This is an unedited manuscript accepted for publication and provided as an Article in Press for early access at the author’s request. The article will undergo copyediting, typesetting, and galley proof review before final publication. Please be aware that errors may be identified during production that could affect the content. All legal disclaimers of the journal apply.
V. Basil Hans,
- Professor, SRINIVAS UNIVERSITY , PANDESHWAR, MANGALORE, Karnataka, India
Abstract
Microwave energy—300 MHz to 300 GHz electromagnetic radiation—is essential to modern science and technology. Its applications include telecommunications, medicine, industrial processing, and renewable energy, despite its association with kitchen appliances. Microwave energy generation, transmission, and material interaction are covered in this article. It emphasises wireless communication, radar, medical therapies, and microwave- assisted chemical processes. The study also discusses microwave-based power transfer and improved material processing. Microwave energy is efficient, fast, and precise, yet safety, energy loss, and technology restrictions are issues. This article emphasises microwave energy’s growing importance as a potent and adaptable instrument affecting science and engineering by understanding its capabilities and restrictions.
Keywords: The microwave radiation , EM Spectrum, Dielectric Heating, A wireless connection , Industry Applications
V. Basil Hans. Potential, Principles, and Applications of Microwave Energy. Journal of Microwave Engineering and Technologies. 2026; 13(01):-.
V. Basil Hans. Potential, Principles, and Applications of Microwave Energy. Journal of Microwave Engineering and Technologies. 2026; 13(01):-. Available from: https://journals.stmjournals.com/jomet/article=2026/view=242367
References
1. Microwave Assisted Technology in Pharma: Function and Role. 2019. DOI: 10.22270/jddt.v9i3.2616 Vol. Volume 9, Issue 3, May-June 2019
2. Yang M, Huang H, Huang S, Deng X. Discover how microwave heating modifies the structure, characteristics, and activities of novel dietary macromolecular nutrients. 2022. ncbi.nlm.nih.gov
3. Heat transfer in microwave heating”, Dissertation, Michigan Technological University, 2012. https://doi.org/10.37099/mtu.dc.etds/17
4. Review of Cherenkov radiation-based high-power vacuum tube microwave sources. 2020. https://arxiv.org/abs/2003.04288
5. Early microwave radiation biology research: 1940?1960. 1980. Annals of Science
6. DJEDDI TAREK. High-Power Radar System Digitally Controlled Microwave Components. 2018. A thesis in electrical and computer engineering presented in partial fulfilment of the Master of Applied Sciences requirements at Concordia University Montreal, Quebec, Canada.
7. Casper M. Modulated Scatterer Concept Evaluation Radar Testbed Characterisation. 2010. kuscholarworks.ku.edu
8. Food-treatment solid-state microwave processor. 2019. Food-treatment solid-state microwave processor. 2019. Food-treatment solid-state microwave processor. 2019.
9. Microwave Radiation and the Brain: Mechanisms, Status, and Prospects. 2022. ncbi.nlm.nih.gov
10. Wang N, Zou W, Li X, Liang Y. Microwave nonthermal effects in chemistry and materials science: study and application. 2022. ncbi.nlm.nih.gov
11. In microwave radiation-induced biological impacts investigations, damage models are established. 2021. ncbi.nlm.nih.gov
12. Microwave photonics: present challenges to widespread application. Opt Express. 2013 Sep 23;21(19):22862-7. 10.1364/OE.21.022862. PMID: 24104173.
Journal of Microwave Engineering and Technologies
| Volume | 13 |
| 01 | |
| Received | 29/04/2026 |
| Accepted | 30/04/2026 |
| Published | 30/04/2026 |
| Publication Time | 1 Days |
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