AI Article Synopsis
- The Bloch band theory and Brillouin zone are key concepts in physics that describe wave behavior in periodic structures, crucial for fields like condensed matter and topological physics.
- Recent advances have shown that the traditional 2D Brillouin zone can be transformed into a non-orientable Klein bottle due to artificial gauge fields, but similar investigations for the 3D Brillouin zone were lacking.
- New theoretical and experimental findings reveal that the 3D Brillouin zone can also be altered to exhibit unusual topologies, leading to the discovery of novel symmetries and a unique type of topological insulator, paving the way for new research in topological physics and acoustic wave manipulation.
Article Abstract
The Bloch band theory and Brillouin zone (BZ) that characterize wave-like behaviors in periodic mediums are two cornerstones of contemporary physics, ranging from condensed matter to topological physics. Recent theoretical breakthrough revealed that, under the projective symmetry algebra enforced by artificial gauge fields, the usual two-dimensional (2D) BZ (orientable Brillouin two-torus) can be fundamentally modified to a non-orientable Brillouin Klein bottle with radically distinct manifold topology. However, the physical consequence of artificial gauge fields on the more general three-dimensional (3D) BZ (orientable Brillouin three-torus) was so far missing. Here, we theoretically discovered and experimentally observed that the fundamental domain and topology of the usual 3D BZ can be reduced to a non-orientable Brillouin Klein space or an orientable Brillouin half-turn space in a 3D acoustic crystal with artificial gauge fields. We experimentally identify peculiar 3D momentum-space non-symmorphic screw rotation and glide reflection symmetries in the measured band structures. Moreover, we experimentally demonstrate a novel stacked weak Klein bottle insulator featuring a nonzero Z topological invariant and self-collimated topological surface states at two opposite surfaces related by a nonlocal twist, radically distinct from all previous 3D topological insulators. Our discovery not only fundamentally modifies the fundamental domain and topology of 3D BZ, but also opens the door towards a wealth of previously overlooked momentum-space multidimensional manifold topologies and novel gauge-symmetry-enriched topological physics and robust acoustic wave manipulations beyond the existing paradigms.
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| http://dx.doi.org/10.1016/j.scib.2024.05.003 | DOI Listing |
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- Recent advances have shown that the traditional 2D Brillouin zone can be transformed into a non-orientable Klein bottle due to artificial gauge fields, but similar investigations for the 3D Brillouin zone were lacking.
- New theoretical and experimental findings reveal that the 3D Brillouin zone can also be altered to exhibit unusual topologies, leading to the discovery of novel symmetries and a unique type of topological insulator, paving the way for new research in topological physics and acoustic wave manipulation.
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