Sustainable Solutions in Sound Shielding: Harnessing Metamaterials for Acoustic Cloaking

¹ Department of Mechanical Engineering, Silver oak college of Engineering and Technology, Silver Oak University, India.
² Hilla University College, Babylon, Iraq.
³ Department of Civil Engineering, IES Institute of Technology and Management, IES University, Bhopal, Madhya Pradesh, India 462044.
⁴ Department of Civil, GRIET, Bachupally, Hyderabad, Telangana, India.
⁵ Department of Information Science Engineering, New Horizon College of Engineering, Bangalore, India.
⁶ Lovely Professional University, Phagwara, India.
⁷ Department of Electronics and Communication Engineering, MLR Institute of Technology, Hyderabad, Telangana, India - 500051

^* Corresponding Author: devendrasingh.me@socet.edu.in

Abstract

The development of metamaterials promises to enable smallscale, worldwide industry-wide acoustic, electromagnetic, mechanical, and solar energy harvesting. Engineered structures surpass natural material limitations, offering capabilities unattainable in traditional counterparts. This paper explores metamaterials' manipulation of acoustic, electromagnetic, mechanical, and solar energy. Mechanical metamaterials convert strain into electrical energy, applicable from interstellar travel to terrestrial infrastructure. Precision-configured acoustic metamaterials efficiently harness dispersed acoustic energy, improving renewable energy methodologies. Integration into photovoltaic cells showcases metamaterials' solar potential, with innovative designs enhancing solar energy conversion efficiency. “Metamaterials” is a word used to describe artificial structures whose properties are based on the aggregate expression of individual components. Acoustic metamaterials are the term used for such constructions intended for the manipulation of acoustic waves. Controlled wave propagation is made possible by acoustic metamaterials, which is frequently not possible with bulk materials created chemically. This indicates that the wave propagation in acoustic metamaterials is directed and produces desired acoustic effects, independent of the mass-density properties of the material. The distinct properties of acoustic metamaterials have paved the way for the creation of practical solutions for a variety of uses, such as passive destructive interference, acoustic cloaking, sound focusing, low-frequency sound insulation, and biomedical acoustics. The kind of sound modification determines the general properties of an acoustic metamaterial. The properties of several of the most promising acoustic metamaterials from passive to active are introduced in this work. In order to achieve a sustainable future, it is necessary to combine environmentally friendly technologies with renewable energy sources for their final application. This is demonstrated by highlighting both the fundamental concepts and the physical models that were assessed.