%0 Journal Article %1 PhysRevB.109.075123 %A Köhler, Fabian %A Vojta, Matthias %D 2024 %I American Physical Society %J Phys. Rev. B %K a %N 7 %P 075123 %R 10.1103/PhysRevB.109.075123 %T Nodal semimetals in d$\ge$3 to sharp pseudo-Landau levels by dimensional reduction %U https://link.aps.org/doi/10.1103/PhysRevB.109.075123 %V 109 %X Nonuniform strain applied to graphene's honeycomb lattice can induce pseudo-Landau levels in the single-particle spectrum. Various generalizations have been put forward, including a particular family of hopping models in d space dimensions. Here we show that the key ingredient for sharp pseudo-Landau levels in higher dimensions is dimensional reduction. We consider particles moving on a d-dimensional hyperdiamond lattice which displays a semimetallic band structure, with a (d−2)-dimensional nodal manifold. By applying a suitable strain pattern, the single-particle spectrum evolves into a sequence of relativistic Landau levels. We develop and solve the corresponding field theory: Each nodal point effectively generates a Landau-level problem which is strictly two dimensional to leading order in the applied strain. While the effective pseudovector potential varies across the nodal manifold, the Landau-level spacing does not. Our theory paves the way for strain engineering of single-particle states via dimensional reduction and beyond global minimal coupling.

@article{PhysRevB.109.075123, abstract = {Nonuniform strain applied to graphene's honeycomb lattice can induce pseudo-Landau levels in the single-particle spectrum. Various generalizations have been put forward, including a particular family of hopping models in d space dimensions. Here we show that the key ingredient for sharp pseudo-Landau levels in higher dimensions is dimensional reduction. We consider particles moving on a d-dimensional hyperdiamond lattice which displays a semimetallic band structure, with a (d−2)-dimensional nodal manifold. By applying a suitable strain pattern, the single-particle spectrum evolves into a sequence of relativistic Landau levels. We develop and solve the corresponding field theory: Each nodal point effectively generates a Landau-level problem which is strictly two dimensional to leading order in the applied strain. While the effective pseudovector potential varies across the nodal manifold, the Landau-level spacing does not. Our theory paves the way for strain engineering of single-particle states via dimensional reduction and beyond global minimal coupling.}, added-at = {2024-02-27T20:50:41.000+0100}, author = {K\"ohler, Fabian and Vojta, Matthias}, biburl = {https://www.bibsonomy.org/bibtex/28169d58173b5f9e98770028d88388844/ctqmat}, day = 12, doi = {10.1103/PhysRevB.109.075123}, interhash = {079b2507ddfd237d774f5628c7d67c65}, intrahash = {8169d58173b5f9e98770028d88388844}, journal = {Phys. Rev. B}, keywords = {a}, month = {02}, number = 7, numpages = {6}, pages = 075123, publisher = {American Physical Society}, timestamp = {2024-02-27T20:50:41.000+0100}, title = {Nodal semimetals in d$\ensuremath{\ge}$3 to sharp pseudo-Landau levels by dimensional reduction}, url = {https://link.aps.org/doi/10.1103/PhysRevB.109.075123}, volume = 109, year = 2024 }