In the present article, the linear and the nonlinear deformation behaviour of functionally graded(FG) spherical shell panel are examined under thermomechanical load. The temperaturedependent effective material properties of FG shell panel are evaluated using Voigt’s micro-mechanical rule in conjunction with power-law distribution. The nonlinear mathematical model of the FG shell panel is developed based on higher-order shear deformation theory and Green-Lagrange type geometrical nonlinearity. The desired nonlinear governing equation of the FG shell panel is computed using the variational principle. The model is discretised through suitable nonlinear finite element steps and solved using direct iterative method. The convergence and the validation behaviour of the present numerical model are performed to show the efficacy of the model.The effect of different parameters on the nonlinear deformation behaviour of FG spherical shell panel is highlighted by solving numerous examples. In the present article, the linear and the nonlinear deformation behavior of functionally graded (FG) spherical shell panels are examined under thermomechanical load. The temperature dependent inherent material properties of FG shell panels are evaluated using Voigt’s micro-mechanical rule in conjunction with power-law The nonlinear mathematical model of the FG shell panel is developed based on higher-order shear deformation theory and Green-Lagrange type geometrical nonlinearity. The desired nonlinear governing equation of the FG shell panel is computed using the variational principle. The model is discretized through suitable nonlinear finite element steps and solved using direct iterative method. The convergence and the validation behavior of the present numerical model are performed to show the efficacy of the model. the effect of different parameters on the nonlinear deformation behavior of FG spherical shell panel is highlighted by solved numerous examples.