In the field of composite materials, mechanics/acoustics wave regulation is a very active research direction, which aims to achieve fine control of mechanical and acoustic properties by accurately designing and adjusting the structure of composites. The core of mechanics wave regulation is to change the mechanical properties of materials by adjusting the structural level, fiber direction and component ratio of the composite structure, so as to meet the requirements of strength, stiffness and toughness in different applications. In the aspect of acoustics wave regulation, the propagation velocity, absorption characteristics and scattering behavior of sound waves in the composite structure can be adjusted by carefully designing the microstructure of the material, so as to optimize its acoustic performance. These studies are not only of great significance for improving the overall properties of materials, but also provide new possibilities for the fields of lightweight structure, efficient energy transfer and acoustic isolation, and promote the innovation of composite structure in engineering and technological applications.
The topic of this study is "Mechanics/Acoustics wave regulation in composite structure". It is devoted to the precise control of the mechanical and acoustic properties of composite structures through the regulation of fine mechanical / acoustic fluctuations of composite structures. Through in-depth research, careful design and customization of the microstructure of composites, we aim to address the challenges in engineering applications, with particular attention to key areas such as lightweight, efficient energy transfer and acoustic isolation. The long-term goal of this research is to promote the continuous development of engineering materials science, provide innovative solutions, further promote the wide application of composite structures in the fields of engineering and technology, make key contributions to the sustainable development in the future.
This Research Topic aims to explore the field of multifunctional regulation of composite structures for engineering applications, with emphasis on the field of mechanics and acoustics wave regulation.We invite submissions that explore the following topics in depth:
• Acoustic absorption/insulation metamaterials: Explore new mechanisms of absorption/insulation, optimize microstructure design, etc., to achieve low frequency, large bandwidth and efficient absorption/insulation.
• Acoustic black hole wave regulation: Research focuses on using thickness reduction to reduce bending wave velocity for lightweight, broadband and efficient wave control.
• Elastic wave metasurface: The research focuses on the rational design of elastic wave metasurface to realize the effective control of directional transmission, asymmetric transmission, focusing and absorption of bending waves.
• Capture/storage mechanic/acoustic metamaterials: Explore the performance of mechanic /acoustic metamaterials in energy capture and energy storage, and realize the recycling of mechanic/acoustic energy.
• Intelligent Active control of mechanic/acoustic metamaterials: Explore the intelligent active tunable design of mechanic/acoustic metamaterials for more flexible adaptability and tunability.
Important Note:
All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.
In the field of composite materials, mechanics/acoustics wave regulation is a very active research direction, which aims to achieve fine control of mechanical and acoustic properties by accurately designing and adjusting the structure of composites. The core of mechanics wave regulation is to change the mechanical properties of materials by adjusting the structural level, fiber direction and component ratio of the composite structure, so as to meet the requirements of strength, stiffness and toughness in different applications. In the aspect of acoustics wave regulation, the propagation velocity, absorption characteristics and scattering behavior of sound waves in the composite structure can be adjusted by carefully designing the microstructure of the material, so as to optimize its acoustic performance. These studies are not only of great significance for improving the overall properties of materials, but also provide new possibilities for the fields of lightweight structure, efficient energy transfer and acoustic isolation, and promote the innovation of composite structure in engineering and technological applications.
The topic of this study is "Mechanics/Acoustics wave regulation in composite structure". It is devoted to the precise control of the mechanical and acoustic properties of composite structures through the regulation of fine mechanical / acoustic fluctuations of composite structures. Through in-depth research, careful design and customization of the microstructure of composites, we aim to address the challenges in engineering applications, with particular attention to key areas such as lightweight, efficient energy transfer and acoustic isolation. The long-term goal of this research is to promote the continuous development of engineering materials science, provide innovative solutions, further promote the wide application of composite structures in the fields of engineering and technology, make key contributions to the sustainable development in the future.
This Research Topic aims to explore the field of multifunctional regulation of composite structures for engineering applications, with emphasis on the field of mechanics and acoustics wave regulation.We invite submissions that explore the following topics in depth:
• Acoustic absorption/insulation metamaterials: Explore new mechanisms of absorption/insulation, optimize microstructure design, etc., to achieve low frequency, large bandwidth and efficient absorption/insulation.
• Acoustic black hole wave regulation: Research focuses on using thickness reduction to reduce bending wave velocity for lightweight, broadband and efficient wave control.
• Elastic wave metasurface: The research focuses on the rational design of elastic wave metasurface to realize the effective control of directional transmission, asymmetric transmission, focusing and absorption of bending waves.
• Capture/storage mechanic/acoustic metamaterials: Explore the performance of mechanic /acoustic metamaterials in energy capture and energy storage, and realize the recycling of mechanic/acoustic energy.
• Intelligent Active control of mechanic/acoustic metamaterials: Explore the intelligent active tunable design of mechanic/acoustic metamaterials for more flexible adaptability and tunability.
Important Note:
All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.