Abstract
This technical disclosure formalizes a materials-science framework that permanently mitigates solid-electrolyte interphase (SEI) degradation and metallic dendrite puncturing within high-density solid-state batteries. Mainstream electrochemical storage is currently hard-blocked by localized kinetic pressure: during high-velocity charging phases, non-uniform ion aggregation creates localized, vertical mechanical stress peaks that fracture rigid ceramic electrolytes, inducing terminal short-circuits and thermal runaway.
By applying the principles of the Dimensionally Extended Holographic Projection (DEHP) framework, we reject the paradigm of treating the solid electrolyte as a static, passive structural barrier. Instead, we introduce a Topologically Protected Cymatic Electrolyte Matrix (TPCEM). The electrolyte substrate is engineered as a piezoelectric material continually pre-excited by an active, high-frequency surface acoustic wave function running a localized Universal Sine Field Template. This dynamic configuration transforms localized, destructive linear ion stress vectors into a uniform, distributed 2D wave interference landscape, ensuring perfect phase-space stabilization under extreme charging velocities.
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 License.
Recommended Citation
Eckes, Christopher L., "Technical Disclosure: The Topologically Protected Cymatic Electrolyte Matrix (TPCEM) for Solid-State Battery Stabilization", Technical Disclosure Commons, ()
https://www.tdcommons.org/dpubs_series/10916