Behrends, J.Roy, S.Kolodrubetz, Michael H.Bardarson, J. H.Grushin, A. G.2019-10-312019-10-312019-04-012469-9950https://hdl.handle.net/10735.1/7067Condensed matter systems realizing Weyl fermions exhibit striking phenomenology derived from their topologically protected surface states as well as chiral anomalies induced by electromagnetic fields. More recently, inhomogeneous strain or magnetization were predicted to result in chiral electric E₅ and magnetic B₅ fields, which modify and enrich the chiral anomaly with additional terms. In this Rapid Communication, we develop a lattice-based approach to describe the chiral anomaly, which involves Landau and pseudo-Landau levels and treats all anomalous terms on equal footing, while naturally incorporating Fermi arcs. We exemplify its potential by physically interpreting the largely overlooked role of Fermi arcs in the covariant (Fermi level) contribution to the anomaly and revisiting the factor of 1/3 difference between the covariant and consistent (complete band) contributions to the E₅·B₅ term in the anomaly. Our framework provides a versatile tool for the analysis of anomalies in realistic lattice models as well as a source of simple physical intuition for understanding strained and magnetized inhomogeneous Weyl semimetals. ©2019 American Physical Society.en©2019 American Physical SocietyWeyl groupsParticles (Nuclear physics)—ChiralityElectromagnetic fieldsLandau levelsLattice ordered groupsPolynomials, BardeenarticleBehrends, J., S. Roy, M. H. Kolodrubetz, J. H. Bardarson, et al. 2019. "Landau levels, Bardeen polynomials, and Fermi arcs in Weyl semimetals: Lattice-based approach to the chiral anomaly." Physical Review B 99(14): art. 140241, doi: 10.1103/PhysRevB.99.1402019914