Lie symmetry analysis of the nonlinear generalized heat equation for varying cross-section geometry

Abstract

We study the nonlinear generalized heat equation C(u)ut=1z(K(u)zuz)z, where C(u) and K(u) are temperature-dependent thermal coefficients and >0 is a geometric parameter describing the varying cross-section geometry. By applying the classical Lie symmetry method, we derive the determining equations and perform a complete classification of the admitted Lie point symmetries according to the functional dependence between C(u) and K(u). The analysis shows that the symmetry structure splits naturally into two principal cases: C(u)/K(u) non-constant and C(u)/K(u)=β constant. In the first case, only the basic symmetries are admitted for arbitrary coefficients, whereas additional generators appear under special compatibility relations. In the second case, the equation can be transformed to a linear radial heat equation by the substitution v=∫ K(u)du, yielding an extended symmetry algebra. For each case, we construct the infinitesimal generators, commutator tables, one-parameter transformation groups, and corresponding invariant reductions. Invariant and similarity solutions are obtained and then specialized to several physically relevant subclasses, including power-law, exponential-type, and linear constitutive coefficients. The results provide a unified symmetry-based model for the analysis of generalized nonlinear heat equations in non-Cartesian geometries.