The Science of Solar Mobility
Our journey began with a simple question: Why use fossil fuels when the sun provides more energy in one hour than the world uses in a year? To solve this, we developed Perovskite-Silicone Tandem Cells.
These cells are layered to capture different wavelengths of light. The top layer captures high-energy blue photons, while the bottom layer captures low-energy red and infrared photons. This allows us to reach a remarkable 29.5% conversion efficiency on vehicle surfaces.
Unlike rigid rooftop panels, our solar cells are ultra-thin, flexible, and embedded directly into the vehicle body. This means the entire surface of the car becomes a solar generator without compromising design, weight, or aerodynamics.
Aerodynamics & Solar
Standard solar panels are flat. We engineered liquid-crystal deposition to create solar “paints” that follow vehicle curves. This allows our cars to maintain a 0.20 drag coefficient while maximizing solar absorption.
The result is a sleek design that produces energy while cutting through air with minimal resistance.
Solid State Storage
Traditional lithium-ion batteries are heavy and heat-sensitive. Our motors rely on solid-state battery technology that is lighter, safer, and more efficient.
These batteries replace liquid electrolytes with solid materials, removing the risk of leakage and reducing thermal instability. The result is higher energy density and improved vehicle range.
Even when the vehicle is parked, the solar roof continues charging the battery system, slowly replenishing power throughout the day.
Smart Solar Charging
SolarsDeals vehicles are equipped with a dynamic solar charging system. Micro-inverters are embedded directly into the solar layers of the vehicle, converting sunlight into usable energy instantly.
This means the car does not rely solely on external charging infrastructure. During sunny days, drivers can gain up to 40 kilometers of range without plugging in.
When parked outdoors for extended periods, the car gradually stores energy which can later be used for driving or powering onboard systems.
AI Energy Management
Our vehicles use artificial intelligence to manage energy flow between solar generation, battery storage, and propulsion.
The AI system predicts sunlight availability, driving behavior, and terrain conditions to distribute energy in the most efficient way possible.
This ensures maximum efficiency whether the car is traveling long distances or navigating urban traffic.
Thermal Regulation System
Heat management is critical for solar vehicles. Our vehicles include nano-ceramic cooling channels embedded within the battery structure.
These channels guide heat away from critical components while maintaining ideal battery temperatures. This improves lifespan and maintains performance even in extreme climates.
Additionally, reflective coatings on solar surfaces prevent overheating while still allowing optimal photon absorption.
Autonomous Energy Routing
Energy inside the vehicle is managed through a decentralized power grid. Each subsystem—from motors to climate control—receives energy based on priority.
When sunlight is abundant, excess energy can power interior systems such as air conditioning, infotainment, and computing hardware without draining the battery.
This intelligent routing system ensures that every watt generated from sunlight is used efficiently.
Future Research
Our research teams are already working on the next generation of solar mobility. This includes transparent solar glass for windows, quantum dot energy capture layers, and ultra-light carbon composite solar panels.
The goal is simple: a vehicle that can operate for weeks using only sunlight, dramatically reducing dependence on charging infrastructure.
SolarsDeals is not just building cars. We are building a future where transportation is powered directly by the most abundant energy source in our solar system.