In statistical mechanics, Lee–Yang theory, sometimes also known as Yang–Lee theory, is a scientific theory which seeks to describe phase transitions in large physical systems in the thermodynamic limit based on the properties of small, finite-size systems. The theory revolves around the complex zeros of partition functions of finite-size systems and how these may reveal the existence of phase transitions in the thermodynamic limit.
Lee–Yang theory constitutes an indispensable part of the theories of phase transitions. Originally developed for the Ising model, the theory has been extended and applied to a wide range of models and phenomena, including protein folding, percolation, complex networks, and molecular zippers.
The theory is named after the Nobel laureates Tsung-Dao Lee and Yang Chen-Ning, who were awarded the 1957 Nobel Prize in Physics for their unrelated work on parity non-conservation in weak interaction.[1]
For an equilibrium system in the canonical ensemble, all statistical information about the system is encoded in the partition function,
Z=\sumi
| -\betaEi | |
| e |
,
\beta=1/(kBT)
kB
Ei
\langleEn\rangle
\langleEn\rangle=
| 1 | |
| Z |
| n | |
| \partial | |
| -\beta |
Z=
| |||||||||||||||||
|
.
F=-\beta-1log[Z].
\langle\langleEn\rangle\rangle=
| n | |
| \partial | |
| -\beta |
(-\betaF).
More generally, if the microstate energies
Ei(q)=Ei(0)-q\Phii
q
\Phi
\Phi
\langle\Phin\rangle=
| 1 | |
| Z |
\beta-n
| n | |
| \partial | |
| q |
Z(q)=
| 1 | |
| Z |
\beta-n
| n | |
| \partial | |
| q |
\sumi
| -\betaEi(q) | |
| e |
=
| |||||||||||||||||
|
,
\langle\langle\Phin\rangle\rangle=\beta-n
| n | |
| \partial | |
| q |
[-\betaF(q)].
q=h
\Phi=M
The partition function and the free energy are intimately linked to phase transitions, for which there is a sudden change in the properties of a physical system. Mathematically, a phase transition occurs when the partition function vanishes and the free energy is singular (non-analytic). For instance, if the first derivative of the free energy with respect to the control parameter is non-continuous, a jump may occur in the average value of the fluctuating conjugate variable, such as the magnetization, corresponding to a first-order phase transition.
Importantly, for a finite-size system,
Z(q)
q
F(q)
F(q)
Using that
Z(q)
q
q=q*
In this way, Lee–Yang theory establishes a connection between the properties (the zeros) of a partition function for a finite size system and phase transitions that may occur in the thermodynamic limit (where the system size goes to infinity).
The molecular zipper is a toy model which may be used to illustrate the Lee–Yang theory. It has the advantage that all quantities, including the zeros, can be computed analytically. The model is based on a double-stranded macromolecule with
N
\varepsilon
For a number
g
N
Z=
| Ng | |
| \sum | |
| n=0 |
ne-\beta=
| 1-(ge-\beta)N+1 | |
| 1-ge-\beta |
\betak=\betac+
| 2\pik | |
| \varepsilon(N+1) |
i, k\in\{-N,...,N\}\backslash\{0\},
| -1 | |
| \beta | |
| c |
=kBTc
Tc=
| \varepsilon | |
| kBlogg |
N → infty
\betak=\betac
g=1
g>1
Tc
To confirm that the system displays a non-analytic behavior in the thermodynamic limit, we consider the free energy
F=-kBTlogZ
| F | |
| N\varepsilon |
.
\limN →
| F | |
| N\varepsilon |
=\limN → -
| \beta-1 | log\left[ | |
| N\varepsilon |
| 1-(ge-\beta)N+1 | |
| 1-ge-\beta |
\right]=\begin{cases} 1-T/Tc,&T>Tc\\ 0,&T\leqTc \end{cases}
Tc
See also: Ising model. The Ising model is the original model that Lee and Yang studied when they developed their theory on partition function zeros. The Ising model consists of spin lattice with
N
\{\sigmak\}
\sigmak=+1
\sigmak=-1
Jij
h>0
\{\sigmai\}
H(\{\sigmai\},h)=-\sum\langleJij\sigmai\sigmaj-h\sumj\sigmaj.
Z(h)=
| \sum | |
| \{\sigmai\ |
See main article: article and Lee–Yang theorem. For the ferromagnetic Ising model, for which
Jij\geq0
i,j
Z(h)
z\equiv\exp(-2\betah)
A similar approach can be used to study dynamical phase transitions. These transitions are characterized by the Loschmidt amplitude, which plays the analogue role of a partition function.
The Lee–Yang zeros may be connected to the cumulants of the conjugate variable
\Phi
q
\beta=1
Z(q)=Z(0)ecq\prodk(1-q/qk),
Z(0)
c
qk
k
q
-F(q)=log[Z(q)]=log[Z(0)]+cq+\sumklog[1-q/qk].
n
q
n
\langle\langle\Phin\rangle\rangle=
| n | |
| \partial | |
| q |
[-F(q)]=-\sumk
| (n-1)! | ||||||
|
, n>1.
\langle\langle\Phin\rangle\rangle=-(n-1)!\sumk
| 2\cos(n\arg\{qk-q\ | |
| )}{|q |
| n}, | |
| k-q| |
n>1,
Moreover, if
n
q
q0
\langle\langle\Phin\rangle\rangle\simeq-(n-1)!
| 2\cos(n\arg\{q0-q\ | |
| )}{|q |
| n}, | |
| 0-q| |
n\gg1.
\begin{bmatrix}2Re[q-q0]\ |q-q0|\end{bmatrix}=\begin{bmatrix}1&-
| |||||||
| n |
\ 1&-
| |||||||
| n+1 |
\end{bmatrix}-1\begin{bmatrix}(n-1)
| (-) | |
| \kappa | |
| n |
\ n
| (-) | |
| \kappa | |
| n+1 |
\end{bmatrix}, \kappa\pm\equiv
| \langle\langle\Phin\pm1\rangle\rangle | |
| \langle\langle\Phin\rangle\rangle |
.
Being complex numbers of a physical variable, Lee–Yang zeros have traditionally been seen as a purely theoretical tool to describe phase transitions, with little or none connection to experiments. However, in a series of experiments in the 2010s, various kinds of Lee–Yang zeros have been determined from real measurements. In one experiment in 2015, the Lee–Yang zeros were extracted experimentally by measuring the quantum coherence of a spin coupled to an Ising-type spin bath. In another experiment in 2017, dynamical Lee–Yang zeros were extracted from Andreev tunneling processes between a normal-state island and two superconducting leads. Furthermore, in 2018, there was an experiment determining the dynamical Fisher zeros of the Loschmidt amplitude, which may be used to identify dynamical phase transitions.