L-3: Difference between revisions
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=Polymers, interfaces and manifolds in random media= | =Polymers, interfaces and manifolds in random media= | ||
We consider the following potential energy | We consider the following potential energy | ||
<center> <math> | |||
E_{pot}= \int dr \frac{\sigma}{2}(\nabla h)^2 + V(r,h) | |||
</math></center> | |||
The first term represents the elasticity of the manifold and the second term is the quenched disorder, due to the impurities. In general, the medium is D-dimensional, the internal coordinate of the manifold is d-dimensional and the height filed is N-dimensional. Hence,the following equations always holds: | |||
<center> <math> | |||
D=d+N | |||
</math></center> | |||
In practice, we will study two cases: | |||
* Directed Polymers (<math>d=1</math>), <math> D=1+N </math>. Examples are vortices, fronts... | |||
* Elastic interfaces (<math>N=1</math>), <math> D=d+1 </math>. Examples are domain walls... | |||
Revision as of 15:33, 28 December 2023
Goal: This lecture is dedicated to a classical model in disordered systems: the directed polymer in random media. It has been introduced to model vortices in superconductur or domain wall in magnetic film. We will focus here on the algorithms that identify the ground state or compute the free energy at temperature T, as well as, on the Cole-Hopf transformation that map this model on the KPZ equation.
Polymers, interfaces and manifolds in random media
We consider the following potential energy
The first term represents the elasticity of the manifold and the second term is the quenched disorder, due to the impurities. In general, the medium is D-dimensional, the internal coordinate of the manifold is d-dimensional and the height filed is N-dimensional. Hence,the following equations always holds:
In practice, we will study two cases:
- Directed Polymers (), . Examples are vortices, fronts...
- Elastic interfaces (), . Examples are domain walls...
