Abstract
Phase coherence of charge carriers leads to electron-wave interference in ballistic mesoscopic conductors. In graphene, such Fabry-P\'erot-like interference has been observed, but a detailed analysis has been complicated by the two-dimensional nature of conduction, which allows for complex interference patterns. In this work, we have achieved high-quality Fabry-P\'erot interference in a suspended graphene device, both in conductance and in shot noise, and analyzed their structure using Fourier transform techniques. The Fourier analysis reveals two sets of overlapping, coexisting interferences, with the ratios of the diamonds being equal to the width to length ratio of the device. We attribute these sets to a unique coexistence of longitudinal and transverse resonances, with the longitudinal resonances originating from the bunching of modes with low transverse momentum. Furthermore, our results give insight into the renormalization of the Fermi velocity in suspended graphene samples, caused by unscreened many-body interactions.
Highlights
Phase coherence of charge carriers leads to electronwave interference in ballistic mesoscopic conductors [1]
We have achieved high-quality Fabry-Perot interference in a suspended graphene device both in conductance and in shot noise
We show that these sets originate from the unique coexistence of longitudinal and transverse resonances, with the longitudinal resonances occurring due to bunching of modes with low transverse momentum
Summary
Phase coherence of charge carriers leads to electronwave interference in ballistic mesoscopic conductors [1]. Single-mode and multimode Fabry-Perot interference in suspended graphene We have achieved high-quality Fabry-Perot interference in a suspended graphene device both in conductance and in shot noise.
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