A valley valve and electron beam splitter in bilayer graphene

To develop alternative paradigms of electronics beyond the performance and application domains of silicon technology requires the exploration of fundamentally new physical mechanisms. The valley degree of freedom inherent to hexagonal two-dimensional materials offers a new route to this pursuit. In this work, quantum valley Hall kink states with ballistic conductance of $4e^2/h$ are realized in bilayer graphene. We demonstrate valley-controlled current transmission in a four-kink router device. The operations of a waveguide, a valve and a tunable electron beam splitter are achieved. The on/off ratio of the valley valve is 800%. The partition ratio of the electron beam splitter is continuously tunable from 0 to 1, with quantized fractional ratios at 1/4, 1/2 and 3/4 observed in a strong magnetic field. An S-matrix model and Landauer-B\"uttiker transport formulism provide excellent description of data. The demonstrated operations pave the path to a dissipationless quantum transportation network based on kink states in bilayer graphene.