An Energy-Aware Nanoscale Design of Reversible Atomic Silicon Based on Miller Algorithm
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Date
2023
Authors
Ahmadpour, Seyed-Sajad
Jafari Navimipour, Nima
Bahar, Ali Nawaz
Mosleh, Mohammad
Yalcin, Senay
Journal Title
Journal ISSN
Volume Title
Publisher
IEEE-Inst Electrical Electronics Engineers Inc
Open Access Color
Green Open Access
No
OpenAIRE Downloads
OpenAIRE Views
Publicly Funded
No
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Impulse
Top 10%
Influence
Average
Popularity
Top 10%
Abstract
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 suitable alternatives to address both issues. In this article, the authors propose novel nano-scale circuit design with low area and energy overheads using the same. In particular, the authors propose a reversible gate with Miller algorithm and atomic silicon technology. This article is extremely relevant in todays era, when the world is moving toward low area and low energy circuits for use in edge devices.
Description
Keywords
Logic gates, Silicon, Adders, Costs, Capacitance-voltage characteristics, Qubit, Energy consumption, Digital circuits, Scalability, Quantum-Dot, Nanoscale devices, Atomic Silicon, Reversible logic, Simulation, Nanotechnology, Miller algorithm, Quantum-Dot, Flip-flop, Simulation, Full-Adder (FA), Silicon, Flip-flop, Capacitance-voltage characteristics, Scalability, Logic gates, Digital circuits, Quantum-Dot, Costs, Full-Adder (FA), Energy consumption, Nanoscale devices, Reversible logic, Nanotechnology, Miller algorithm, Qubit, Atomic Silicon, Adders, Simulation
Fields of Science
02 engineering and technology, 01 natural sciences, 0103 physical sciences, 0210 nano-technology
Citation
WoS Q
Q3
Scopus Q
Q2
OpenCitations Citation Count
15
Source
Ieee Design & Test
Volume
40
Issue
5
Start Page
62
End Page
69
PlumX Metrics
Citations
CrossRef : 2
Scopus : 19
Captures
Mendeley Readers : 3
SCOPUS™ Citations
19
checked on Feb 21, 2026
Web of Science™ Citations
18
checked on Feb 21, 2026
Page Views
9
checked on Feb 21, 2026
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