Patent Application Number: GB2511144.4
Filed Date: July 09, 2025
Status: Pending
Abstract:
This invention relates to a method and apparatus for detecting nonlinear entropic response in photonic-stimulated materials. The system is designed to expose certain solid-state materials—such as thin-film silica or amorphous semiconducting surfaces—to directional photonic inputs at varying angles and frequencies. The aim is to detect electrical output triggered by τ-resonant entropy release rather than classical photoelectric excitation. The device uses coherent or semi-coherent light sources (e.g., lasers or narrowband LEDs) arranged to stimulate the material at controlled angles. Electrical measurements are recorded in real time to observe nonlinear, threshold-based output behaviour distinct from energy-proportional photovoltaic response.
Note: The above applications are pending. Implementation or commercial use of the disclosed methods may require a license. Abstracts on this page are informational and non-exhaustive.
Patent Application Number: GB2514577.2
Filed Date: September 04, 2025
Status: Pending
Abstract:
A method and system for designing electrochemical cells is disclosed, based on an entropy–decay framework rather than conventional electron/ion transport models. The invention provides rules for selecting cathode and anode materials according to entropic dimensional bands, wherein cathodes occupy higher-dimensional entropic states (14D–16D) and anodes occupy lower-dimensional states (11D–13D). Energy discharge is achieved as entropic propagation from cathode to anode, while rechargeability arises from τ-resonant reversibility of the electrode pair. Electrolytes are further classified as entropic channels or mismatches, enabling controlled resonance coupling. By applying a memory-integrated entropy–decay equation to experimental datasets, τ-resonance of candidate materials can be predicted, allowing for guided material design and manufacturing. The disclosed method and system enable predictive development of batteries with enhanced stability, reversibility, and cycle life, applicable to electric vehicles, grid storage, and portable electronics.
Note: The above applications are pending. Implementation or commercial use of the disclosed methods may require a license. Abstracts on this page are informational and non-exhaustive.