Thanks all... looks like the 2800 degree temps recorded in the DEA choppers was dealt with long ago. So now I return to a simple question one person has answered and I just want more validation for: IS IT TRUE THAT 4500 DEGREE THERMATE TEMPERATURES WOULD BREAK DOWN THE Fe-O-S CHEMICAL STRUCTURE ENTIRELY, AS I THINK SOMEONE ELSE ON THIS THREAD ASSERTED?
This is fun.
Oh, for my part, sorry Chris. I haven't read
all the posts in this thread; some days I only get to look at the last few posts in a thread and end up missing quite a bit.
I need to brush up on the argument regarding iron oxide/iron sulfide/pure iron structures, so I actually can't speak directly to your point right now. I'm working at the edge of my knowledge anyway, so hopefully someone who knows about that stuff better will save me the effort
. But anyway, I
have been one of the folks talking about thermite temps obliterating microstructures. While including the eutectic structures, I was also referring to something else as well. Biederman, Sullivan, Vander Voort, and Sisson wrote the following in their paper "
Microstructural Analysis Of The Steels From Buildings 7, & 1 or 2 From The World Trade Center":
The as-fabricated microstructure consisted of a hot worked banded structure of ferrite and pearlite. In severely “eroded” regions where the thickness had been reduced to less than a 1/16 of and inch significant decarburation was observed. In addition, some pearlite bands presented regions that had re-austentized as well as regions where the pearlite had started to spheroidize. These observations indicate that steel had experienced temperature between 550 and 850°C.
That's important. Even though it's not speaking towards the eutectic formations at all, it's important. What that statement is referencing are the specific phases of the carbon steel that those Worcester researchers observed. It's an important point because it gives an upper end on what temperatures were experienced right at the point of erosion. As background, take a peek at this carbon phase diagram:
The important thing to take away from this diagram is the fact that for certain percentages of carbon content, certain
"phases" of steel only are formed within certain temperature ranges. As the paper's authors stated, the phases they saw indicated a high of around 850
oC.
That's well below what thermite reacts at.
What would've happened if it had gone
above 850 degrees? I need to get a definitive answer from any metallurgists present (Hi, Sunstealer!
). But what I take from the other Worcester paper - "
Metal Removal via Slag Attack of the Steel from Building 7 of the World Trade Center — Some Observations" - is that the microstructures would been different. How exactly they would've been different, I'm just don't know (that's why I need a metallurgist to educate me on this) but I think I got a hint of it in that "
phases of steel" link I gave above: If you scroll to near the end, you'll see that they give pictures of grain structure formation based on temperature excursion. Or in plain english: The first diagram is what you'll see when the steel experiences temperatures below a certain point, the second picture is when it sees a higher temp, and so on. The lesson here is that a higher peak temperature results in a different grain structure when things cool off. I don't know what specific structures relate to what specific temperature ranges, but I
do know what ranges the WPI papers give. It's there for all to see: The steel itself hit around 850
oC, and the "slag" material on top that contributed to the erosion may have gotten as high as 1100
oC. Either way, both figures are way below thermite's reaction temperature.
I'll look up the other half of the argument - the obliteration of the iron sulfide/iron oxide structures in a bit. I believe it's as simple as the fact that you shouldn't see FeS/FeO/Fe intermixed like it was had the temperatures been high enough to melt
all of those. Instead, you would've had distinct "pools" or hardened pigs/pools/drops/whatever of pure Fe and some remaining powders of FeS and FeO lying about because they all would've separated when they all became molten. I think. I'm not positive. Again, I defer to any metallurgists and chemists reading this; please correct me if I've gotten anything wrong here. But that's how I'm remembering the argument.
