Barkhausen noise

Research into the study of small perturbations within a large domains began in the late 1910s when Heinrich Barkhausen investigated how the domains, or dipoles, within a ferromagnetic material changed under the influence of an external magnetic field. When demagnetised, a magnet’s dipoles are pointing in random directions hence the net magnetic force from all the dipoles will be zero. By coiling an iron bar with wire and passing an electric current through the wire, a magnetic field perpendicular to the coil is produced (Fleming’s right hand rule for a coil), this causes the dipoles within the magnet to align to the external field.

Contrary to what was thought at the time that these domains flip continuously one by one, Barkhausen found that clusters of domains flipped in small discrete steps.^[7] By coiling a secondary coil around the bar connected to a speaker or detector, when a cluster of domains change alignment a change in flux occurs, this disrupts the current in the secondary coil and hence causes a signal output. When played out loud, this is referred to as Barkhausen noise, the magnetisation of the magnet increases in discrete steps as a function of the flux density.^[8]

Gutenberg–Richter law

Further research into crackling noise was done in the late 1940s by Charles Francis Richter and Beno Gutenberg who examined earthquakes analytically. Before the invention of the well-known Richter scale, the Mercalli intensity scale was used; this is a subjective measurement of how damaging an earthquake was to property, i.e. II would be small vibrations and objects moving, while XII would be wide spread destruction of all buildings. The Richter scale is a logarithmic scale which measures the energy and amplitude of vibrations dissipated from the epicentre of the earthquake, i.e. a 7.0 earthquake is 10 times more powerful than a 6.0 earthquake. Together with Gutenberg, they went on to discover the Gutenberg–Richter law which is a probability distribution relationship between the magnitude of an earthquake and its probability of occurrence. It states that small earthquakes happen much more frequently and larger earthquakes occur very rarely.^[9]

${\displaystyle N=10^{a-bM}}$

Gutenberg–Richter law^[10] shows an inverse power relation between the number of earthquakes occurring N and its magnitude M with a proportionality constant b and intercept a.

Parametrisation

The net force is composed of three components which can correspond to physical attributes of any crackling noise system; the first is an external force field (K) that increases with time (t). The second component is a force that is dependent on the sum of the states of neighbouring cells (S) and the third is a random component (r) scaled by (X)^[11]

${\displaystyle F_{i}=Kt+\Sigma JS_{i}+Xr_{i}}$

The external force K is multiplied by time (t), where K is a positive scalar constant, however this can be varying and or negative as well. S represents the state of a cell (+1 or −1), the second component takes the sum of the four neighbouring cell states (up, down, left & right) and multiplies it by another scalar quantity, this is analogous to a coupling constant (J). The random number generator (r) is a normally distributed range of values with a mean of zero and a fixed standard deviation (r_σ), this is also multiplied by a scalar constant (X). Of the three components of the net force (F), the neighbour and random components can produce positive and negative values, while the external force is only positive meaning that there is a forward bias applied to the system which over time becomes the dominant force.

If the net force on a cell is positive it will turn the cell on (+1) and off (−1) if the force on the cell is negative. In a 2D system, there are a multitude of state combinations and arrangements possible, but this can be grouped into three regions, two global stable states of all +1s or all −1s and an unstable state in between where there is a mixture of both states. Traditionally if the system is unstable it will shortly flip to one of the global states, however under the perfect conditions, i.e. a critical point, a metastable state can form in between the two global states which is only sustainable if the parameters for the net force are balanced. The boundary conditions for the matrix wrap around top to bottom and left to right, problems for the corner cells can be negated using a large matrix.

Snap, crackle and pop

Three statements can be formed to describe when and how the system reacts to stimulus. The difference between the external field and the other components decides whether a system pops or crackles, but there is also a special case if the modulus of the random and neighbour components are much greater than the external field, the system snaps to a density of zero and then slows down its rate of conversion.

${\displaystyle {\begin{aligned}Kt<{}&|X2r_{\sigma }-\Sigma JS|\Rightarrow {\text{popping}}\\Kt>{}&|X2r_{\sigma }-\Sigma JS|\Rightarrow {\text{crackling}}\Rightarrow {\text{snapping}}\\Kt\ll {}&|X2r_{\sigma }-\Sigma JS|\Rightarrow {\text{snapping to equilibrium}}\end{aligned}}}$

Popping is when there are small perturbations to the system which are reversible and have a negligible effect on the global system state.

Snapping is when large clusters of cells or the whole system flips to an alternate state, i.e. all +1s or all −1s. The whole system will only flip when it has reached a critical or tipping point.

Crackling is observed when the system experiences popping and snapping of reversible small and large clusters. The system is constantly imbalanced and attempts to reach equilibrium which is not possible due to internal or external forces.

Physical meaning of components

Practical applications

During magnetisation of a magnet; the external field is the applied electric field, the neighbour component is the effect of localised magnetic fields of the dipoles and the random component represents other perturbations from external or internal stimuli. There are many practical applications to this, a manufacturer can use this type of simulation to non-destructively test their magnets to see how it responds under certain conditions. To test its magnetisation after taking a large force i.e. a hammer blow or dropping it on the floor, one could suddenly increase the external force (H) or the coupling constant (J). To test heat conditions a boundary condition could be applied to one edge with an increase in thermal fluctuations (increase X), this would require a three dimensional model.