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      Observation of chiral zero mode in inhomogeneous three-dimensional Weyl metamaterials

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          Abstract

          Owing to the chirality of Weyl nodes, the Weyl systems can support one-way chiral zero modes under a strong magnetic field, which leads to nonconservation of chiral currents—the so-called chiral anomaly. Although promising for robust transport of optical information, the zero chiral bulk modes have not been observed in photonics. Here we design an inhomogeneous Weyl metamaterial in which a gauge field is generated for the Weyl nodes by engineering the individual unit cells. We experimentally confirm the presence of the gauge field and observe the zero-order chiral Landau level with one-way propagation. Without breaking the time-reversal symmetry, our system provides a route for designing an artificial magnetic field in three-dimensional photonic Weyl systems and may have potential for device applications in photonics.

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          Topological photonics

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            Strain-induced pseudo-magnetic fields greater than 300 tesla in graphene nanobubbles.

            Recent theoretical proposals suggest that strain can be used to engineer graphene electronic states through the creation of a pseudo-magnetic field. This effect is unique to graphene because of its massless Dirac fermion-like band structure and particular lattice symmetry (C3v). Here, we present experimental spectroscopic measurements by scanning tunneling microscopy of highly strained nanobubbles that form when graphene is grown on a platinum (111) surface. The nanobubbles exhibit Landau levels that form in the presence of strain-induced pseudo-magnetic fields greater than 300 tesla. This demonstration of enormous pseudo-magnetic fields opens the door to both the study of charge carriers in previously inaccessible high magnetic field regimes and deliberate mechanical control over electronic structure in graphene or so-called "strain engineering."
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              Energy gaps and a zero-field quantum Hall effect in graphene by strain engineering

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                Author and article information

                Journal
                Science
                Science
                American Association for the Advancement of Science (AAAS)
                0036-8075
                1095-9203
                January 10 2019
                January 11 2019
                January 10 2019
                January 11 2019
                : 363
                : 6423
                : 148-151
                Article
                10.1126/science.aau7707
                30630925
                ebf935c5-6de3-47d5-b85a-957938aeb6ee
                © 2019

                http://www.sciencemag.org/about/science-licenses-journal-article-reuse

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