Affiliation:
1. Institute for Superconducting and Electronic Materials (ISEM) Faculty of Engineering and Information Sciences (EIS) University of Wollongong Wollongong New South Wales 2525 Australia
2. ARC Centre of Excellence in Future Low‐Energy Electronics Technologies (FLEET) University of Wollongong Wollongong New South Wales 2525 Australia
Abstract
AbstractQuantum materials, with nontrivial quantum phenomena and mechanisms, promise efficient quantum technologies with enhanced functionalities. Quantum technology is held back because a gap between fundamental science and its implementation is not fully understood yet. In order to capitalize the quantum advantage, a new perspective is required to figure out and close this gap. In this review, spin gapless quantum materials, featured by fully spin‐polarized bands and the electron/hole transport, are discussed from the perspective of fundamental understanding and device applications. Spin gapless quantum materials can be simulated by minimal two‐band models and could help to understand band structure engineering in various topological quantum materials discovered so far. It is explicitly highlighted that various types of spin gapless band dispersion are fundamental ingredients to understand quantum anomalous Hall effect. Based on conventional transport in the bulk and topological transport on the boundaries, various spintronic device aspects of spin gapless quantum materials as well as their advantages in different models for topological field effect transistors are reviewed.