?t=402572).

TMS Superalloys Archive - http://knowledge.tms.org/superalloys.aspx

See also - http://www.tms.org/meetings/specialty/superalloys2000/superalloyshistory.html

The high melting point can be attributed to NiAl, an intermetallic compound.

See the Ni-Al phase diagram here - http://www.ias.ac.in/sadhana/Pdf2003Apr/Pe1064.pdf

The challenge is that there are several different phases that can form during the freezing of a melt, so one possibility is to produce a rapid solidified powder, which then must be hot pressed.
 
Thanks, Joe. Now I have to go do some studying before I can ask further questions.
 

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