About Us

Methodology & Tech Pillars

The Four Breakthroughs

A. Ultra-Low Consumption

Harvesting internally
generated photocurrents.

B. Integrated PMUs

Inductor-less CMOS
technology with cold-startup.

C. EO Interfaces

Exploring PN-junctions,
Plasmonics, 2D Materials
(Graphene), and Molecular
complexes.

D. Photonic Neurons

Co-locating computation
and energy harvesting.

Iterative Design & Validation

Our methodology relies on an agile feedback loop connecting design, simulation, and lab-scale validation. Utilizing standard CMOS fabrication methods (Silicon on Insulator), we ensure that both the Photonic Integrated Circuit (PIC) and the PMU can be seamlessly integrated on the same platform.

Harvesting internally generated photocurrents. We design specific “lossy spots” (like attenuators and MZIs) to balance parasitic energy collection with signal integrity.

Inductor-less CMOS technology with cold-startup. Utilizing Maximum Power Point Tracking (MPPT) to dynamically adjust circuit parameters and maximize power transfer.

We are exploring four complementary strategies to convert optical losses into electrons:

PN-junctions: Exploiting photon recycling.
Plasmonics: Utilizing nanostructured metals for hot electron generation.
2D Materials: Graphene and transition metal dichalcogenides (TMDs).
Molecular Complexes: Bio-inspired synthetic photosystems.

Co-locating computation and energy harvesting. Developing an optical neuron capable of processing information at nanosecond scales while using harvested energy to perform its own non-linear activation (spiking).