Semicircle law (quantum Hall effect): Difference between revisions

The semicircle law, in condensed matter physics, is a mathematical relationship that occurs between quantities measured in the quantum Hall effect. It describes a relationship between the anisotropic and isotropic components of the macroscopic conductivity tensor Template:Mvar, and, when plotted, appears as a semicircle.

The semicircle law was first described theoretically in Dykhne and Ruzin's analysis of the quantum Hall effect as a mixture of 2 phases: a free electron gas, and a free hole gas.^[1][2] Mathematically, it states that $${\displaystyle {\sigma }_{xx}^2+({\sigma }_{xy}-{\sigma }_{xy}^0{)}^2=({\sigma }_{xx}^0{)}^2}$$where Template:Mvar is the mean-field Hall conductivity, and Template:Math is a parameter that encodes the classical conductivity of each phase. A similar law also holds for the resistivity.^[1]

A convenient reformulation of the law mixes conductivity and resistivity: $${\displaystyle {\sigma }_{xy}^0=\frac{{\rho }_{xy}^0}{({\rho }_{xy}^0{)}^2+({\rho }_{xx}^0{)}^2}=\frac{e^2}{h}(n+\frac{1}{2})}$$where Template:Mvar is an integer, the Hall divisor.^[3]

Although Dykhne and Ruzin's original analysis assumed little scattering, an assumption that proved empirically unsound, the law holds in the coherent-transport limits commonly observed in experiment.^[2][4]

Theoretically, the semicircle law originates from a representation of the modular group Template:Math, which describes a symmetry between different Hall phases. (Note that this is not a symmetry in the conventional sense; there is no conserved current.)^[5][6] That group's strong connections to number theory also appear: Hall phase transitions (in a single layer)^[5] exhibit a selection rule$${\displaystyle |p{q}^{\prime }-p^{\prime }q|=1}$$that also governs the Farey sequence.^[5][6] Indeed, plots of the semicircle law are also Farey diagrams.

In striped quantum Hall phases, the relationship is slightly more complex, because of the broken symmetry:$${\displaystyle \{\begin{array}{c}{\sigma }_1{\sigma }_2+({\sigma }_h-{\sigma }_h^0{)}^2=(e^2/(2h){)}^2\\ {\sigma }_h^0=(N+1/2)e^2/h\end{array}}$$Here Template:Math and Template:Math describe the macroscopic conductivity in directions aligned with and perpendicular to the stripes.^[7]

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