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One operator to rule them all: Unifying connectome harmonics, turbulence and complex harmonics in brain dynamics

Morten L Kringelbach, Gustavo Deco

bioRxiv (Cold Spring Harbor Laboratory) June 9, 2026 DOI: 10.64898/2026.06.05.730423 via OpenAlex

Summary

Brain dynamics can be described in three mathematical languages—connectome harmonics, turbulence, and complex harmonics (CHARM)—which are unified as a single self-adjoint operator and its spectral measure. The connectome Laplacian carries this measure; harmonics are its spectral projections, the turbulence smoothing kernel is its resolvent, and CHARM form is its unitary propagator. A shared control parameter, the spectral gap, yields cortical hierarchy, turbulent information cascade, and structured interference. Testing this with a pharmacological perturbation by LSD showed that one scalar coupling simultaneously predicts multi-scale turbulence shifts and macroscale harmonic energy redistribution, supporting the unified operator structure.

Study at a glance

Characteristics Theoretical and empirical study Peer reviewed
Keywords Laplace operator Operator biology Eigenfunction Harmonics Spectral density
Key finding A single self-adjoint operator unifies connectome harmonics, turbulence, and CHARM frameworks, and a pharmacological perturbation with LSD confirmed that one scalar coupling predicts changes in both turbulence and harmonic energy redistribution.

Abstract

Abstract Brain dynamics can be described in three different convenient mathematical languages, namely connectome harmonics, turbulence and complex harmonics (CHARM). Here we demonstrate that these theoretical frameworks can be rigorously unified, under the functional calculus, as one self-adjoint operator and its single spectral measure. The connectome Laplacian carries that measure; the harmonics are its spectral projections, the turbulence smoothing kernel is its resolvent, and the CHARM form is its unitary propagator. The bridge that makes this exact is a textbook fact: The exponential distance rule, which is the empirical kernel of the turbulence model, is the Green’s function of a screened Laplacian, so the local order parameter is the phase field passed through the resolvent of the same operator whose eigenfunctions are the harmonics. A single shared control parameter, the spectral gap, simultaneously yields the cortical hierarchy, the turbulent information cascade and the structured interference the CHARM form measures. This unification makes a strong predictive claim. If the harmonic projections, the turbulence resolvent and the CHARM propagator really are three functions of one operator, then any structural perturbation that re-tunes the operator must move all three signatures in unison and must do so with a single coupling. We test this prediction with a pharmacological perturbation by lysergic acid diethylamide (LSD), which is known to change the emotional state, by empirically perturbing the operator with a 5-HT 2A receptor density map and asking whether one scalar coupling can simultaneously predict the multi-scale turbulence shift observed, through the resolvent, and the macroscale harmonic energy redistribution, through first-order Rayleigh–Schrödinger perturbation theory. We found that the two independent functional domains respond in unison to one structural perturbation of one operator. The identity is exact as operator calculus and its purchase on the brain depends on a single load-bearing seam, the degree heterogeneity of the connectome, which we make explicit. We propose that this single-operator structure is the necessary mathematical scaffolding of our Entangled Loop theory.

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