Wave Manipulation in Intelligent Metamaterials: Recent Progress and Prospects

Metamaterials (MMs), which include phononic crystals (PCs) as a particular type, exhibit anomalous wave propagation properties through artificial design of topologies or lattice forms of unit-cells. Recent advancements in MMs signify an ascendant research trend, providing promising design ideas and means for unprecedented wave propagation properties. The imperative for on-demand, real-time active control of wave propagation underscores the significance of tunable manipulation of acoustic/elastic waves, promoting the design and development of tunable MMs. Furthermore, the versatility of intelligent materials and their ongoing development and innovation contribute significantly to the emergence of diverse intelligent MMs. This comprehensive survey provides an overview of recent advancements and current research trends in the interdisciplinary field of intelligent MMs with electro-/magneto-mechanical couplings. The primary objective of the review is to emphasize significant progress in agile manipulation of acoustic/elastic waves in electro-/magneto-mechanical coupled MMs, followed by an in-depth exploration of intelligent metasurfaces, topological MMs, non-Hermitian parity-time symmetric wave systems, odd elastic MMs, and spatiotemporally modulated MMs. Special emphasis is given to multi-field coupling effects. The review concludes with a summary and outlines potential prospects, offering a timely and informative guide for future studies on actively tunable PCs and MMs in practical engineering applications. Metamaterials (MMs), including phononic crystals, are the most fascinating type of carriers for acoustic/elastic wave manipulation. Real-time wave control promotes the development of actively tunable MMs. This review delves into intelligent MMs with electro-/magneto-mechanical couplings, covering intelligent metasurfaces, topological MMs, non-Hermitian wave systems, odd elastic MMs, and spatiotemporally modulated MMs. Emphasizing multi-field coupling effects, the review guides future studies, outlining prospects for actively tunable MMs in practical engineering applications. image