# Chiral Topological Semimetal with Multifold Band Crossings and Long   Fermi arcs

**Authors:** Niels B. M. Schr\"oter, Ding Pei, Maia G. Vergniory, Yan Sun, Kaustuv, Manna, Fernando de Juan, Jonas. A. Krieger, Vicky S\"uss, Marcus Schmidt,, Pavel Dudin, Barry Bradlyn, Timur K. Kim, Thorsten Schmitt, Cephise Cacho,, Claudia Felser, Vladimir N. Strocov, and Yulin Chen

arXiv: 1812.03310 · 2020-03-26

## TL;DR

This paper reports the discovery of a chiral topological semimetal, AlPt, hosting multifold fermions with high Chern numbers, resulting in long Fermi arcs and novel topological phenomena, confirmed through experimental imaging.

## Contribution

It introduces AlPt as a new chiral topological semimetal with multifold fermions and long Fermi arcs, expanding the understanding of topological materials without mirror symmetry.

## Key findings

- AlPt hosts fourfold and sixfold fermions with high Chern numbers.
- Long Fermi arcs span the full diagonal of the surface Brillouin zone.
- Experimental imaging reveals the dispersion and handedness of Fermi arcs.

## Abstract

Topological semimetals in crystals with a chiral structure (which possess a handedness due to a lack of mirror and inversion symmetries) are expected to display numerous exotic physical phenomena, including fermionic excitations with large topological charge [1], long Fermi arc surface states [2,3], unusual magnetotransport [4] and lattice dynamics [5], as well as a quantized response to circularly polarized light [6]. To date, all experimentally confirmed topological semimetals exist in crystals that contain mirror operations, meaning that these properties do not appear. Here, we show that AlPt is a structurally chiral topological semimetal that hosts new fourfold and sixfold fermions, which can be viewed as a higher spin eneralization of Weyl fermions without equivalence in elementary particle physics. These multifold fermions are located at high symmetry points and have Chern numbers larger than those in Weyl semimetals, thus resulting in multiple Fermi arcs that span the full diagonal of the surface Brillouin zone. By imaging these long Fermi arcs, we experimentally determine the magnitude and sign of their Chern number, allowing us to relate their dispersion to the handedness of their host crystal.

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Source: https://tomesphere.com/paper/1812.03310