Originally posted by: f95toli
Silverpig: Yes, but the problem here is that classical thermodynamics doesn't work very well for real systems when the temperature approaches zero since phenomena like Bose-Einstein condensation etc becomes important; a full quantum mechanical description is therefore needed and classical thermodynamics breaks down.
Trivia: The international temperature scale (ITS-90) is only defined above 0.7K, hence strictly speaking "temperature" is not defined for temperatures lower than that.
Good to know. I really know very little (read: just about nothing) about very low 'temperature' systems, as I tend to dwell in the 37°C range with everything I'm doing right now. My background in quantum anything is limited to a single course taken about 5 years ago.Originally posted by: f95toli
Cyclowizard: Temperature is a statistical property, in thermometry it is generally just "defined" as part of the exponent in the distribution function, i.e. exp(-U/kT) where k s Boltzmanns constant (at low temperatures the Fermi- or Bose-Einstein distributions must be used but the same exponent appears there).
This works even when measuring the temperature using electronic sensors (i.e. silicon diodes) since these Fermi distribution determine the number of excitations in the conductions band and therefore the resistance of the diode.
In a fully quantum mechanical treatment of a system "temperature" often enters as a "thermal bath", an ensemble of harmonic oscillators with a disitribution of energy that follows the Bose-Einstein distribution at a temperature T.
As I have already pointed out, in the case of low temperatures (e.g. laser cooling) the concept of temperature becomes ill-defined but can still be used as a measure of the kinetic energy or more generally the amount of noise in the system, the latter is not always directly related to the thermal noise. I.e. the temperature measured by an wide bandwith electronic sensor is quite often the thermal temperature plus the electrical noise in system. This is a VERY important point which is often overlooked even by many scientists, I have seen examples of experiments where they have claimed that the temperature was e.g. 50 mK (the temperature of the fridge) but the where the real ("relevant") temperature was in reality much higher, in some cases several Kelvin which has a significant effect on the experiments.
Also, it is interesting to note that "noise temperature" is often used as a measure of the the noise properties of e.g. amplifiers and quite often this is LOWER than the thermal noise, you can e.g. buy microwave amlifiers that have noise temperature of 4K when operated at a temperature of 15K. The reason why this is possible if of course that they have a limited bandwidth (thermal noise is "white", meaning the bandwith is infinite).
Hence, the word "temperature" can be used in many different ways and it is only at relatively hight temperatures that these uses coincide so some extent.
Originally posted by: gsellis
Assuming Big Bang, I say about 30billion light years past the edge of the universe might be absolute zero. It would be completely void of any matter or energy. In theory of course.
errrr... I meant the expanding part from the bang. So yeppersOriginally posted by: andrewbabcock
Originally posted by: gsellis
Assuming Big Bang, I say about 30billion light years past the edge of the universe might be absolute zero. It would be completely void of any matter or energy. In theory of course.
The edge of the universe? There isn't one...The universe is infinitely large...
Originally posted by: andrewbabcock
Originally posted by: gsellis
Assuming Big Bang, I say about 30billion light years past the edge of the universe might be absolute zero. It would be completely void of any matter or energy. In theory of course.
The edge of the universe? There isn't one...The universe is infinitely large...
Originally posted by: gsellis
I say about 30billion light years past the edge of the universe
Originally posted by: superHARD
Stupid person injection
Isn't there lots we don't know for sure?...what if black holes suck everything from close by objects?...even sucking away all heat?
Don't belittle me too much please...
Originally posted by: bsobel
Originally posted by: superHARD
Stupid person injection
Isn't there lots we don't know for sure?...what if black holes suck everything from close by objects?...even sucking away all heat?
Don't belittle me too much please...
Black holes generate alot of radiation, they are a source of heat, they do not remove it.