Dirac Cone Protected by Non-Symmorphic Symmetry and 3D Dirac Line Node in ZrSiS (1509.00861v1)

Abstract: Materials harboring exotic quasiparticles, such as Dirac and Weyl fermions\cite{xu2015discovery,borisenko2015time,weng2015weyl,xu2015observation}, have garnered much attention from the physics and material science communities. These fermions are massless and, in some materials, have shown exceptional physical properties such as ultrahigh mobility and extremely large magnetoresistances \cite{liang2015ultrahigh,ali2014large,du2015unsaturated,shekhar2015large}. Recently, new materials have been predicted to exist which exhibit line nodes of Dirac cones \cite{PhysRevLett.115.036806,xie2015new,burkov2011topological,rhim2015landau}. Here, we show with angle resolved photoemission studies supported by \textit{ab initio} calculations that the highly stable, non-toxic and earth-abundant material, ZrSiS, has an electronic band structure that hosts several Dirac cones which form a Fermi surface with a diamond-shaped line of Dirac nodes. We also experimentally show, for the first time, that the square Si lattice in ZrSiS is an excellent template for realizing the new types of 2D Dirac cones recently predicted by Young and Kane \cite{young2015dirac} and image an unforseen surface state that arises close to the 2D Dirac cone. Finally, we find that the energy range of the linearly dispersed bands is as high as 2\,eV above and below the Fermi level; much larger than of any known Dirac material so far. This makes ZrSiS a very promising candidate to study the exotic behavior of Dirac electrons, or Weyl fermions if a magnetic field is applied, as well as the properties of lines of Dirac nodes

• The paper demonstrates that ZrSiS hosts multiple Dirac crossings with linear dispersion extending up to 2 eV.
• It applies ARPES and ab initio calculations to confirm non-symmorphic symmetry protection and unexpected surface states.
• The study reveals minimal SOC-induced gaps, highlighting ZrSiS's potential for future electronic and device applications.

An Analysis of Dirac Cones and 3D Dirac Line Nodes in ZrSiS

The paper of materials hosting exotic quasiparticles such as Dirac and Weyl fermions remains a key area in condensed matter physics. These materials demonstrate remarkable electronic properties, such as high mobility and large magnetoresistance, driven by their unique electronic band structures. The paper entitled "Dirac Cone Protected by Non-Symmorphic Symmetry and 3D Dirac Line Node in ZrSiS," authored by Schoop et al., presents a detailed investigation into the electronic structure of ZrSiS, a material that exemplifies these characteristics.

Summary and Methodology

The authors utilize angle-resolved photoemission spectroscopy (ARPES) and ab initio calculations to examine ZrSiS, focusing on its capacity to host Dirac fermions. They identify the presence of multiple Dirac cones within the Brillouin zone, creating a distinctive Fermi surface characterized by a diamond-shaped line of Dirac nodes. The analysis reveals that ZrSiS maintains linear band dispersion over a wide energy range, up to 2 eV above and below the Fermi level. This is notably larger than that observed in other Dirac materials, which typically exhibit much smaller ranges.

The paper also confirms, through experimental verification, the prediction by Young and Kane regarding two-dimensional Dirac cones in 2D square lattices protected by non-symmorphic symmetry. The team discovers an unforeseen surface state that is closely associated with the 2D Dirac cone. Additionally, they note that spin-orbit coupling (SOC) effects introduce a minimal gap (approximately 20 meV) in the Dirac cones near the Fermi surface, which is significantly less than observed in related bismuth-based compounds.

Key Findings

• ZrSiS hosts several Dirac crossings, contributing to a diamond-shaped Fermi surface without intervention by other bands. This, in combination with the non-toxic and stable nature of the material, renders ZrSiS an ideal candidate for in-depth exploration of Dirac and Weyl fermions.
• The energy range of ZrSiS's linear band dispersion is significantly broader than in other known Dirac materials. This allows for easier examination of Dirac and Weyl physics across various Fermi level perturbations.
• Experimentally, using ARPES, the paper confirms the presence of Dirac cones, including the non-symmorphic symmetry-protected 2D Dirac features, reinforcing theoretical predictions.

Implications and Future Directions

The discovery of ZrSiS as a host for robust Dirac fermions offers several implications for the future of material science and condensed matter physics. Practically, the large energy range for linear dispersion in ZrSiS facilitates applied research into device fabrication, particularly semiconductor technologies where electronic properties are pivotal.

The paper prompts further investigation into the complex interplay of surface states and bulk electronic structure, especially around the X point in the Brillouin zone where hybridization is observed. Given the reduced SOC in ZrSiS compared to other Dirac materials, it presents an opportunity to explore Dirac physics in a less perturbed electronic context. Future studies could explore the effects of doping or external fields to modulate the electronic properties of ZrSiS further.

In conclusion, Schoop et al.'s work contributes significantly to the understanding of Dirac semimetals, with ZrSiS being a promising subject for future theoretical and experimental efforts aimed at harnessing the unique properties of Dirac and Weyl fermions.