Plasmon–Phonon Coupling From Spiral Memory to Quantum Light
Recognizing the urgency of environmental transformation, TENGENA pioneers scalable platforms for photonics and light–matter interaction, advancing foundational research in quantum optics, plasmonics, and subnanoscale material dynamics. Our work bridges quantum information science, AI-driven synthesis, and adaptive nanomaterials engineering to address energy and signal modulation challenges critical to a net-zero carbon economy.
Through precision control of electromagnetic behavior at atomic and photonic scales, TENGENA's unique materials critical for the development of multifunctional substrates, dynamic sensing architectures, and energy-efficient optical systems. Our team redefines mobility and signal fidelity by dissolving conventional boundaries between material science, quantum logic, and environmental stewardship—laying the groundwork for next-generation product ecosystems that are resilient, responsive, and radically sustainable.
TENGENA redefines the future of computing through a vertically integrated, light-native architecture that eliminates the constraints of classical electronic interconnects. Unlike conventional silicon photonics and thin-film systems that remain confined to passive routing and basic modulation, TENGENA’s design initiates a paradigm shift. Where conventional photonic systems remain fragmented—separating quantum processors, analog accelerators, and photonic algebra—TENGENA converges these domains into a singular substrate of intelligence. This unified platform integrates plasmonic logic, quantum photonics, and power-over-light delivery to enable simultaneous inference, memory, and sensing within a coherent, self-powered photonic space. The result is a system that doesn’t just compute—it perceives, adapts, and evolves through light alone.
At the core of TENGENA’s architecture lies a paradigm-shifting fusion of quantum-class spiral memory, anisotropic microring crossbars for native vector–matrix multiplication, and fully optical inference fabrics. These are energized by single-fiber optical carriers that transmit both data and power, activating on-chip photovoltaic biasing modules and eliminating resistive losses. This design enables sub-100 ns inference latencies, radiation resilience, and EMI immunity—ideal for edge intelligence, orbital compute fabrics, and secure environments. Our deterministic plasma-assisted synthesis of chemically pure, sub-nanometer plasmonic inclusions within perovskite-type spiral resonators unlocks nonlinear gain modulation, quantum confinement, and optothermal responsiveness, forming the foundation for dynamic, reconfigurable AI acceleration.
TENGENA Transcend extends from neural acceleration to entangled photon generation, enabling full-spectrum adaptability and quantum-class performance. Plasmonic metastructures support second harmonic generation and spontaneous parametric down-conversion, yielding tunable Bell states and hyperentangled photon pairs. Embedded phase-change layers and liquid crystal overlays provide agile spectral control, while inverse-designed metastructures and cryo-compatible waveguides establish the basis for monolithic quantum photonic chips. Our roadmap paves the way for mass-manufacturable, inference-grade photonic processors and reconfigurable sensor arrays. TENGENA’s architecture is not just a system—it is a modality shift in how light powers cognition, adaptation, and environmental intelligence.
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