The spectral approach as an organizing principle of the laws of nature
Joseph Kouneiher
Université Côte d’Azur, Nice, France

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Abstract
This chapter develops a framework in which spectral data provide a unifying principle for physical law. Across classical and quantum theories, physically meaningful quantities are encoded in the spectra of operators governing dynamics rather than in local field configurations. Within noncommutative geometry, spectral triples offer a representation-independent formulation of space-time in which geometry, gauge symmetry, and dynamics emerge from operatorial structures. Spectral data acquire physical significance through their pairing with cohomological invariants, which select stable and quantized observables. Gauge fields arise as inner fluctuations of the Dirac operator, and dynamics is governed by spectral invariants such as the spectral action. Renormalization is interpreted as a flow of spectral data under scale-dependent truncation. Classical and quantum equations, including Einstein’s and Schrödinger’s equations, appear as effective limits of this spectral dynamics, providing a unified and robust perspective on geometry and quantum physics.