128,707 research outputs found

    Bilayer Graphene Interferometry : Phase Jump and Wave Collimation

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    We theoretically study the phase of the reflection amplitude of an electron (massive Dirac fermion) at a lateral potential step in Bernal-stacked bilayer graphene. The phase shows anomalous jump of π\pi, as the electron incidence angle (relative to the normal direction to the step) varies to pass ±π/4\pm \pi/4. The jump is attributed to the Berry phase associated with the pseudospin-1/2 of the electron. This Berry-phase effect is robust against the band gap opening due to the external electric gates generating the step. We propose an interferometry setup in which collimated waves can be generated and tuned. By using the setup, one can identify both the π\pi jump and the collimation angle.Comment: 4 pages, 6 figure

    Large-N analysis of (2+1)-dimensional Thirring model

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    We analyze (2+1)(2+1)-dimensional vector-vector type four-Fermi interaction (Thirring) model in the framework of the 1/N1/N expansion. By solving the Dyson-Schwinger equation in the large-NN limit, we show that in the two-component formalism the fermions acquire parity-violating mass dynamically in the range of the dimensionless coupling α\alpha, 0≤α≤αc≡116exp(−Nπ216)0 \leq \alpha \leq \alpha_c \equiv {1\over16} {\rm exp} (- {N \pi^2 \over 16}). The symmetry breaking pattern is, however, in a way to conserve the overall parity of the theory such that the Chern-Simons term is not induced at any orders in 1/N1/N. αc\alpha_c turns out to be a non-perturbative UV-fixed point in 1/N1/N. The β\beta function is calculated to be β(α)=−2(α−αc)\beta (\alpha) = -2 (\alpha - \alpha_c) near the fixed point, and the UV-fixed point and the β\beta function are shown exact in the 1/N1/N expansion.Comment: 14 pages Latex. (Revised version: some changes have been made and references added.) To appear in Phys. Rev. D, SNUTP 93-4
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