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→Critical exponents 临界指数
:<math>\label{eq:10}
:<math>\label{eq:10}
h(r,t)=r^{-(d-2+\eta)}G(r/\xi). </math>
h(r,t)=r^{-(d-2+\eta)}G(r/\xi). </math>
铁磁体和流体中的长程空间相关函数在临界点附近也表现出齐次性。简单起见,考虑磁场强度<math>H=0</math>且温度接近临界点的情况,关联函数<math>r</math>作为空间分离<math>r</math>(假设很大)的函数,如下所示:{{NumBlk|:|<math>h(r,t)=r^{-(d-2+\eta)}G(r/\xi). </math>|{{EquationRef|10}}}}
铁磁体和流体中的长程空间相关函数在临界点附近也表现出齐次性。简单起见,考虑磁场强度<math>H=0</math>且温度接近临界点的情况,关联函数<math>h(r,t)</math>作为空间分离<math>r</math>(假设很大)的函数,如下所示:{{NumBlk|:|<math>h(r,t)=r^{-(d-2+\eta)}G(r/\xi). </math>|{{EquationRef|10}}}}
Here <math>d</math> is the dimensionality of space, <math>\eta</math> is another critical-point exponent, and <math>\xi</math> is the correlation length (exponential
Here <math>d</math> is the dimensionality of space, <math>\eta</math> is another critical-point exponent, and <math>\xi</math> is the correlation length (exponential
:<math>\label{eq:11}
:<math>\label{eq:11}
\xi\sim \mid t\mid ^{-\nu} </math>
\xi\sim \mid t\mid ^{-\nu} </math>
其中<math>d</math>是空间维度,<math>\eta</math>是另一临界点指数,<math>\xi</math>是关联长度(相关系数的指数衰减长度),当趋近于临界点时,其发散过程满足:{{NumBlk|:|<math>\xi\sim \mid t\mid ^{-\nu}</math>|{{EquationRef|11}}}}
其中<math>d</math>是空间维度,<math>\eta</math>是另一临界点指数,<math>\xi</math>是关联长度(相关关系的指数衰减长度),当趋近于临界点时,其发散过程满足:{{NumBlk|:|<math>\xi\sim \mid t\mid ^{-\nu}</math>|{{EquationRef|11}}}}
as the critical point is approached, with <math>\nu</math> still another critical-point exponent. Thus, <math>h(r,t)</math> (with <math>H=0)</math> is a homogeneous function of <math>r</math> and <math>\mid t\mid
as the critical point is approached, with <math>\nu</math> still another critical-point exponent. Thus, <math>h(r,t)</math> (with <math>H=0)</math> is a homogeneous function of <math>r</math> and <math>\mid t\mid
Thus, as <math>r\rightarrow \infty</math> in any fixed thermodynamic state (fixed t) near the critical point, <math>h</math> decays with increasing <math>r</math> proportionally to <math>r^{-\frac{1}{2}(d-1)}e^{-r/\xi}\ ,</math> as in the [https://en.wikipedia.org/wiki/Ornstein%E2%80%93Zernike_equation?oldformat=true '''Ornstein-Zernike theory''']. If, instead, the critical point is approached <math>(\xi \rightarrow \infty)</math> with a fixed, large <math>r\ ,</math> we have <math>h(r)</math> decaying with <math>r</math> only as an inverse power, <math>r^{-(d-2+\eta)}\ ,</math> which corrects the <math>r^{-(d-2)}</math> that appears in the Ornstein-Zernike theory in that limit. The scaling law({{EquationNote|1=10}}) with scaling function <math>G(x)</math> interpolates between these extremes.
Thus, as <math>r\rightarrow \infty</math> in any fixed thermodynamic state (fixed t) near the critical point, <math>h</math> decays with increasing <math>r</math> proportionally to <math>r^{-\frac{1}{2}(d-1)}e^{-r/\xi}\ ,</math> as in the [https://en.wikipedia.org/wiki/Ornstein%E2%80%93Zernike_equation?oldformat=true '''Ornstein-Zernike theory''']. If, instead, the critical point is approached <math>(\xi \rightarrow \infty)</math> with a fixed, large <math>r\ ,</math> we have <math>h(r)</math> decaying with <math>r</math> only as an inverse power, <math>r^{-(d-2+\eta)}\ ,</math> which corrects the <math>r^{-(d-2)}</math> that appears in the Ornstein-Zernike theory in that limit. The scaling law({{EquationNote|1=10}}) with scaling function <math>G(x)</math> interpolates between these extremes.
因此,在任何靠近临界点的恒温热力学状态下,当<math>r\rightarrow \infty</math>时,<math>h</math>随<math>r</math>的增加而衰减,与<math>r^{-\frac{1}{2}(d-1)}e^{-r/\xi}\ ,</math>成正比(参见'''[https://en.wikipedia.org/wiki/Ornstein%E2%80%93Zernike_equation? 奥恩斯泰因-泽尔尼克理论 Ornstein-Zernike theory]''')
In the language of fluids, with <math>\rho</math> the number density and <math>\chi</math> the isothermal compressibility, we have as an exact relation in the Ornstein-Zernike theory
In the language of fluids, with <math>\rho</math> the number density and <math>\chi</math> the isothermal compressibility, we have as an exact relation in the Ornstein-Zernike theory