Archive/Coupled Thermal and Nonlocal Effects in Advanced Composite Nanobeams: An Efficient Higher-Order Modeling Approach
Coupled Thermal and Nonlocal Effects in Advanced Composite Nanobeams: An Efficient Higher-Order Modeling Approach
Rabab A. Alghanmi, Mohammed Sid Ahmed Houari
10. Juli 2026
en

Abstract

The present research proposes a mathematical method to examine the combined impacts of thermal loading and nonlocal elasticity on the dynamic behavior of functionally graded (FG) nanobeams. A refined higher-order shear deformation theory is introduced, featuring an enhanced displacement field with integral unknowns and a hyperbolic thickness-dependent function to accurately capture transverse shear strains without shear correction constants. Temperature affects the material characteristics, which follow a power-law pattern as they rise through thickness. Using Hamilton’s principle, the study establishes and solves the governing equations analytically. The study discusses how thermal environment, material gradation, and nonlocality alter the dynamic response of FG nanobeams, providing important insights into their nanoscale thermomechanical behavior.

IPC Classification

C07B60H01

Keywords

coupledthermalnonlocaleffectsadvancedcompositenanobeamsefficienthigher-ordermodelingapproachnanomaterialspresentresearchproposesmathematicalexaminecombinedimpactsloadingelasticitydynamicbehaviorfunctionally
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