Field-effect transistors based on two-dimensional (2D) materials have the potential to be
used in very large-scale integration (VLSI) technology, but whether they can be used at the …

Abstract Two-dimensional (2D) semiconductors have attracted tremendous interest as
atomically thin channels that could facilitate continued transistor scaling. However, despite …

For ultra-scaled technology nodes at channel lengths below 12 nm, two-dimensional (2D)
materials are a potential replacement for silicon since even atomically thin 2D …

Abstract Two-dimensional (2D) materials could potentially be used to develop advanced
monolithic integrated circuits. However, despite impressive demonstrations of single devices …

The shrinking of transistors has hit a wall of material degradation and the specialized
electronic applications for complex scenarios have raised challenges in heterostructures …

During the past decade, two-dimensional materials have attracted incredible interest from
the electronic device community. The first two-dimensional material studied in detail was …

The primary challenge facing silicon-based electronics, crucial for modern technological
progress, is difficulty in dimensional scaling. This stems from a severe deterioration of …

Two-dimensional (2D) semiconductors could be used to build advanced 3D chips based on
monolithic 3D integration. But challenges related to growing single-crystalline materials at …

Abstract 2D semiconductors have emerged both as an ideal platform for fundamental
studies and as promising channel materials in beyond‐silicon field‐effect‐transistors due to …

Two dimensional (2D) semiconductors have been established as promising candidates to
break through the short channel effect that existed in Si metal-oxide-semiconductor field …