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Main Authors: Shahid, Farzeen, Alam, Maqusud, Park, Jin-Young, Choi, Young, Park, Chan-Jeong, Park, Hyung-Keun, Yi, Chang-Yong
Format: Artículo científico
Language:en
Published: Biomimetics (Basel, Switzerland) 2025
Online Access:https://pubmed.ncbi.nlm.nih.gov/40710242/
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author Shahid, Farzeen
Alam, Maqusud
Park, Jin-Young
Choi, Young
Park, Chan-Jeong
Park, Hyung-Keun
Yi, Chang-Yong
author_facet Shahid, Farzeen
Alam, Maqusud
Park, Jin-Young
Choi, Young
Park, Chan-Jeong
Park, Hyung-Keun
Yi, Chang-Yong
Shahid, Farzeen
Alam, Maqusud
Park, Jin-Young
Choi, Young
Park, Chan-Jeong
Park, Hyung-Keun
Yi, Chang-Yong
collection PubMed - marine biology
contents Bioinspired Morphing in Aerodynamics and Hydrodynamics: Engineering Innovations for Aerospace and Renewable Energy. Shahid, Farzeen Alam, Maqusud Park, Jin-Young Choi, Young Park, Chan-Jeong Park, Hyung-Keun Yi, Chang-Yong Bioinspired morphing offers a powerful route to higher aerodynamic and hydrodynamic efficiency. Birds reposition feathers, bats extend compliant membrane wings, and fish modulate fin stiffness, tailoring lift, drag, and thrust in real time. To capture these advantages, engineers are developing airfoils, rotor blades, and hydrofoils that actively change shape, reducing drag, improving maneuverability, and harvesting energy from unsteady flows. This review surveys over 296 studies, with primary emphasis on literature published between 2015 and 2025, distilling four biological archetypes-avian wing morphing, bat-wing elasticity, fish-fin compliance, and tubercled marine flippers-and tracing their translation into morphing aircraft, ornithopters, rotorcraft, unmanned aerial vehicles, and tidal or wave-energy converters. We compare experimental demonstrations and numerical simulations, identify consensus performance gains (up to 30% increase in lift-to-drag ratio, 4 dB noise reduction, and 15% boost in propulsive or power-capture efficiency), and analyze materials, actuation, control strategies, certification, and durability as the main barriers to deployment. Advances in multifunctional composites, electroactive polymers, and model-based adaptive control have moved prototypes from laboratory proof-of-concept toward field testing. Continued collaboration among biology, materials science, control engineering, and fluid dynamics is essential to unlock robust, scalable morphing technologies that meet future efficiency and sustainability targets.
format Artículo científico
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institution PubMed
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publishDate 2025
publisher Biomimetics (Basel, Switzerland)
record_format pubmed
spellingShingle Bioinspired Morphing in Aerodynamics and Hydrodynamics: Engineering Innovations for Aerospace and Renewable Energy.
Shahid, Farzeen
Alam, Maqusud
Park, Jin-Young
Choi, Young
Park, Chan-Jeong
Park, Hyung-Keun
Yi, Chang-Yong
Bioinspired Morphing in Aerodynamics and Hydrodynamics: Engineering Innovations for Aerospace and Renewable Energy. Shahid, Farzeen Alam, Maqusud Park, Jin-Young Choi, Young Park, Chan-Jeong Park, Hyung-Keun Yi, Chang-Yong Bioinspired morphing offers a powerful route to higher aerodynamic and hydrodynamic efficiency. Birds reposition feathers, bats extend compliant membrane wings, and fish modulate fin stiffness, tailoring lift, drag, and thrust in real time. To capture these advantages, engineers are developing airfoils, rotor blades, and hydrofoils that actively change shape, reducing drag, improving maneuverability, and harvesting energy from unsteady flows. This review surveys over 296 studies, with primary emphasis on literature published between 2015 and 2025, distilling four biological archetypes-avian wing morphing, bat-wing elasticity, fish-fin compliance, and tubercled marine flippers-and tracing their translation into morphing aircraft, ornithopters, rotorcraft, unmanned aerial vehicles, and tidal or wave-energy converters. We compare experimental demonstrations and numerical simulations, identify consensus performance gains (up to 30% increase in lift-to-drag ratio, 4 dB noise reduction, and 15% boost in propulsive or power-capture efficiency), and analyze materials, actuation, control strategies, certification, and durability as the main barriers to deployment. Advances in multifunctional composites, electroactive polymers, and model-based adaptive control have moved prototypes from laboratory proof-of-concept toward field testing. Continued collaboration among biology, materials science, control engineering, and fluid dynamics is essential to unlock robust, scalable morphing technologies that meet future efficiency and sustainability targets.
title Bioinspired Morphing in Aerodynamics and Hydrodynamics: Engineering Innovations for Aerospace and Renewable Energy.
url https://pubmed.ncbi.nlm.nih.gov/40710242/