Contemporary experimental verification in high-energy physics relies on ever-larger particle colliders, with construction costs reaching tens of billions of dollars and circumferences of tens of kilometers, yet the energy scales at which new physics can be effectively verified remain perpetually beyond current technological reach. This paper points out that, based on the constraint network dynamics of Energy Ontology, the equipment for verifying new physics already exists—it has simply not yet been directed at the correct physical targets. The key experimental variable is not particle collision energy, but the precise manipulation and observation of the electron's M-value state—that is, the label of the degree to which the electron is compressed within the constraint network. The M-value is determined by the local constraint network density ρ; when ρ crosses the critical density thresholds ρc1, ρc2, and ρc3, M-value transitions and channel opening or closing are triggered. This paper proposes an entirely new experimental strategy: using pulse sequences to continuously inject energy, causing the M-value to undergo sustained back-and-forth transitions between the M≈0. 5 oscillation state and the M→0⁺ narrow-channel state. The energy scale required for sustained oscillation is far lower than the single-shot extremely-high-energy impacts of existing colliders, because oscillation only requires repeatedly pushing ρ across the ρc2 threshold, rather than pushing it all the way to the sealed region above ρc3 in a single shot. Within the unified operational spectrum of Constraint Network Engineering, this set of equipment constitutes a universal experimental platform for Unlocking and Locking—it can execute all fundamental operations including oscillation unlocking, thermal unlocking, undertaking-fracture unlocking, and forced-sealing locking on the same target point. This paper presents three categories of immediately executable verification protocols: femtosecond laser pulse sequence-driven M-value resonance transitions, measuring the time constants of channel narrowing and widening; strong magnetic fields combined with high-precision spectrometers to measure the anisotropy of the compression degree C (r) ; and the deployment of ultra-large-scale gravitational wave detectors on the far side of the Moon to listen to the fluctuation noise of M→0 free-state energy in the ground state of the constraint network. The key physical aspects of all protocols are benchmarked against existing publicly available experimental data, and no new equipment construction is required. The most precise experiment of the particle world is not to smash particles, but to listen to the constraint network itself. An appendix, proceeding from the master equation, deduces an extreme physical state that may be triggered by sustained high-energy oscillation—constraint network encryption runaway.
Menggang Yu (Wed,) studied this question.