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Stability analysis of nano-devices: Exercise-mediated effects on nanodevice stability in drug delivery applications
(2025-05-25)
Huanan Chen
;
HABIBI, MOSTAFA
;
Jiahao Zhu
;
Ameni Brahmia
;
Wnag, Dan
The use of sophisticated materials and nanoscale structures in the design of sports equipment is recognized as a key strategy for boosting athletic performance. The study of spinning small-scale structures, such as nanobeams and nanotubes, is centered on their potential use in the creation of next-generation sporting equipment. The distinct characteristics of these constructions, such as improved stiffness, vibration damping, and longevity, play an important role in improving the efficiency, control, and responsiveness of various athletic equipment. Nanomaterials are used in tennis rackets, golf clubs, and hockey sticks to efficiently eliminate undesired vibrations while increasing energy transfer upon impact, boosting player comfort and performance. These structures’ rotational dynamics closely resemble real-world circumstances encountered by sports equipment, such as the swinging motion of a bat and the bending of a ski. The nonlocal strain gradient theory provides useful insights for improving material behavior in dynamic loading situations, notably in terms of size effects at the nanoscale. Case studies and practical examples demonstrate how these innovations support athletes in improving their power, accuracy, and the longevity of their equipment. A connection exists between nanotechnology and sports engineering, facilitating the development of lighter, stronger, and more efficient technologies that enhance athletic performance capabilities. The significance of diverse methods for enhancing sports technology is emphasized, providing advantages for both elite athletes and recreational users.
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Advancing sports equipment performance: Leveraging rotating small-scale structures for enhanced athletic tools
(2025-05-25)
Yuan Wan
;
Guizhi Zhang
;
Zimin Chang
;
HABIBI, MOSTAFA
;
Albaijan, Ibrahim
The use of sophisticated materials and nanoscale structures in the design of sports equipment is recognized as a key strategy for boosting athletic performance. The study of spinning small-scale structures, such as nanobeams and nanotubes, is centered on their potential use in the creation of next-generation sporting equipment. The distinct characteristics of these constructions, such as improved stiffness, vibration damping, and longevity, play an important role in improving the efficiency, control, and responsiveness of various athletic equipment. Nanomaterials are used in tennis rackets, golf clubs, and hockey sticks to efficiently eliminate undesired vibrations while increasing energy transfer upon impact, boosting player comfort and performance. These structures’ rotational dynamics closely resemble real-world circumstances encountered by sports equipment, such as the swinging motion of a bat and the bending of a ski. The nonlocal strain gradient theory provides useful insights for improving material behavior in dynamic loading situations, notably in terms of size effects at the nanoscale. Case studies and practical examples demonstrate how these innovations support athletes in improving their power, accuracy, and the longevity of their equipment. A connection exists between nanotechnology and sports engineering, facilitating the development of lighter, stronger, and more efficient technologies that enhance athletic performance capabilities. The significance of diverse methods for enhancing sports technology is emphasized, providing advantages for both elite athletes and recreational users.
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A pathway to sports innovation through the stability performance of lightweight functionally graded tubular structures
(2025-04-25)
Xiao, Donglin
;
Belgacem Bouallegue
;
Maryam Bagheri
;
HABIBI, MOSTAFA
Small-scale tubular structures have garnered considerable interest owing to their exceptional mechanical qualities, making them suitable for applications requiring lightweight and durable designs. This work examines the stability and buckling behavior of these structures via an integrated approach that merges beam theory with modified couple stress theory, yielding a more accurate comprehension of micro and nanoscale phenomena. The findings are particularly relevant to the sports industry, where advances in equipment and practices may considerably impact player performance and safety. This study looks at how these structures may improve the design of high-performance sports equipment, such as lightweight yet stable bicycle frames, ski poles, and gymnastic vaulting poles, by increasing their strength-to-weight ratio for better performance. The study emphasizes the potential applications in protective equipment and wearable technologies, where maintaining structural integrity is essential for ensuring longevity while preserving mobility. The comprehension of mechanical stability has progressed, leading to the development of a method for integrating advanced structural mechanics into sports engineering, thereby facilitating innovations that improve athletic performance and safety.

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