β-Ga2O3 thin-channel metal-oxide-semiconductor field-effect transistors (MOSFETs) were evaluated using both DC and pulsed I-V measurements. The reported pulsed I-V technique was used to study self-heating effects in the MOSFET channel. The device was analyzed over a large temperature range of 23 to 200°C. A relationship between dissipated power and channel temperature was established, and it was found that the MOSFET channel was heating up to 208°C when dissipating 2.5 W/mm of power. The thermal resistance of the channel was found to be 73°C-mm/W. The results are supported with experimental Raman nano-thermography and thermal simulations and are in excellent agreement with pulsed I-V findings. The high thermal resistance underpins the importance of optimizing thermal management in future Ga2O3 devices.
While
heterostructures are ubiquitous tools enabling
new physics
and device functionalities, the palette of available materials has
never been richer. Combinations of two emerging material classes,
two-dimensional materials and topological materials, are particularly
promising because of the wide range of possible permutations that
are easily accessible. Individually, both graphene and Pb1-xSnxTe (PST) are widely investigated for spintronic applications
because graphene’s high carrier mobility and PST’s topologically
protected surface states are attractive platforms for spin transport.
Here, we combine monolayer graphene with PST and demonstrate a hybrid
system with properties enhanced relative to the constituent parts.
Using magnetotransport measurements, we find carrier mobilities up
to 20 000 cm2/(V s) and a magnetoresistance approaching
100%, greater than either material prior to stacking. We also establish
that there are two distinct transport channels and determine a lower
bound on the spin relaxation time of 4.5 ps. The results can be explained
using the polar catastrophe model, whereby a high mobility interface
state results from a reconfiguration of charge due to a polar/nonpolar
interface interaction. Our results suggest that proximity induced
interface states with hybrid properties can be added to the still
growing list of behaviors in these materials.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.