Sustainability is an engineering challenge, not just a goal.
We design autonomous robotic systems that maintain critical infrastructure: maximizing solar yield, ensuring clean air, and closing the resource loop through precision engineering.
GLOBAL TEMPERATURE REDUCTION
The world has invested trillions in sustainable infrastructure.
Most of it underperforms. Efficiency degrades. Capacity goes unrealized. The gap between what exists and what it could deliver is measured in gigatons of emissions: every year.
What if closing that gap: across every sector, everywhere, continuously: could shift global temperature by half a degree?
That's not a dream. It's arithmetic.
The capability exists. The potential is real.
It just needs to work.
As infrastructure scales, so do maintenance complexities. Physical accumulation: whether dust, smog, or waste: creates friction that undermines sustainable investments.
SCOPE: GLOBAL INFRASTRUCTURE
FOCUS: YIELD OPTIMIZATION
The Challenge: Environmental Soiling.
Solar assets can lose up to 30% capacity due to dust accumulation. Traditional cleaning is labor-intensive and water-scarce.
The Challenge: Localized Pollution.
Static sensors monitor pollution but cannot reduce it. Urban environments require dynamic filtration to improve livability.
The Challenge: Mixed Waste Streams.
Valuable resources are lost in landfills. High-speed, accurate sorting is essential to making the circular economy viable.
A waterless, autonomous dry-cleaning rover designed for desert extremes. It gently removes dust layers from PV panels, ensuring maximum photon absorption and extended asset life.
FOUNDER & PRODUCT ARCHITECT
Bridging the gap between lab-scale innovation and field-hardened reality. Specializes in "Zero-to-One" engineering: transforming raw concepts into deployable industrial assets.
CO-FOUNDER & CTO
Architecting resilience at scale. A veteran of Oracle & Juniper with 22+ years building systems that do not fail. Scaled critical mesh networks to 1M+ nodes.