Landau-Level-Resolved Mode Mixing and Shot Noise in Gate-Defined Graphene Quantum Point Contacts
Abstract
Graphene quantum point contacts (QPCs) in the quantum Hall regime host competing transport mechanisms including chiral edge propagation, valley degeneracy, and gate-induced mode mixing. Their interplay is not visible in conductance alone. Shot noise directly probes the statistics of transmission eigenvalues, revealing microscopic mode partitioning that conductance cannot access. We develop a hybrid framework combining tight-binding simulations of gate-defined graphene QPCs with random matrix theory (RMT) to predict shot noise and Fano factor signatures across different quantum Hall regimes, validated against experimental conductance maps of hBN-encapsulated graphene Hall bars. Three distinct regimes are identified: adiabatic propagation, sharp mode filtering, and multi-mode mixing driven by localized states beneath the split gate. For higher Landau levels (NL > 0), complete mode mixing produces the universal chaotic-cavity limit F 1/4. Strikingly, the zeroth Landau level (NL = 0) converges to F = 1/3. This distinct value originates in the sublattice polarization of the NL = 0 edge state: coupling to mixed-sublattice localized states beneath the gate is suppressed, confining transport to an effective single channel (N = 1). Complete mixing within this single channel yields a flat transmission eigenvalue distribution and hence exactly F = 1/3 from single-channel RMT, numerically coincident with but mechanistically distinct from pseudo-diffusive zero-field graphene transport. The F = 1/3 versus F = 1/4 crossover is a Landau-level-resolved noise signature absent in conductance, providing a direct discriminator between single-channel and multi-channel chaotic transport in graphene QPCs.
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