Investigating Analogue Gravity Phenomena through Electronic Black Holes: A Study

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Volume: 12 | Issue: 01 | Year 2026 | Subscription
International Journal of Microwave Engineering and Technology
Received Date: 04/18/2026
Acceptance Date: 05/07/2026
Published On: 2026-05-14
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By: Dr. Kazi Kutubuddin Sayyad Liyakat and Heena Tajoddin Shaikh.

1 Assistant Professor, 2 Professor and Head,
1,2 Department of Electronics and Telecommunication Engineering, Brahmdevdada Mane Institute of Technology, Solapur, Maharashtra, India

Abstract

The universe, in its grand cosmic ballet, is replete with mysteries, and among the most profound are the enigmatic black holes. These celestial behemoths, born from the collapse of massive stars, warp spacetime to such an extent that nothing, not even light, can escape their gravitational embrace. Their behavior, governed by Einstein’s theory of General Relativity, pushes the boundaries of our understanding, presenting phenomena like Hawking radiation – a quantum whisper escaping the event horizon, defying classical intuition. The concept of an “electronic black hole” (EBH) represents a fascinating interdisciplinary bridge between astrophysics and condensed matter physics, offering a terrestrial analogue for cosmic singularities. Unlike their gravitational counterparts, EBHs are meticulously engineered material systems (e.g., advanced semiconductors, metamaterials, or quantum dots) designed to create a region where electrons or their associated energy waves (like phonons or plasmons) are irreversibly absorbed, trapped, or channeled, preventing reflection. This paper explores the theoretical underpinnings and practical implications of EBHs, highlighting their defining characteristics: unidirectional energy flow, near-perfect absorption, and suppression of reflection. Potential applications span highly efficient energy harvesting, advanced thermal management, electromagnetic stealth, and even as platforms for exploring analogue gravity phenomena like Hawking radiation at accessible scales. While significant challenges remain in optimizing efficiency, scalability, and precise control, EBHs represent an active and promising research frontier with the potential to revolutionize our command over energy at the nanoscale.
Keywords : – Black Hole, Electronics, Artificial Intelligence, Absorption, Electromagnetic,
Unidirectional energy flow.

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How to cite this article: Dr. Kazi Kutubuddin Sayyad Liyakat and Heena Tajoddin Shaikh Investigating Analogue Gravity Phenomena through Electronic Black Holes: A Study. International Journal of Microwave Engineering and Technology. 2026; 12(01): -p.

How to cite this URL: Dr. Kazi Kutubuddin Sayyad Liyakat and Heena Tajoddin Shaikh, Investigating Analogue Gravity Phenomena through Electronic Black Holes: A Study. International Journal of Microwave Engineering and Technology. 2026; 12(01): -p. Available from:https://journalspub.com/publication/ijmet/article=25539

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