Solar Roads: Roads That Generate Electricity

What if roads could generate electricity? Photovoltaic panels instead of asphalt, LEDs instead of painted lines, heating instead of road salt. The idea sounds revolutionary — and it's been tested in France, the Netherlands, China, and the US. The results? Mixed to disappointing — but the technology is evolving and new approaches offer hope.

64M km

Global road network

€5M

Wattway 1km cost (France)

~50%

Actual vs expected output

$2.2M

Solar Roadways crowdfunding

The Idea: Roads as Solar Farms

The global road network spans approximately 64 million kilometers. If even a small fraction of this surface were converted to photovoltaic, the energy produced would be enormous. The basic idea is simple: replace traditional asphalt or concrete with durable photovoltaic panels embedded in the road surface.

⚡ Power Generation

Photovoltaic cells beneath toughened glass convert sunlight into electricity — powering grids, lighting, nearby buildings.

💡 LED Road Markings

Dynamic lane markings, warning messages ("Reduce Speed"), real-time traffic information displayed on the road surface.

🧳 Ice Melting

Heating elements powered by the panels themselves can prevent ice formation — no more road salt or chemicals needed.

🔋 Wireless EV Charging

Inductive coils in the road charge electric vehicles while driving — no stops, no cables required.

The Major Experiments

🇳🇱

SolaRoad — Netherlands (2014)

The world's first solar road opened in November 2014 in Krommenie — a 70m bike path (later expanded to 100m). Result: 73 kWh/m² in the first year, exceeding expectations. It proved the concept works, but costs remained prohibitive.

🇫🇷

Wattway — France (2016)

The world's longest solar road: 1 km in Tourouvre-au-Perche, Normandy. Cost: €5 million, 2,800 m² of panels. Inaugurated Dec. 2016 by the Environment Minister. Result: a fiasco — 50% of expected output (149,459 kWh vs ~290,000 kWh/year), bothersome noise, significant deterioration by August 2018 (Le Monde).

🇺🇸

Solar Roadways — USA (2006-present)

Scott & Julie Brusaw from Idaho started the dream of hexagonal tempered glass panels with LEDs and heating in 2006. Funding: $100K DOT (2009), $750K DOT Phase II, and a viral Indiegogo campaign raising $2.2M (2014) ("Solar Freakin' Roadways"). A prototype was installed in a parking lot in Sandpoint, Idaho — but was never deployed on a real road.

🇨🇳

Jinan Solar Highway — China (2017)

In December 2017, China installed a 1 km solar highway in Jinan (Shandong). Three layers: PV cells, insulation, transparent concrete. Result: powered street lighting but parts of the panels were stolen within 5 days of the opening.

Why Do They Fail?

Critics explain that solar roads face fundamental problems that haven't been solved:

📖 Read more: Wave Energy: Electricity from the Sea

The 6 Major ProblemsNo tilt — panels must be flat, losing 30-40% efficiency vs angled panels
Thick glass — must withstand tons of weight, reducing transparency
Shading & dirt — vehicles, dust, mud, oil all shade the cells
Temperature — without ventilation, overheating = performance drop
Cost — €5,000/m² for Wattway vs ~€50/m² for traditional road
Durability — braking, turning, heavy vehicles cause rapid wear

"Solar roadways are more expensive, less productive, and require much more maintenance than conventional solar installations."

— Interesting Engineering, 2017

The Evolution: What Actually Works?

If PV on road surfaces fails, newer approaches look more practical:

🔌 Electric Roads (Sweden)

Instead of PV, conductive rails embedded in the road power electric trucks while driving. First permanent electric road: E20 Hallsberg-Örebro, by 2026. Target: 3,000 km of electric roads by 2045.

📶 Wireless Charging (Electreon)

Israel's Electreon develops dynamic wireless EV charging — coils inside the road transfer energy to moving vehicles. Pilots in Sweden, Italy, and Germany.

☀️ Solar Bike Paths

Where there are no heavy vehicles, PV panels perform much better. The SolaRoad in the Netherlands proved that the technology works on bike paths.

🌟 Glowing Roads

Studio Roosegaarde (Netherlands) developed photo-luminescent paint for road markings — charges with light and glows for 10 hours. Piloted in Brabant (Apr. 2014), but moisture destroyed the paint within 2 weeks.

The KAIST Case: Online Electric Vehicle

The Korea Advanced Institute of Science and Technology (KAIST) developed the “Online Electric Vehicle” — buses charged via inductive coils embedded in the road. The technology was tested on KAIST's campus bus route, but commercialization was unsuccessful, sparking controversy over continued public funding (2019).

Success Rates by Type

What Works and What Doesn't

PV on highways — ❌ Failure (Wattway, Jinan): weight, wear, shading
PV on bike paths — ✅ Success (SolaRoad): light traffic, panels hold up
Conductive charging — ✅ Promising (Sweden E20): doesn't generate power but feeds EVs
Wireless charging — 🔄 In progress (Electreon, Magment): pilots in multiple countries
Glowing roads — ⚠️ Partial failure: paint doesn't withstand moisture

Global Impact: Where Smart Roads Make Sense

Sun-rich countries and regions with extensive road infrastructure stand to benefit most from evolving smart road technologies:

Opportunities & Challenges WorldwideSunshine belts — Southern Europe, Middle East, Australia ideal for solar sidewalk pilots
Nordic countries — Sweden leads electric road charging, Norway follows for EV-heavy traffic
Urban bike networks — Amsterdam, Copenhagen, growing city bike lanes perfect for SolaRoad-type installations
Electric highways — major corridors like E20 Sweden could become models for EU Trans-European Transport Network (TEN-T)
Cost challenge — still early stage, but EU Green Deal and national EV strategies drive investment

Timeline

2014 SolaRoad Netherlands — first solar bike path, 73 kWh/m²/year.

2016 Wattway France — 1 km solar road, €5M. Failure by 2018.

2017 Jinan China — 1 km solar highway. Panels stolen in 5 days.

2026 Sweden E20 — first permanent electric road (conductive rails, not PV).

2030+ Next generation — lighter PV, nano-materials, sidewalks & parking instead of highways.

2045 Sweden — 3,000 km of electric roads (target). Model for Europe.

Maybe the Road of the Future Isn't “Solar”?

The biggest lesson from a decade of experiments: solar roads for cars don't make sense — they're more expensive and less efficient than panels on rooftops, parking canopies, or roadside installations. But the “smart road” idea lives on through:

Electric roads (conductive/inductive) — charging while driving
Solar sidewalks & bike paths — light traffic, less wear
Solar canopies — covers above roads that provide shade AND generate power
Piezoelectric roads — generating electricity from traffic vibrations

The road of the future won't necessarily replace asphalt — but it will become energy-active, helping cities generate power where they need it most.

Solar Roads Solar Roadways Photovoltaic Pavement Wattway SolaRoad Electric Roads Smart Highways Green Energy

Solar Roads: The Revolutionary Technology That Turns Highways Into Power Plants