This work develops a complete abstract framework for quadratic variational structures of the form: F (u) = ||R (u) ||², where R is a C² mapping between Hilbert spaces and vanishes at a reference configuration u₀. The analysis is entirely local and focuses on the second-order structure of F near u₀. The central result identifies the canonical operator governing the problem: A = L*L, where L = DR (u₀). The second variation satisfies: D²F (u₀) = 2L*L, and the local expansion is given by: F (u₀ + h) = ||A^ (1/2) h||² + o (||h||²). This shows that the entire quadratic behavior of F is encoded by the positive self-adjoint operator A. The associated closed quadratic form: q (h) = ||A^ (1/2) h||², defines the intrinsic object of the theory, independent of the particular representation of the residual R. The work establishes a complete spectral characterization of the local regime: • Stability is governed by the spectral gap λ₁ (A) > 0• Dissipative dynamics are generated by the semigroup e^ (−tA) • The Green operator is given by A⁻¹ on the effective space• The effective Hilbert space is H₀ = (ker A) ⊥ A key structural result is that all second-order phenomena—energy, stability, dynamics, and response—are different manifestations of the same spectral object A. The framework is fully representation-invariant: different residuals R leading to the same linearization produce the same operator A. The scope is explicitly restricted to the local quadratic regime. Higher-order nonlinear effects and global behavior are not addressed and require additional analytic tools. The results rely on functional analysis, spectral theory of self-adjoint operators, and elliptic regularity, and apply uniformly across geometric analysis, PDEs, and mathematical physics. Author: Mario César Garms ThimoteoEmail: mariothimoteo@hotmail. comDOI (Zenodo): 10. 5281/zenodo. 19359862
Mário César Garms Thimoteo (Tue,) studied this question.