Si Substrate Photonic-Core vs Ti3SiC2 Enhanced Architecture
Traditional silicon photonics relies on Si substrate 3s2 3p2 with integrated lasers for optical signal generation. While Si enables photon propagation at ~150,000 m/s through the crystalline lattice, this high velocity limits control over signal timing and increases crosstalk in dense 3D stacks.
3s2 3p2 = 2 lasers Si configuration forces isotropic emission. Ti3SiC2 confines photons along basal planes, reducing leakage and enabling deterministic 6-connection routing: IN L0, IN L1, OUT+, OUT-, GND, Xe gap.
Layer 1 (Bottom): Si Substrate or Ti3SiC2 base with dual laser injection (L0/L1). GND plane.
Layer 2 (Mid): Ag Core with +/- terminals. Ti traces left/right for signal routing.
Layer 3 (Top): S passivation above Ag. Xe gas gap above for pressure-tunable optical coupling.
The 10kHz clock synchronizes optical pulses. O1 bias modulates S-Ag Schottky barrier height. Pressure controls Xe density, tuning the gap capacitance and photon tunneling probability. The dramatic delay difference makes Ti3SiC2 ideal for temporal logic gates where propagation time is a computational variable, not a bug.