Editing Universality classes

'''Universality classes''' are groups of [[Idealised models | models]] that have the same set of [[critical exponents]]

:{| border="1"
|- 
| dimension ||<math>\alpha</math> || <math>\beta</math> || <math>\gamma</math> || <math>\delta</math> ||<math>\nu</math> || <math>\eta</math> || class
|- 
|  ||    ||   || || ||  || || 3-state Potts
|- 
|  ||   ||    || || || ||  ||Ashkin-Teller
|- 
|  ||  ||    || || || || ||Chiral
|- 
|  ||   ||    || || || ||  ||Directed percolation
|- 
| 2 ||  0 || <math>1/8</math>  || <math>7/4</math> || || 1  || 1/4  ||  2D Ising
|- 
| 3 ||   0.1096(5)  || 0.32653(10)  ||  1.2373(2)    || 4.7893(8) ||  0.63012(16) || 0.03639(15) ||  3D Ising
|- 
|  ||    ||    || || || ||   ||Local linear interface
|- 
|  ||  0 || <math>1/2</math>   || 1  ||  || ||  || Mean-field
|- 
|  ||  ||    || || || ||  ||Molecular beam epitaxy
|- 
|  ||   ||   ||  || || ||  ||Random-field
|- 
| 3 ||  −0.0146(8) || 0.3485(2)  ||   1.3177(5) || 4.780(2)  ||0.67155(27)  || 0.0380(4) ||  XY
|}

where 
*<math>\alpha</math>  is known as  the [[Critical exponents#Heat capacity exponent| heat capacity exponent]]  
*<math>\beta</math>  is known as the  [[Critical exponents#Magnetic order parameter exponent | magnetic order parameter exponent]]
*<math>\gamma</math> is known as  the [[Critical exponents#Susceptibility exponent |susceptibility exponent ]]
*<math>\nu</math> is known as the [[Critical exponents#Correlation length | correlation length]]
*<math>\eta</math> is known as...

==3-state Potts==
[[Potts model]]
==Ashkin-Teller==
[[Ashkin-Teller model]]
==Chiral==
==Directed percolation==
==Ising==
The [[Hamiltonian]] of the [[Ising model]] is 

<math>
 H=\sum_{<i,j>}S_i S_j
</math>


where <math>S_i=\pm 1</math> and the summation runs over the lattice sites.

The [[Order parameters | order parameter]] is 
<math>
m=\sum_i S_i
</math>

In two dimensions, Onsager obtained the exact solution in the absence of a external field, and the [[critical exponents]] are

:<math>
\alpha=0
</math>

(In fact, the [[Heat capacity |specific heat]] diverges logarithmically with the [[Critical points |critical temperature]])

<math>
\beta=\frac{1}{8}
</math>

<math>
\gamma=\frac{7}{4}
</math>

<math>
\delta=15
</math>

along with <ref>[http://dx.doi.org/10.1103/PhysRev.180.594 Michael E. Fisher "Rigorous Inequalities for Critical-Point Correlation Exponents", Physical Review '''180''' pp. 594-600 (1969)]</ref>:

:<math>
\nu=1
</math>

:<math>
\eta = 1/4
</math>


In three dimensions, the critical exponents are not known exactly. However, [[Monte Carlo | Monte Carlo simulations]] and   [[Renormalisation group]] analysis provide accurate estimates <ref name="Campostrini2002">[http://dx.doi.org/10.1103/PhysRevE.65.066127 Massimo Campostrini, Andrea Pelissetto, Paolo Rossi, and Ettore Vicari "25th-order high-temperature expansion results for three-dimensional Ising-like systems on the simple-cubic lattice", Physical Review E '''65''' 066127 (2002)]</ref>:

:<math>
\nu=0.63012(16)
</math>

:<math>
\alpha=0.1096(5)
</math>

:<math>
\beta= 0.32653(10)
</math> 

:<math>
\gamma=1.2373(2)
</math>

:<math>
\delta=4.7893(8)
</math>

:<math>
\eta =0.03639(15)
</math>

with a critical temperature of <math>k_BT_c = 4.51152786~S </math><ref>[http://dx.doi.org/10.1088/0305-4470/29/17/042 A. L. Talapov and H. W. J Blöte "The magnetization of the 3D Ising model", Journal of Physics A: Mathematical and General '''29''' pp. 5727-5733 (1996)]</ref>. In four and higher dimensions, the critical exponents are mean-field with logarithmic corrections.

==Local linear interface==
==Mean-field==
The [[critical exponents]] of are derived as follows <ref>Linda E. Reichl "A Modern Course in Statistical Physics", Wiley-VCH, Berlin 3rd Edition (2009) ISBN 3-527-40782-0 &sect; 4.9.4 </ref>:
====Heat capacity exponent: <math>\alpha</math>====
(final result: <math>\alpha=0</math>)
====Magnetic order parameter exponent: <math>\beta</math>====
(final result: <math>\beta=1/2</math>)
====Susceptibility exponent: <math>\gamma</math>====
(final result: <math>\gamma=1</math>)
==Molecular beam epitaxy==
==Random-field==
==XY==
For the three dimensional [[XY model]] one has the following [[critical exponents]]<ref name="Campostrini2001" >[http://dx.doi.org/10.1103/PhysRevB.63.214503  Massimo Campostrini, Martin Hasenbusch, Andrea Pelissetto, Paolo Rossi, and Ettore Vicari "Critical behavior of the three-dimensional XY universality class" Physical Review B  '''63''' 214503 (2001)]</ref>:

:<math>
\nu=0.67155(27)
</math>

:<math>\alpha = -0.0146(8)</math>

:<math>
\beta= 0.3485(2)
</math> 

:<math>
\gamma=1.3177(5)
</math>

:<math>
\delta=4.780(2)
</math>

:<math>
\eta =0.0380(4)
</math>

==References==
<references/>
[[category: Renormalisation group]]