Underbarrier interference

Quantum tunneling through a two-dimensional static barrier becomes unusual when a momentum of an electron has a tangent component with respect to a border of the prebarrier region. If the barrier is not homogeneous in the direction perpendicular to tunneling a fraction of the electron state is waves propagating away from the barrier. When the tangent momentum is zero a mutual interference of the waves results in an exponentially small outgoing flux. The finite tangent momentum destroys the interference due to formation of caustics by the waves. As a result, a significant fraction of the prebarrier density is carried away from the barrier providing a not exponentially small penetration even through an almost classical barrier. The total electron energy is well below the barrier.

Research Highlights
► In tunneling a momentum, tangent to a border of the prebarrier region, is important.
► A tangent momentum, transferred under the barrier, is real in contrast to normal one.
► Real momenta lead to caustics points under the barrier where new branches are formed.
► Resulting eigenstate can be not small after the barrier.
► This results in a possibility of penetration through an almost classical barrier.