Contribution study on factors impacting the vibration behavior of functionally graded nanoplates
Journal: Journal of Computational Applied Mechanics (Vol.55, No. 3)Publication Date: 2024-07-01
Authors : H Benaddi; B Rebai; K Mansouri; N M Seyam; Ashraf M. Zenkour;
Page : 369-380
Keywords : Functionally Graded Materials; small-scale length parameter; homogenization models; volume fraction laws; vibrational behavior;
Abstract
This comprehensive study investigates the behavior of functionally graded (FG) nanoplates, providing insights into their characteristics and important design considerations. By examining factors such as homogenization models (Voigt Reuss, LRVE, and Tamura), volume fraction laws (power-law model, Viola-Tornabene four-parameter model, trigonometric model), eigenmode, aspect ratios, index material, and small-scale length parameters, the study evaluates their influence on the natural frequency response of simply supported nanoplates. A novel twisting function is introduced and its accuracy in predicting natural frequencies in FG square nanoplates is rigorously validated through numerical comparisons with existing literature. The findings obtained from this research offer valuable guidance for optimizing the design of FG nanoplates and significantly contribute to advancing our understanding of their dynamics and practical applications.
Other Latest Articles
- Stability analysis of functionally graded graphene platelets-reinforced nanocomposite shells
- The onset of Casson fluid convection in a permeable medium layer produced by purely inner heating with magnetic field
- Analyzing the Buckling Behavior of In-plane Bidirectional Functionally Graded Porous Plates
- DEVELOPMENT OF A MULTIMODAL TOOL TO SUPPORT TEACHING OF ROOT CANAL ANATOMY OF PRIMARY MOLARS: AN OBSERVATIONAL CROSS-SECTIONAL STUDY TO EVALUATE THE ACCEPTANCE OF UNDERGRADUATE STUDENTS
- OPTIMIZING LEARNING: A META-ANALYSIS OF TIME MANAGEMENT STRATEGIES IN UNIVERSITY EDUCATION
Last modified: 2024-06-28 18:50:05