Neutrino billiards: time-reversal symmetry-breaking without magnetic fields

Abstract

A Dirac hamiltonian describing massless spin-half particles (‘neutrinos’) moving in the plane r = ( x, y ) under the action of a 4-scalar (not electric) potential V(r) is, in position representation, H ^ = − i h c σ ^ ⋅ ∇ + V ( r ) σ ^ z , , where σ̂ = (σ̂ _x , σ̂ _y ) and σ̂ _z are the Pauli matrices; Ĥ acts on two-component column spinor wavefunctions ψ ( r ) = ( ψ ₁ , ψ ₂ ) and has eigen­values ћck _n . Ĥ does not possess time-reversal symmetry ( T ). If V ( r ) describes a hard wall bounding a finite domain D (‘billiards’), this is equivalent to a novel boundary condition for ψ ₂ / ψ ₁ . T -breaking is interpreted semiclassically as a difference of π between the phases accumulated by waves travelling in opposite senses round closed geo­desics in D with odd numbers of reflections. The semiclassical (large- k ) asymptotics of the eigenvalue counting function (spectral staircase) N ( k ) are shown to have the ‘Weyl’ leading term Ak ² /4π, where A is the area of D, but zero perimeter correction. The Dirac equation is transformed to an integral equation round the boundary of D, and forms the basis of a numerical method for computing the k _n . When D is the unit disc, geodesics are integrable and the eigenvalues, which satisfy J _l ( k _n ) = J _{l +1} ( k _n ), are (locally) Poisson-distributed. When D is an ‘Africa’ shape (cubic conformal map of the unit disc), the eigenvalues are (locally) distributed according to the statistics of the gaussian unitary ensemble of random-matrix theory, as predicted on the basis of T -breaking and lack of geometric symmetry.