A thin piece of gold reached 33,740 degrees Fahrenheit, which is more than 14 times higher than its melting point, by being rapidly heated—and it didn't melt
it lasted as solid at a certain temperature for a certain length of time after it had reached that temperature.
That’s the problem, reading the quotes from my top reply even they seem to admit that what they are calling temperature is not what is usually called temperature in thermal equilibrium.
High temperature/energy leads to entropy/liquification, but I think what this experiment demonstrated is there’s a short delay or “entropy build up curve” between high amounts of energy and the “transmission” of entropy through the solid molecular structure to a liquid state.
That’s the problem, reading the quotes from my top reply even they seem to admit that what they are calling temperature is not what is usually called temperature in thermal equilibrium.
It’s a subtle distinction.
High temperature/energy leads to entropy/liquification, but I think what this experiment demonstrated is there’s a short delay or “entropy build up curve” between high amounts of energy and the “transmission” of entropy through the solid molecular structure to a liquid state.
I’m not sure if I’m wording all this correctly.