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'''Widom scaling''' is a hypothesis in [[statistical mechanics]] regarding the [[Thermodynamic free energy|free energy]] of a [[magnetic system]] near its [[critical point (thermodynamics)|critical point]] which leads to the [[critical exponent]]s becoming no longer independent so that they can be parameterized in terms of two values. The hypothesis can be seen to arise as a natural consequence of the block-spin renormalization procedure, when the block size is chosen to be of the same size as the correlation length.<ref>Kerson Huang, Statistical Mechanics. John Wiley and Sons, 1987</ref>
 
Widom scaling is an example of [[universality (dynamical systems)|universality]].
 
== Definitions ==
 
The critical exponents <math> \alpha, \alpha', \beta, \gamma, \gamma' </math> and <math> \delta </math> are defined in terms of the behaviour of the order parameters and response functions near the critical point as follows
 
:<math> M(t,0) \simeq (-t)^{\beta}</math>, for <math> t \uparrow 0 </math>
:<math> M(0,H) \simeq |H|^{1/ \delta} \mathrm{sign}(H)</math>, for <math> H \rightarrow 0 </math>
:<math> \chi_T(t,0) \simeq \begin{cases}
(t)^{-\gamma}, & \textrm{for} \ t \downarrow 0 \\
(-t)^{-\gamma'}, & \textrm{for} \ t \uparrow 0 \end{cases}
</math>
 
:<math> c_H(t,0) \simeq \begin{cases}
(t)^{-\alpha} & \textrm{for} \ t \downarrow 0 \\
(-t)^{-\alpha'} & \textrm{for} \ t \uparrow 0 \end{cases}
</math>
 
where
 
:<math> t \equiv \frac{T-T_c}{T_c}</math> measures the temperature relative to the critical point.
 
Near the critical point, Widom's scaling relation reads
 
:<math> H(t) \simeq  M|M|^{\delta-1} f(t/|M|^{1/\beta})</math>.
 
where <math>f</math> has an expansion
:<math> f(t/|M|^{1/\beta})\approx 1+{\rm const}\times( t/|M|^{1/\beta})^\omega +\dots
</math>,
with <math> \omega</math>
being Wegner's exponent governing the [[approach to scaling]].  
 
== Derivation ==
 
The scaling hypothesis is that near the critical point, the free energy <math>f(t,H)</math>, in <math>d</math> dimensions, can be written as the sum of a slowly varying regular part <math>f_r</math> and a singular part <math>f_s</math>, with the singular part being a scaling function, i.e., a [[homogeneous function]], so that
 
:<math> f_s(\lambda^p t, \lambda^q H) = \lambda^d f_s(t, H) \,</math>
 
Then taking the [[partial derivative]] with respect to  ''H'' and the form of ''M(t,H)'' gives
 
:<math> \lambda^q M(\lambda^p t, \lambda^q H) = \lambda^d M(t, H)  \,</math>
 
Setting <math>H=0</math> and <math> \lambda = (-t)^{-1/p} </math> in the preceding equation yields
 
:<math> M(t,0) = (-t)^{\frac{d-q}{p}} M(-1,0),</math> for <math> t \uparrow 0 </math>
 
Comparing this with the definition of <math>\beta</math> yields its value,
 
:<math> \beta = \frac{d-q}{p}\equiv \frac{\nu}2(d-2+\eta). </math>
 
Similarly, putting <math>t=0</math> and <math> \lambda = H^{-1/q} </math> into the scaling relation for ''M'' yields
 
:<math> \delta = \frac{q}{d-q} \equiv \frac{d+2-\eta}{d-2+\eta}.</math>
 
Hence
 
:<math> \frac{q}{p}  = \frac{\nu}{2}
(d+2-\eta),~\frac 1 p=\nu.</math>
 
 
Applying the expression for the [[isothermal susceptibility]] <math> \chi_T </math> in terms of ''M'' to the scaling relation yields
 
:<math> \lambda^{2q} \chi_T (\lambda^p t, \lambda^q H) = \lambda^d \chi_T (t, H)  \,</math>
 
Setting ''H=0'' and <math> \lambda = (t)^{-1/p}</math> for <math> t \downarrow 0</math> (resp. <math> \lambda = (-t)^{-1/p} </math> for <math> t \uparrow 0 </math>) yields
 
:<math> \gamma = \gamma' = \frac{2q -d}{p}  \,</math>
 
Similarly for the expression for [[specific heat]] <math> c_H </math> in terms of ''M'' to the scaling relation yields
 
