F1 2026 power unit, Mercedes: the technical loopholes that could deliver an advantage
Assessing every current hypothesis surrounding the alleged Mercedes “trick” for the 2026 Formula 1 power units is exactly what is needed at this stage. This is especially true considering that the FIA has reportedly declared the German manufacturer’s engine system to be legal. It is therefore worth trying to understand where teams can still operate within the regulations, because the information circulating over the past few days does not make the situation entirely clear.
Some technical certainties regarding the 2026 power unit hypotheses
At the moment, it seems almost certain that the Brackley-based team has found something significant. This belief is reinforced by the fact that, last Monday, the teams met with the International Federation to discuss the issue. From within the factories of several teams, a clear technical detail has emerged regarding the geometric compression ratio of the 2026 F1 power units, a topic well known to many and already discussed in recent days.
In the Formula 1 engineering market, engineers frequently move from one team to another, which is precisely why information tends to circulate between competitors. The data we have gathered appears to confirm what has been reported recently. The geometric compression ratio is simply the relationship between two volumes: the maximum volume, which occurs when the piston is at its lowest position, known as bottom dead centre (BDC).
The minimum volume, on the other hand, corresponds to top dead centre (TDC), when the mixture is compressed into a very small space. All of this is regulated by Article C5.4.3 of the 2026 technical regulations. According to information obtained by our editorial team, the Brixworth engineers may have managed to increase this geometric ratio from the regulatory baseline of 16:1 to around 18:1 at operating conditions. This would represent a notable and inherently risky step.
The risk lies in the fact that the mixture is compressed more aggressively, increasing the chance of auto-ignition without the spark from the spark plug. From this increase, through relatively simple calculations, it is possible to estimate a potential power gain. On paper, such a jump could be worth between 10 and 15 horsepower. Naturally, this is a theoretical figure that can only be confirmed on track, as there is often a gap between theory and real-world performance.
F1 2026: how Mercedes may have found an advantage through material options
This brings us to the most complex aspect, as several hypotheses are currently being evaluated. The first involves a very intelligent use of thermal expansion. One point must be made clear straight away: at certain operating temperatures, a degree of “natural” thermal expansion is inevitable. The real difference is made by the most capable engine designers, who are able to extract a meaningful advantage from it.
The idea that has been circulating and that we have analysed concerns the thermal expansion of the connecting rod. In simple terms, this component lengthens under heat, effectively increasing the top dead centre position and consequently reducing the volume in which the mixture is compressed. This could represent a starting concept, but its real-world implementation is far more sophisticated than it might initially appear.
A significant amount of work would be required on materials, which are tightly regulated, in order to gain an advantage from such a solution. For connecting rods, for example, only iron-based and titanium-based alloys are permitted. However, these components can be machined from solid material, starting from a single block. This type of manufacturing process allows the use of a broader range of alloys within the regulatory framework.
There is also the question of pistons. Once again, iron- and titanium-based materials are required, although in this case the FIA does not explicitly specify the manufacturing process. For pistons, only four iron-based alloys are permitted. It might seem that teams are heavily constrained when it comes to materials, but not as much as one might think. There are several nuances where Mercedes could have worked by combining alloys and materials in clever ways.
It is important to remember that, for now, we are still talking about hypotheses. The aim here is to explain the situation as clearly and simply as possible, while remaining technically rigorous.
Mercedes: another option lies in the piston crown
As mentioned earlier, increasing the compression ratio means reducing the volume in which the mixture is compressed when the piston reaches top dead centre. One possible approach would be to thermally expand the piston crown so that it bulges slightly, reducing that volume. Even a minimal reduction could contribute to a higher compression ratio.
There is far less freedom when working on the piston itself. Only a limited number of alloys can be used, which means the component cannot be made anisotropic. One would have to work on creating a temperature difference between the crown and the skirt, but this would likely prove to be a much more complex route. For this reason, research on the connecting rod appears to be the simpler path, although, once again, we are still dealing with theoretical scenarios.
Two things, however, are certain. Grey areas in the regulations do exist, and Mercedes has found something. For the internal combustion engine, the FIA attempts to narrow the scope as much as possible, but it is worth remembering that teams employ hundreds of engineers who have spent countless hours figuring out how to extract the maximum from these rules.
And this is without even considering the electrical side of the power unit, which remains a relatively unexplored topic. We will share our analysis on that aspect in the coming days.
Jan 1, 2026Alex Marino
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