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Problem 1: Ginzburg criterion in arbitrary spatial dimension and upper critical dimension

The general solution for the correlation function in arbitrary spatial dimension ${\displaystyle d}$ within the mean-field theory can be written as:

${\displaystyle G(r)\sim {\frac {e^{-r/\xi }}{r^{d-2}}}}$

assuming that distance ${\displaystyle r\gg a}$ is much larger than the lattice spacing ${\displaystyle a}$.

(a) Generalize the Ginzburg criterion

${\displaystyle {\frac {G(r)}{\int m^{2}d\mathbf {r} }}\ll 1}$

for the validity of the mean-field theory to arbitrary spatial dimension ${\displaystyle d}$ to show that it is satisfied if

${\displaystyle d>2+2\beta /\nu }$.

where ${\displaystyle \beta }$ and ${\displaystyle \nu }$ are critical exponents for describing vanishing of the order parameter ${\displaystyle m}$ and divergence of the correlation length ${\displaystyle \xi }$, respectively.

(b) Using your result in (a), find the upper critical dimension for the Ising model above which its critical behavior near temperature ${\displaystyle T_{c}}$ is well-described by the mean-field theory.

Problem 3: Renormalization group for 1D Ising model using transfer matrix method

The partition function for the N-spin Ising chain can be written as the trace of the N-th power of the transfer matrix T. Another way to reduce the number of degrees of freedom is the describe the system in terms of two-spin cells, where the partition function is written as:

${\displaystyle Z=\mathrm {Tr} \,\mathbf {T} ^{N}=\mathrm {Tr} \,(\mathbf {T} ^{2})^{N/2}=\mathrm {Tr} \,\mathbf {T'} ^{N/2}}$