First proposed in 2008, spin-gapless semiconductors offer both ultrafast and ultra-low energy electrical conduction. Now, a University of Wollongong team has published an extensive review of spin-gapless semiconductors (SGSs), a new class of zero gap materials which have fully spin polarized electrons and holes.
The study tightens the search for materials that would allow for “spintronic” electronics with no wasted dissipation of energy from electrical conduction.
Their defining property of SGS materials relates to their “bandgap,” the gap between the material’s valence and conduction bands, which defines their electronic properties.
In general, one spin channel (i.e. one of the spin directions, up or down) is semiconducting with a finite band gap, while the other spin channel has a closed (zero) band gap.
In a spin-gapless semiconductor (SGS), conduction and valence band edges touch in one spin channel, and no threshold energy is required to move electrons from occupied (valence) states to empty (conduction) states.
This property gives these materials unique properties: their band structures are extremely sensitive to external influences (e.g. pressure or magnetic field).
Most of the SGS materials are all ferromagnetic materials with high Curie temperatures.
The band structures of the SGSs can have two types of energy-momentum dispersions: Dirac (linear) dispersion or parabolic dispersion.
The new review investigates both Dirac and the three sub-types of parabolic SGSs in different material systems.
For Dirac type SGS, their electron mobility is two to four orders of magnitude higher than in classical semiconductors. Very little energy is needed to excite electrons in an SGS, charge concentrations are very easily “tunable.” For example, this can be done by introducing a new element (doping) or by application of a magnetic or electric field (gating).
The Dirac type spin gapless semiconductors exhibit fully spin polarized Dirac cones and offer a platform for spintronics and low-energy consumption electronics via dissipationless edge states driven by the quantum anomalous Hall effect.
“Potential applications of SGSs in next-generation spintronic devices are outlined, along with low-electronics, and optoelectronics with high speed and low energy consumption,” said Professor Xiaolin Wang, Director of Institute for Superconducting and Electronic Materials, UoW and the theme leader of FLEET.
Since spin-gapless semiconductors (SGSs) were first proposed by Professor Xiaolin Wang in 2008, efforts worldwide to find suitable candidate materials have particularly focussed on Dirac type SGSs.
In the past decade, a large number of Dirac or parabolic type SGSs have been predicted by density functional theory, and some parabolic SGSs have been experimentally demonstrated in both monolayer and bulk materials.