Understanding magnetic focusing in graphene p-n junctions through quantum modeling

Abstract

We present a quantum model which provides enhanced understanding of recent transverse magnetic focusing experiments on graphene p-n junctions. Spatially resolved flow maps of local particle current density show quantum interference and p-n junction filtering effects which are crucial to explaining the device operation. The Landauer-B\"uttiker formula is used alongside dephasing edge contacts to give exceptional agreement between simulated non-local resistance and the recent experiment by Chen et al (Science, 2016). The origin of positive and negative focusing resonances and off resonance characteristics are explained in terms of quantum transmission functions. Our model also captures subtle features from experiment, such as the previously unexplained p-p- to p-p+ transition and the second p-n focusing resonance.