What are eVTOLs: the electric 'flying cars' that could transform urban mobility

Yes, they really do exist. In recent years, we have seen the flight of several eVTOL (electric vertical take-off and landing) prototypes. Meanwhile, various certification processes are making headway in Europe and the United States.

Beyond the media hype, the real takeaway is the structural leap: the electrification of transport is no longer confined to the road; it is taking to the skies. This forces us to rethink our infrastructure – how we generate, distribute, and manage energy in our cities. That is the real story behind these so-called 'flying cars'.

What is an eVTOL?

An eVTOL (electric Vertical Take-Off and Landing) vehicle is a 100% electric aircraft that takes off and lands vertically using distributed electric propulsion. In some cases, they transition to a more efficient cruise flight using dynamic configurations.

In Europe, their certification is based on EASA's Special Condition VTOL (SC‑VTOL); in the US, the FAA classifies them as 'powered‑lift' aircraft within its Advanced Air Mobility strategy.

These regulatory frameworks are not just marketing: they establish stringent standards for safety, design, maintenance, and operation on a par with light commercial aviation, which are absolutely essential for taking them from prototypes to a viable, real-world market.

How do they differ from a helicopter?

The comparison is inevitable, but the technical approach is entirely different. A conventional helicopter is highly effective, yet noisy and mechanically complex to maintain.

Many eVTOLs rely on distributed electric propulsion across multiple rotors, which eliminates single points of failure and significantly lowers noise levels during both take-off and cruising.

Furthermore, their electric architecture facilitates built-in redundancy and paves the way for lower operating costs in the medium term, although these benefits ultimately depend on the specific design.

The other major difference is the regulatory framework. Because they do not fit neatly into traditional categories, specific standards (SC‑VTOL/powered‑lift) are being developed to govern their safety, operation, and integration into urban environments, alongside acoustic requirements and contingency procedures.

Do 'electric flying cars' already exist?

Yes, but we need to be precise. There are prototypes and demonstrator models that have combined ground and air mobility in controlled environments, as well as modular platforms that deploy an eVTOL module directly from a vehicle. 

However, this is not the same as being certified for passenger transport. These are capability trials that demonstrate the potential of ground‑to-air integration, helping to mature the technology, enhance safety, and build public acceptance, rather than representing a fully fledged market.

The leap to commercialisation requires complying with rigorous aviation certification, standardising vertiports, testing operational procedures, and proving economic viability.

Why the eVTOL conversation is really about energy (and not just vehicles)

The true value of eVTOLs lies not in the 'flying gadget' itself, but in the infrastructure that makes them possible. They require infrastructure that allows them to operate regularly, safely, and efficiently. Rolling out these services in a major city requires: 

• Strategically located vertiports: Situated on rooftops, at transport interchanges, hospitals, or logistics hubs, featuring obstacle-free zones, specific signage, and security processes that are compatible with the city environment.
• Standardised, interoperable fast-charging systems: The industry is converging towards DC Combined Charging Systems (CCS). The goal is to simplify infrastructure, cut costs, and facilitate rapid turnaround times between flights.
• Digital, automated airspace management: Systems such as U‑space in the EU are needed to coordinate low-altitude flights, integrate both manned and unmanned aircraft, and react in real time to shifting priorities (such as emergencies, weather conditions, or public events).
• Sufficient grid capacity: Operational nodes must have robust grid connections, incorporating local energy storage to flatten demand peaks, alongside the integration of renewables and smart grid management systems (such as scheduled charging, load control, and grid flexibility).