In experimental physics, researchers have proposed non-extensive self-consistent thermodynamic theory to describe phenomena observed in the Large Hadron Collider (LHC). This theory investigates a fireball for high-energy particle collisions, while using Tsallis non-extensive thermodynamics. Fireballs lead to the bootstrap idea, or self-consistency principle, just as in the Boltzmann statistics used by Rolf Hagedorn. Assuming the distribution function gets variations, due to possible symmetrical change, Abdel Nasser Tawfik applied the non-extensive concepts of high-energy particle production.
The motivation to use the non-extensive statistics from Tsallis[1] comes from the results obtained by Bediaga et al.[2] They showed that with the substitution of the Boltzmann factor in Hagedorn's theory by the q-exponential function, it was possible to recover good agreement between calculation and experiment, even at energies as high as those achieved at the LHC, with q>1.
The starting point of the theory is entropy for a non-extensive quantum gas of bosons and fermions, as proposed by Conroy, Miller and Plastino, which is given by
Sq=S
| FD | |
| q |
| BE | |
| +S | |
| q |
| FD | |
| S | |
| q |
| BE | |
| S | |
| q |
That group and also Clemens and Worku, the entropy just defined leads to occupation number formulas that reduce to Bediaga's. C. Beck, shows the power-like tails present in the distributions found in high energy physics experiments.
Using the entropy defined above, the partition function results are
ln[1+Zq(V
|
| infty | |
| \sum | |
| n=1 |
| 1 | |
| n |
| infty | |
| \int | |
| 0 |
dm
| infty | |
| \int | |
| 0 |
dpp2\rho(n;m)[1+(q-1)\beta\sqrt{p2+m2}]
| ||||
.
q>1
Another way to write the non-extensive partition function for a fireball is
Zq(Vo,T)=\int
| infty | |
| 0 |
\sigma(E)[1+(q-1)\beta
| ||||
| E] |
dE,
\sigma(E)
Self-consistency implies that both forms of partition functions must be asymptotically equivalent and that the mass spectrum and the density of states must be related to each other by
log[\rho(m)]=log[\sigma(E)]
m,E
The self-consistency can be asymptotically achieved by choosing[3]
m3/2\rho(m)=
| \gamma | |
| m |
[1+(qo-1)\betao
| |||||
| m] | = |
| \gamma | |
| m |
[1+(q'o-1)
| ||||
| m] |
| ||||
| \sigma(E)=bE | ||||
| o-1)E] |
,
\gamma
q'o-1=\betao(qo-1)
a,b,\gamma
q' → 1
With the mass spectrum and density of states given above, the asymptotic form of the partition function is
Zq(Vo,T) → (
| 1 | |
| \beta-\betao |
)\alpha
| \alpha= | \gammaVo |
| 2\pi2\beta3/2 |
,
| a+1=\alpha= | \gammaVo |
| 2\pi2\beta3/2 |
.
One immediate consequence of the expression for the partition function is the existence of a limiting temperature
To=1/\betao
The connection between Hagedorn's theory and Tsallis statistics has been established through the concept of thermofractals, where it is shown that non extensivity can emerge from a fractal structure. This result is interesting because Hagedorn's definition of fireball characterizes it as a fractal.
Experimental evidence of the existence of a limiting temperature and of a limiting entropic index can be found in J. Cleymans and collaborators,[5] [6] and by I. Sena and A. Deppman.[7] [8]