Kiki Ayu Winarni, Tanti Febrianti, Gede Mudita Edi Putra, Hamdi Akhsan, Ismet Ismet

MAXWELL'S EQUATIONS AND ELECTROMAGNETIC WAVES: SHAPING MODERN TECHNOLOGY

Introduction

Maxwell's equations and electromagnetic waves: shaping modern technology. Investigate how Maxwell's Equations & electromagnetic waves shaped modern technology. This meta-analysis reveals their pivotal role in wireless communication, medical imaging, renewable energy, and more.

Abstract

This meta-analysis investigated how Maxwell's Equations and electromagnetic waves shaped key advances in modern technology. A systematic review was conducted across major academic databases, initially identifying 150 otential sources. Applying predefined inclusion criteria, findings were synthesized from 30 included studies. This synthesis revealed that these foundational concepts shaped technological advancement by providing the essential theoretical framework for understanding electromagnetic wave generation, propagation, and interaction with matter. This understanding was found to be pivotal in enabling breakthroughs across diverse domains identified in the synthesized literature, including Wireless Communication, Microwave Technology, Medical Imaging, Renewable Energy, and Metamaterials, among other related fields. This synthesis provides a comprehensive perspective on the mechanisms by which fundamental electromagnetic theory underpins technological progress. The findings underscore the enduring practical relevance of Maxwell's Equations and electromagnetic waves for research and engineering and offer valuable material for physics education by demonstrating their tangible impact in shaping the modern world.

Review

This meta-analysis, titled "MAXWELL'S EQUATIONS AND ELECTROMAGNETIC WAVES: SHAPING MODERN TECHNOLOGY," presents a timely and important investigation into the foundational role of Maxwell's Equations and electromagnetic waves in driving modern technological advancements. The authors employed a systematic review methodology, scrutinizing 150 initial sources from major academic databases and synthesizing findings from 30 ultimately included studies. This rigorous approach lends significant credibility to the endeavor, aiming to provide a robust and comprehensive overview of how these core principles have concretely shaped the technological landscape. The synthesis reveals that these foundational concepts are critical because they provide the essential theoretical framework for understanding electromagnetic wave generation, propagation, and interaction with matter. This understanding, as the paper demonstrates, has been pivotal in enabling breakthroughs across an impressive array of domains, including Wireless Communication, Microwave Technology, Medical Imaging, Renewable Energy, and Metamaterials. The work effectively elucidates the mechanisms by which fundamental electromagnetic theory underpins and enables progress in such diverse and critical fields, offering a comprehensive perspective on its widespread impact. The paper successfully underscores the enduring practical relevance of Maxwell's Equations and electromagnetic waves for ongoing research and engineering. Furthermore, it highlights the significant value of its findings for physics education, demonstrating the tangible impact of these theories in shaping the modern world. By consolidating a broad spectrum of evidence, this meta-analysis provides a compelling testament to the power of fundamental physics in driving innovation. It stands as an excellent resource for researchers, educators, and students alike, offering a holistic view of the profound and continuing influence of electromagnetism on society.

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