Atomically precise manufacturing (APM) is a key technique that involves the direct control of
atoms in order to manufacture products or components of products. It has been developed …

Because of recent technological developments, such as Internet of Things (IoT) devices,
power consumption has become a major issue. Atomic silicon quantum dot (ASiQD) is one …

In this manuscript, we first suggest a single-layer 2: 1 QCA MUX with an ultra-low number of
cells and high speed. Unlike existing designs, the output of the proposed design does not …

Field-coupled Nanocomputing (FCN) defines a class of post-CMOS nanotechnologies that
promises compact layouts, low power operation, and high clock rates. Recent breakthroughs …

Area overhead and energy consumption continue to dominate the scalability issues of
modern digital circuits. In this context, atomic silicon and reversible logic have emerged as …

Quantum-dot cellular automata (QCA) is a domain coupling nano-technology that has drawn
significant attention for less power consumption, area, and design overhead. It is able to …

The Silicon Dangling Bond (SiDB) logic platform, an emerging computational beyond-CMOS
nanotechnology, is a promising competitor due to its ability to achieve integration density …

Silicon Dangling Bonds have established themselves as a promising competitor in the field
of beyond-CMOS technologies. Their integration density and potential for energy dissipation …

Silicon Dangling Bonds (SiDBs) on the hydrogen-passivated silicon surface have emerged
as a promising competitor in the realm of beyond-CMOS computational technologies. They …

This article proposes a complete 3-input gate library using atomic silicon quantum-dots
made of silicon dangling bonds (SiDBs). This emerging technology aims to achieve ultralow …