Revision as of 20:03, 21 February 2024

Goal : This is the first lecture about the dynamics of a disordered system. We will see that different systems display pinning until a critical threshold. We will revisit Larkin arguments and discuss the spectrum of excitation of the instabilities.

Pinning and depininng of a disordered material

In the first lectures we saw that a disorder system can be trapped in deep energy states and form a glass. Today we will see that it can be also pinned and resist external deformation. Indeed disorder is at the origin of a complex energy landscape characterized by many minima (more or less deep), maxima and saddle points. An external force tilts this multidimensional landscape in a direction, but local minima survives until a finite threshold that unveils spectacular critical dynamics.

Experiments

We will discuss two examples of transition induced by pinning:

The depinning transition: interfaces pinned by impurities are ubiquitous and range from magnetic domain walls to crack fronts, from dislocations in crystals or vortices in superconductors. Above a critical force, interfaces depin, their motion is intermittent and a Barkhausen noise is detected.

The yielding transition: Everyday amorphous materials such as mayonnaise, toothpaste or foams display a behaviour intermediate between solid and liquid. They deform at small stress (as a solid) and flow at large stress (as a liquid). In between we observe intermittent plastic events.

Equation of motion

We focus on zero temperature and on the overdamped regime. In presence of an external force $f$ the equation of motion of the interface is

\partial_{t} h (x, t) = \nabla^{2} h + f + F (x, h (x, t)), with F (x, h (x, t)) = - \frac{δ V (x, h (x, t))}{δ h (x, t)}

The disorder force $F (x, h (x, t))$ is a stochastic function:

\overline{F (x, h) F (x^{'}, h^{'})} = δ^{d} (x - x^{'}) Δ (h - h^{'})

There are usually two kind of disorder: (i) Random Bond (RB) if $V (x, h)$ is short range correlated. Hence, the area below $Δ (h)$ is zero, (ii) Random field if $V (x, h)$ is a Brownian motion along $h$ .Hence, $Δ (h)$ is short range corraleted.

The velocity - force characteristic

Existence of a unique critical force $f_{c}$ : no-passing rule and Larkin model

Large force behaviour

Scaling behaviour of the depinning transition

The order parameter of the transition is the velocity of the center of mass of the interface. It is vanishing as

v_{C M} \sim | f - f_{c} |^{β} .

Two point correlation function:

\overline{v (y + x, t) v (y, t)} \sim \frac{e^{- x / ξ (f)}}{| x |^{η}}, ξ (f) \sim | f - f_{c} |^{- ν}

The interface is rough at $f_{c}$

u (b x) \sim b^{ζ} u (x), {\hat{u}}_{b q} \sim b^{ζ - d} u_{q}

\overline{{\hat{u}}_{q} {\hat{u}}_{q^{'}}} = δ^{d} (q + q^{'}) S (q), S (q) \sim \frac{1}{| q |^{d + 2 ζ}}

The motion is intermittent with avalanches even below $f_{c}$ . Their size and duration is scale free up to a cut-off:

P (S) = S^{- τ} f (S / S_{\max}), S_{\max} \sim ξ (f)^{d + ζ} \sim | f - f_{c} |^{- (d + ζ) ν}

P (T) = T^{- α} f (T / T_{\max}), T_{\max} \sim ξ (f)^{z} \sim | f - f_{c} |^{- (z) ν}

To work below threshold it iss useful to study the following protocol

Depinning exponents
Exponent	Observable	Mean field	d=1
$z$	$ℓ (t) \sim t^{z}$	2	$1.43 \pm 0.01$
$ζ$	$h (b x) \sim b^{ζ} h (x)$	0	$1.25 \pm 0.01$
$ν$	$ξ (f) \sim \| f - f_{c} \|^{- ν}$	1/2	$ν = \frac{1}{2 - ζ}$
$β$	$v_{C M} \sim \| f - f_{c} \|^{β}$	1	$β = ν (z - ζ)$
$τ$	$P (S) \sim S^{- τ}$	3/2	$τ = 2 - \frac{2}{d + ζ}$

@@ Line 63: / Line 63: @@
 P(T) = T^{-\alpha} f(T/T_\max), \quad T_\max \sim \xi(f)^{z} \sim |f-f_c|^{-(z)\nu}
 </math></center>
+To work below threshold it iss useful to study the following protocol
@@ Line 70: / Line 73: @@
 ! Exponent  !! Observable !! Mean field !! d=1
 |-
-| <math>z</math> || Example || 2 || <math>1.43\pm 0.01</math>
+| <math>z</math> || <math> \ell(t) \sim t^{z} </math> || 2 || <math>1.43\pm 0.01</math>
 |-
-| <math>\zeta</math> || Example ||0|| <math>1.25\pm 0.01</math>
+| <math>\zeta</math> || <math> h(b x) \sim b^\zeta h(x)</math> ||0|| <math>1.25\pm 0.01</math>
 |-
-| <math>\nu</math> || Example ||1/2 || <math>\nu= \frac{1}{2-\zeta}</math>
+| <math>\nu</math> || <math>\xi(f) \sim |f-f_c|^{-\nu}</math>  ||1/2 || <math>\nu= \frac{1}{2-\zeta}</math>
 |-
-| <math>\beta</math> || Example || 1 || <math>\beta= \nu(z-\zeta)</math>
+| <math>\beta</math> || <math>v_{CM} \sim |f-f_c|^{\beta}</math>  || 1 || <math>\beta= \nu(z-\zeta)</math>
 |-
 | <math>\tau</math> || <math>P(S) \sim S^{-\tau}</math>|| 3/2 || <math>\tau= 2 -\frac{2}{d+\zeta}</math>
@@ Line 83: / Line 86: @@
-, namely <math>P(S) \sim S^{-tau}</math> up to a cut-off
+==Cellular Automata==
-===Cellular automata===

L-5: Difference between revisions

Revision as of 20:03, 21 February 2024

Contents

Pinning and depininng of a disordered material

Experiments

Equation of motion

Scaling behaviour of the depinning transition

Cellular Automata

Navigation menu

L-5: Difference between revisions

Revision as of 20:03, 21 February 2024

Pinning and depininng of a disordered material

Experiments

Equation of motion

Scaling behaviour of the depinning transition

Cellular Automata

Navigation menu

Search