Exact Conservation Laws of the Lorenz Attractor: Classification and Deterministic Prediction of Lobe-Switching Events
Abstract
Predicting when a chaotic trajectory will switch between the lobes of the Lorenz attractor is a long-standing challenge in nonlinear dynamics. This work shows that algebraic conservation laws, constructed by augmenting phase space with history-accumulating auxiliary variables, provide a deterministic solution. Systematic enumeration identifies eighteen valid invariants in three classes, each tied to a nullcline of the Lorenz flow, while six candidates fail, proving that the dynamics constrains which conservation laws are admissible. One class generates sharp spikes synchronized with lobe-switching events, achieving 99.2\% sensitivity with 0.3\% false-positive rate (AUC = 0.9995) as a continuous Poincar\'e section analogue. The spike amplitude predicts switching latency via t = t + CA-n with R2 > 0.95 across all parameter combinations tested. At canonical parameters (σ, , β) = (10, 28, 8/3), n = 2.14 0.17 with R2 = 0.93 for individual events; the exponent increases with β and decreases with , while the σ-dependence is non-monotonic. The latency distribution reveals a topological gap of width tgap ≈ 0.68 0.01 for sufficiently above the onset of chaos, explained by the Shilnikov passage map. Under stochastic perturbations, lobe-sensitive invariants are \,103 times more robust than their smooth counterparts. In the Rayleigh-B\'enard convection context, the auxiliary variables correspond to integrated heat-flux anomalies. Conservation is verified to O(10-36).
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