TY - JOUR
T1 - Type-III and Tilted Dirac Cones Emerging from Flat Bands in Photonic Orbital Graphene
AU - Milićević, M.
AU - Montambaux, G.
AU - Ozawa, T.
AU - Jamadi, O.
AU - Real, B.
AU - Sagnes, I.
AU - Lemaître, A.
AU - Le Gratiet, L.
AU - Harouri, A.
AU - Bloch, J.
AU - Amo, A.
N1 - Funding Information:
This work was supported by the ERC grant Honeypol, the EU-FET Proactive grant AQuS, the Quantera grant Inerpol, the FETFLAG grant PhoQus, the French National Research Agency (ANR) project Quantum Fluids of Light (ANR-16-CE30-0021), the Labex CEMPI (ANR-11-LABX-0007) and NanoSaclay (ICQOQS, Grant No. ANR-10-LABX-0035), the French RENATECH network, the CPER Photonics for Society P4S, the I-Site ULNE via the project NONTOP and the Métropole Européenne de Lille via the project TFlight. T. O. acknowledges support from JSPS KAKENHI Grant No. JP18H05857, RIKEN Incentive Research Project, and the Interdisciplinary Theoretical and Mathematical Sciences Program (iTHEMS) at RIKEN.
Publisher Copyright:
© 2019 authors. Published by the American Physical Society.
PY - 2019/7/23
Y1 - 2019/7/23
N2 - The extraordinary electronic properties of Dirac materials, the two-dimensional partners of Weyl semimetals, arise from the linear crossings in their band structure. When the dispersion around the Dirac points is tilted, one can predict the emergence of intricate transport phenomena such as modified Klein tunneling, intrinsic anomalous Hall effects, and ferrimagnetism. However, Dirac materials are rare, particularly with tilted Dirac cones. Recently, artificial materials whose building blocks present orbital degrees of freedom have appeared as promising candidates for the engineering of exotic Dirac dispersions. Here we take advantage of the orbital structure of photonic resonators arranged in a honeycomb lattice to implement photonic lattices with semi-Dirac, tilted, and, most interestingly, type-III Dirac cones that combine flat and linear dispersions. Type-III Dirac cones emerge from the touching of a flat and a parabolic band when synthetic photonic strain is introduced in the lattice, and they possess a nontrivial topological charge. This photonic realization provides a recipe for the synthesis of orbital Dirac matter with unconventional transport properties and, in combination with polariton nonlinearities, opens the way to study Dirac superfluids in topological landscapes.
AB - The extraordinary electronic properties of Dirac materials, the two-dimensional partners of Weyl semimetals, arise from the linear crossings in their band structure. When the dispersion around the Dirac points is tilted, one can predict the emergence of intricate transport phenomena such as modified Klein tunneling, intrinsic anomalous Hall effects, and ferrimagnetism. However, Dirac materials are rare, particularly with tilted Dirac cones. Recently, artificial materials whose building blocks present orbital degrees of freedom have appeared as promising candidates for the engineering of exotic Dirac dispersions. Here we take advantage of the orbital structure of photonic resonators arranged in a honeycomb lattice to implement photonic lattices with semi-Dirac, tilted, and, most interestingly, type-III Dirac cones that combine flat and linear dispersions. Type-III Dirac cones emerge from the touching of a flat and a parabolic band when synthetic photonic strain is introduced in the lattice, and they possess a nontrivial topological charge. This photonic realization provides a recipe for the synthesis of orbital Dirac matter with unconventional transport properties and, in combination with polariton nonlinearities, opens the way to study Dirac superfluids in topological landscapes.
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U2 - 10.1103/PhysRevX.9.031010
DO - 10.1103/PhysRevX.9.031010
M3 - Article
AN - SCOPUS:85074430216
SN - 2160-3308
VL - 9
JO - Physical Review X
JF - Physical Review X
IS - 3
M1 - 031010
ER -