Difference between revisions of "Thermodynamical Properties of Elementary Particles"
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Revision as of 11:03, 16 October 2012
This text is collapsible. Template:Lorem
In the mid-forties G.A. Gamov proposed the idea
of the "hot" origin of the World. Therefore thermodynamics
was introduced into cosmology, and nuclear physics too.
Before him the science of the evolution of Universe
contained only dynamics and geometry of the World.
A.D.Chernin.
Particles | Mass | Number of states | $g$ (particles and anti-particles) | |
---|---|---|---|---|
spin | color | |||
Photon ($\gamma$) | 0 | 2 | 1 | 2 |
$W^+,W^-$ | $80.4\, GeV$ | 3 | 1 | 6 |
$Z$ | $91.2\,GeV$ | 3 | 1 | 3 |
Gluon ($g$) | 0 | 2 | 8 | 16 |
Higgs boson | $>114\, GeV$ | 1 | 1 | 1 |
Bosons | 28 | |||
$u,/,\bar{u}$ | $3\, MeV$ | 2 | 3 | 12 |
$d,/,\bar{d}$ | $6\, MeV$ | 2 | 3 | 12 |
$s,/,\bar{s}$ | $100\,MeV$ | 2 | 3 | 12 |
$c,/,\bar{c}$ | $1.2\,GeV$ | 2 | 3 | 12 |
$b,/,\bar{b}$ | $4.2\, GeV$ | 2 | 3 | 12 |
$t,/,\bar{t}$ | $175\,GeV$ | 2 | 3 | 12 |
$e^+,\,e^-$ | $0.511\, MeV $ | 2 | 1 | 4 |
$\mu^+,\,\mu^-$ | $105.7\,MeV$ | 2 | 1 | 4 |
$\tau^+,\,\tau^-$ | $1.777\, GeV$ | 2 | 1 | 4 |
$\nu_e,\,\bar{\nu_e}$ | $<3\,eV$ | 1 | 1 | 2 |
$\nu_\mu,\,\bar{\nu_\mu}$ | $<0.19\,MeV $ | 1 | 1 | 2 |
$\nu_\tau,\,\bar{\nu_\tau}$ | $<18.2\, MeV $ | 1 | 1 | 2 |
Fermions | 90 |
Problem 1
Find the energy and number densities for bosons and fermions in the relativistic limit.
The energy density equals to $$ \rho = \left\{ \begin{array}{c} \frac{\pi^2}{30}gT^4 \quad \; for\;bosons\\ \frac{7}{8}\frac{\pi^2}{30}gT^4 \quad for \;fermions \end{array} \right. $$ Here $g$ equals to the number of internal degrees of freedom for the particle. For photon (with spin $S=1$) $g=2$ due to absence of longitudinal polarization for the zero-mass particles. The number density is the following: \[ n = \left\{ \begin{array}{c} \frac{\zeta (3)}{\pi ^2 }gT^3 \quad \;for\;bosons \\ \frac{3} {4}\frac{\zeta (3)}{\pi ^2 }gT^3 \quad \; for\;fermions \end{array} \right. \] Here $\zeta (x)$ is the Riemann $\zeta$-function; $\zeta (3) \approx 1.202$.
Problem 2
Find the number densities and energy densities, normalized to the photon energy density at the same temperature, for neutrinos, electrons, positrons, pions and nucleons in the relativistic limit.
\[ \frac{n_i}{n_\gamma} = \left\{ \begin{gathered} \frac{1}{2}g_i \quad for\; bosons\\ \frac{3}{8}g_i \quad for\; fermions\\ \end{gathered} \right.;\quad \frac{\rho_i}{\rho_\gamma} = \left\{ \begin{gathered} \frac{1}{2}g_i \quad for\; bosons\\ \frac{7}{16}g_i \quad for\; fermions\\ \end{gathered} \right. \] \[ \begin{gathered} \left(\frac{n_i }{n_\gamma},\frac{\rho_i}{\rho_\gamma} \right)_{\nu_{\mu ,e}} = \left( \frac{3}{8},\frac{7}{16} \right);\;\;\left( \frac{n_i}{n_\gamma}, \frac{\rho_i}{\rho_\gamma} \right)_{e^\pm} = \left( \frac{3}{4},\frac{7}{8} \right);\\ \left( \frac{n_i}{n_\gamma},\frac{\rho_i}{\rho_\gamma} \right)_\pi = \left( \frac{1}{2},\frac{1}{2} \right);\;\;\left( \frac{n_i}{n_\gamma},\frac{\rho_i}{\rho_\gamma} \right)_{n,p} = \left( \frac{3}{4},\frac{7}{8} \right) \\ \end{gathered} \]
Problem 3
Calculate the average energy per particle in the relativistic and non-relativistic limits.