:<math> \lambda^{2p} c_H ( \lambda^p t, \lambda^q H) = \lambda^d c_H(t, H) \, </math>
 
Taking ''H=0'' and <math> \lambda = (t)^{-1/p} </math> for <math> t \downarrow 0 </math> (or <math> \lambda = (-t)^{-1/p} </math> for <math>t \uparrow 0)</math> yields
 
:<math> \alpha = \alpha' = 2 -\frac{d}{p}=2-\nu d </math>
 
As a consequence of Widom scaling, not all critical exponents are independent but they can be parameterized by two numbers <math> p, q \in \mathbb{R} </math> with the relations expressed as
 
:<math> \alpha = \alpha' = 2-\nu d,</math>
:<math> \gamma = \gamma' = \beta(\delta -1)=\nu(2-\eta) .</math>
 
The relations are experimentally well verified for magnetic systems and fluids.
 
==References==
*H. E. Stanley, ''Introduction to Phase Transitions and Critical Phenomena''
*[[Hagen Kleinert|H. Kleinert]] and V. Schulte-Frohlinde, ''Critical Properties of φ<sup>4</sup>-Theories'', [http://www.worldscibooks.com/physics/4733.html World Scientific (Singapore, 2001)];  Paperback ISBN 981-02-4658-7'' (also available [http://users.physik.fu-berlin.de/~kleinert/kleinert/?p=booklist&details=6 online])''
{{Reflist|2}}
 
[[Category:Critical phenomena]]
[[Category:Statistical mechanics]]

Revision as of 04:57, 26 September 2013

Widom scaling is a hypothesis in statistical mechanics regarding the free energy of a magnetic system near its critical point which leads to the critical exponents becoming no longer independent so that they can be parameterized in terms of two values. The hypothesis can be seen to arise as a natural consequence of the block-spin renormalization procedure, when the block size is chosen to be of the same size as the correlation length.[1]

Widom scaling is an example of universality.

Definitions

The critical exponents α,α,β,γ,γ and δ are defined in terms of the behaviour of the order parameters and response functions near the critical point as follows

M(t,0)(t)β, for t0
M(0,H)|H|1/δsign(H), for H0
χT(t,0){(t)γ,fort0(t)γ,fort0
cH(t,0){(t)αfort0(t)αfort0

where

tTTcTc measures the temperature relative to the critical point.

Near the critical point, Widom's scaling relation reads

H(t)M|M|δ1f(t/|M|1/β).

where f has an expansion

f(t/|M|1/β)1+const×(t/|M|1/β)ω+,

with ω being Wegner's exponent governing the approach to scaling.

Derivation

The scaling hypothesis is that near the critical point, the free energy f(t,H), in d dimensions, can be written as the sum of a slowly varying regular part fr and a singular part fs, with the singular part being a scaling function, i.e., a homogeneous function, so that

fs(λpt,λqH)=λdfs(t,H)

Then taking the partial derivative with respect to H and the form of M(t,H) gives

λqM(λpt,λqH)=λdM(t,H)

Setting H=0 and λ=(t)1/p in the preceding equation yields

M(t,0)=(t)dqpM(1,0), for t0

Comparing this with the definition of β yields its value,

β=dqpν2(d2+η).

Similarly, putting t=0 and λ=H1/q into the scaling relation for M yields

δ=qdqd+2ηd2+η.

Hence

qp=ν2(d+2η),1p=ν.


Applying the expression for the isothermal susceptibility χT in terms of M to the scaling relation yields

λ2qχT(λpt,λqH)=λdχT(t,H)

Setting H=0 and λ=(t)1/p for t0 (resp. λ=(t)1/p for t0) yields

γ=γ=2qdp

Similarly for the expression for specific heat cH in terms of M to the scaling relation yields

λ2pcH(λpt,λqH)=λdcH(t,H)

Taking H=0 and λ=(t)1/p for t0 (or λ=(t)1/p for t0) yields

α=α=2dp=2νd

As a consequence of Widom scaling, not all critical exponents are independent but they can be parameterized by two numbers p,q with the relations expressed as

α=α=2νd,
γ=γ=β(δ1)=ν(2η).

The relations are experimentally well verified for magnetic systems and fluids.

References

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  1. Kerson Huang, Statistical Mechanics. John Wiley and Sons, 1987