Revolutionizing Electronics and Technological Interventions in Semiconductor Devices

Semiconductor devices are the backbone of modern technology, and their development is crucial to the electronics industry's rapid pace of change. Semiconductor devices play an essential role in modern electronic systems, from integrated circuits to transistors. Their efficiency and reliability...

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Bibliographic Details
Published in2023 International Conference on Emerging Research in Computational Science (ICERCS) pp. 1 - 6
Main Authors Shabu, L. Jany, Refonaa, J., Poornima, D., Baron Sam, K B., Priyadharshini, M S.
Format Conference Proceeding
LanguageEnglish
Published IEEE 07.12.2023
Subjects
Electronics
Heterogeneous Integration
Quantum
Quantum computing
Renewable energy sources
Scientific computing
Semiconductor devices
Smart cities
Technological Interventions
Telecommunications
Transistors
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Summary:Semiconductor devices are the backbone of modern technology, and their development is crucial to the electronics industry's rapid pace of change. Semiconductor devices play an essential role in modern electronic systems, from integrated circuits to transistors. Their efficiency and reliability are crucial to the functionality of electronic gadgets and to the quality of life of their users. It is impossible to overestimate the significance of the revolution in semiconductor devices and the impact it will have on many other sectors, including the telecommunications, computer, renewable energy, and healthcare industries. Physical miniaturization constraints, heat dissipation, power consumption, and environmental concerns are among the majority of the issues that the semiconductor business must contend with. Resolving these issues is critical for keeping Moore's Law alive and expanding the capabilities of electronic gadgets. The present research proposes a unique technique called Quantum-Enhanced Heterogeneous Integration for Semiconductor Devices (Q-HISD), which makes use of novel materials, state-of-the-art manufacturing processes, and quantum technologies. The method prioritizes research into unusual approaches to computing, such as quantum computing, while simultaneously fostering the development of smaller, faster, and more energy-efficient semiconductor devices (E-ESD). High-capacity data storage solutions, powerful sensors for Internet of Things Applications, and rapid quantum processors are all examples. Autonomous vehicles, smart cities, medical diagnostics, and many more fields will be affected. Evaluation and performance prediction of the offered methods rely heavily on simulation and modeling. The potential benefits in speed, power efficiency, and reliability that can be realized through the use of innovative semiconductor devices are explored in this paper through comprehensive simulation research.
DOI:10.1109/ICERCS57948.2023.10434125