Average energy per particle reads$\left\langle \varepsilon \right\rangle = \rho /n$. For $T \gg m$ \[ \left\langle \varepsilon \right\rangle = \left\{ \begin{gathered} \frac{\pi ^2}{30\zeta (3)}T\quad \; for\; bosons\\ \frac{7\pi ^4}{180\zeta(3)}T\quad for\; fermions\\ \end{gathered} \right. \] In the non-relativistic limit $(T \ll m)$ one obtains the following: \[ \left\langle \varepsilon \right\rangle = m + \frac{3}{2}T \approx m \]
Problem 4
Find the number of internal degrees of freedom for a quark.
For quark one obtains the following: \[ g = 2(\, spin) \times 3(\, particle) \times 2(\, particles + \, antiparticle) = 12 \]
Problem 5
Find the entropy density for bosons end fermions with zero chemical potential.
In the considered case one gets: \[ s = \frac{\rho + p}{T};\quad p = \frac{1}{3}\rho \] Using the results of problem of the present Chapter one obtains the following: \[ s = \frac{2\pi ^2}{45}g^* T^3, \] where $g^* = 1$ for bosons and $g^* = 7/8$ for fermions.
Problem 6
Find the effective number of internal degrees of freedom for a mixture of relativistic bosons and fermions.
\[ \rho = \sum\limits_{i = bosons} g_i \frac{\pi^2}{30} T^4 + \sum\limits_{j = fermions} \frac{7}{8}g_j\frac{\pi^2}{30} T^4 \frac{\pi^2}{30}g^* T^4, \] where $g^* $ is the effective number of degrees of freedom: \[ g^* = \sum\limits_{i = bosons} g_i + \frac{7}{8}\sum\limits_{j = fermions}g_j. \]
Problem 7
Generalize the results of the previous problem for the case when some $i$-components have temperature $T_i$ different from the CMB temperature $T$.
\[ g^* = \sum\limits_{i = bosons}g_i \left(\frac{T_i}{T} \right)^4 + \frac{7}{8}\sum\limits_{j = fermions}g_i \left( \frac{T_j}{T}\right)^4 \]
Problem 8
Find the effective number of internal degrees of freedom for the Standard Model particles at temperature $T>1TeV$.
At temperature $1\, TeV$ all the Standard Model particles are relativistic (see table). Therefore \[ g^* = 28 + \frac{7}{8} \times 90 = 106.75. \]
Problem 9
Find the change of the number of internal degrees of freedom due to the quark hadronization process.
At temperature $T \approx 0.2\, GeV$ quarks and gluons transform into colorless hadrons (protons and neutrons). Therefore \[ \Delta g = 16\,(gluons) + 12 \times 6\,(quarks) - 8\,(nucleons) = 80. \]
Problem 10
Find the relation between the energy density and temperature at $10^{10}\, K$.
Represent the expression for energy density of relativistic particles in the following form: \[ \rho = \left( \sum\limits_{i = bosons} \frac{g_i}{2} + \sum\limits_{j = fermions} \frac{7}{16}g_j \right)\rho _\gamma. \] At the temperature under consideration the relativistic particles are presented by photons, electron, positrons and neutrinos. Therefore \[ \rho = \left( 1 + \frac{7} {4} + \frac{7}{4} \right)\rho _\gamma = \frac{9}{2}\rho _\gamma = \frac{9}{2}\alpha T^4, \] where the radiation constant \[\alpha = \frac{\pi^2}{15}\frac{k^4}{(\hbar c)^3} \approx 7.56 \cdot 10^{-16}\frac{ J}{ m^3K^4}.\]
Problem 11
Find the ratio of the energy density at temperature $10^{10}\, K$ to that at $10^8\, K$.
Unlike the case considered in the previous problem, now only photons and neutrinos remain relativistic, because $10^8 K \sim 10^{ - 2} \, MeV$, and electron mass is $0.511 \, MeV$ is considerably greater. Therefore in the case under consideration one obtains the following: \[ \rho = \left( 1 + \frac{7}{4} \right)\rho _\gamma = \frac{11}{4}\rho _\gamma \Rightarrow \frac{\rho\left(T_2 = 10^{10} K \right)}{\rho \left( T_1 = 10^8 K \right)} = \frac{18} {11}\left(\frac{T_2}{T_1}\right)^4\simeq1.6\cdot10^8.\]
Problem 12
Determine Fermi energy of cosmological neutrino background (CNB) (a gas).
For a relativistic Fermi-gas the Fermi energy reads the following $E_F = \hbar c\left( 3\pi ^2 n \right)^{1/3} ;$ $\hbar c \simeq 197.3 \, MeV\cdot \, fm$, $n \simeq 300 \, cm^{-3}$, so $$E_F \simeq 0.4 \times 10^{-3} \, eV.$$