Spectral geometry studies the relationship between the geometric structure of manifolds and the spectral properties of differential operators defined on them, particularly the Laplace–Beltrami operator. The eigenvalues of this operator encode deep information about curvature, topology, and global geometric features of a manifold. This paper presents a detailed investigation of the interaction between curvature and spectral invariants on compact Riemannian manifolds. We analyze the analytic structure of the Laplace–Beltrami operator, the asymptotic expansion of the heat kernel, and eigenvalue estimates influenced by curvature bounds. Rigidity theorems and comparison principles that connect geometric constraints with spectral behaviour are discussed in detail. Special attention is given to curvature-dependent inequalities, isoperimetric relations, and spectral comparison theorems. Recent developments in geometric analysis are also highlighted, including advances in eigenvalue estimates, spectral rigidity, and applications in mathematical physics. By combining classical theory with contemporary developments, the paper provides a unified overview of curvature–spectrum interaction and its significance in modern geometry.