TY  - EJOU
AU  - Bibi, Mairaj 
AU  - Arif, Muhammad Shoaib 
AU  - Nawaz, Yasir 
AU  - Kerdid, Nabil 

TI  - Numerical Analysis of Heat and Mass Transfer in Tangent Hyperbolic Fluids Using a Two-Stage Exponential Integrator with Compact Spatial Discretization
T2  - Computer Modeling in Engineering \& Sciences

PY  - 2025
VL  - 145
IS  - 1
SN  - 1526-1506

AB  - This study develops a high-order computational scheme for analyzing unsteady tangent hyperbolic fluid flow with variable thermal conductivity, thermal radiation, and coupled heat and mass transfer effects. A modified two-stage Exponential Time Integrator is introduced for temporal discretization, providing second-order accuracy in time. A compact finite difference method is employed for spatial discretization, yielding sixth-order accuracy at most grid points. The proposed framework ensures numerical stability and convergence when solving stiff, nonlinear parabolic systems arising in fluid flow and heat transfer problems. The novelty of the work lies in combining exponential integrator schemes with compact high-order spatial discretization, enabling accurate and efficient simulations of tangent hyperbolic fluids under complex boundary conditions, such as oscillatory plates and varying thermal conductivity. This approach addresses limitations of classical Euler, Runge–Kutta, and spectral methods by significantly reducing numerical errors (up to 45%) and computational cost. Comprehensive parametric studies demonstrate how viscous dissipation, chemical reactions, the Weissenberg number, and the Hartmann number influence flow behaviour, heat transfer, and mass transfer. Notably, heat transfer rates increase by 18.6% with stronger viscous dissipation, while mass transfer rates rise by 21.3% with more intense chemical reactions. The real-world relevance of the study is underscored by its direct applications in polymer processing, heat exchanger design, radiative thermal management in aerospace, and biofluid transport in biomedical systems. The proposed scheme thus provides a robust numerical framework that not only advances the mathematical modelling of non-Newtonian fluid flows but also offers practical insights for engineering systems involving tangent hyperbolic fluids.
KW  - Exponential integrator scheme; stability; convergence; thermal radiation; tangent hyperbolic nanofluid; variable thermal conductivity; heat and mass transfer

DO  - 10.32604/cmes.2025.070362