The 296 Challenge is the very first car in the single-make series to sport a V6 engine with the hybrid powertrain removed to reduce weight while the power output was increased to 700 cv, resulting in a record specific power output for the segment - 234 cv/l

At the very start of the development process, it was decided to remove the hybrid elements from the V6 powertrain as per the 296 GT3. The electric motor and high voltage battery were eliminated and power output of the twin turbo V6 was boosted to 700 cv. This approach helped limit the car’s weight and the complexity of the overall unit, both fundamental factors for track applications.

The new architecture led to the development of a more linear exhaust line located in the upper part of the engine compartment. The shape of the exhaust reduces back pressure by 30% and provides a significant contribution to the increase in power. The GPF (Gasoline Particulate Filter) used on the road car has been removed, but the highly permeable catalytic converter normally used in racing remains.

Compared to the road-going engine, the Challenge specification sees a number of modifications to capitalise on the lower back pressure. The maximum speed of the turbos has been increased by 10% to 180,000 rpm, increasing the turbo boost pressure by the same amount, and the spark advance has been anticipated, providing a slight increase in pressure in the combustion chamber. The result is a 37 cv increase in power compared to the road-going 296 GTB and GTS, with the same maximum torque output, slightly lower in the rev range.

The increase in the V6’s power output required additional thermal protection in the engine bay with specific turbo insulation. Removing the hybrid elements also led to the introduction of an air-con compressor and a 12-volt starter motor, both driven by the crankshaft via a dedicated belt, fulfilling the dual function of starting the engine and charging the 12V electrical system.

Thanks to its new 234 cv/l specific power output, the 296 Challenge’s ICE sets a new record for a road-derived Ferrari and demonstrates just how central technology transfer – from road to race, and race to road - is to Ferrari in order to constantly develop its products.

Most of downforce over the front axle is generated by the splitters and the front section of the underbody, while the rear aero is dominated by the adjustable-angle fixed wing. The front underbody was designed to create ground effect to keep the flow stable even when the ride height is reduced under braking or in cornering.

Downforce generation over the rear axle comes mostly from the fixed spoiler, the angle of which can be adjusted into seven different positions. This allows the downforce level and balance to be set to meet the specific requirements of each circuit the car competes on. The wing is supported by two aerofoil struts, which attach on the upper surface. This solution minimises aerodynamic interference on the underside of the profile, which generates most of the downforce and is more sensitive to flow disruption.

The wing’s end plates are equipped with appendages that generate downforce and improve the efficiency of the lower edge of the profile. The wing works in symbiosis with the rear diffuser and the underbody, which has two pairs of vortex generators in its rear section.

The central area is dominated by the S-Duct, which connects the underbody with the upper body to maximise the efficiency of the central diffuser and tangibly reduce the sensitivity of the 296 Challenge’s aero balance to pitch. Aside from acting as a vent for the air feeding the central diffuser, the S-Duct creates a connection between the underbody, which functions in close proximity to the ground, and the upper body, an area in which pressure remains much more consistent in racing conditions.

The underbody in the central area has been raised: having it higher off the ground guarantees that the central diffuser can work efficiently during manoeuvres when the front of the car is closer to the ground, such as, for instance, braking at the end of a straight, thereby guaranteeing much more consistent downforce.

There are two diffuser ramps, one on either side of the S-Duct, which create vertical expansion. Either end of the splitter, below the flick, is a separate wing section, which marks the debut on a closed-wheel competition car of the F1-inspired, double-element concept that makes downforce less sensitive to variations in trim.

Behind the S-Duct are three pairs of vortex generators, which create vortices on the underbody and generate a lateral expansion, creating local suction and consequently high-efficiency downforce. The side of the splitter was designed to activate the underbody and manage the flows downstream of it. The end plates generate concentrated vortices to manage the wake from the front wheels.

The 296 Challenge can generate 870 kg of downforce at 250 km/h with the spoiler at its maximum angle of attack. This is an 18% increase in downforce compared to the 488 Challenge Evo. The car’s aero design focused not just on the pursuit of performance, but also on driveability.

The aim with the 296 Challenge’s aero development was to use the knowledge built up the 296 GT3, to deliver unprecedented downforce figures for Ferrari’s single-make series.

The primary goal of delivering downforce that is easily exploitable on the track was achieved by keeping variations in downforce and balance to an absolute minimum both on the straight and through corners. This makes the car agile and responsive and very predictable at high speeds, thereby simultaneously guaranteeing extreme performance and driving thrills.

The layout of the cooling system was modified as a result of removing the hybrid elements. The location and arrangement of the radiating masses is the same as on the 296 GT3, with the water radiator for the high temperature circuit at the front, with the condenser for HVAC circuit ahead of it. The two intercoolers and the engine air filters from its road-going counterpart have been retained at the rear.

The vent on the bonnet has specific wing profiles that optimise the venting of the air from the S-Duct channel, which is immediately behind the radiator shroud. The rear bumper has been redesigned compared to the 296 GTB: the engine bay venting area is now much larger to guarantee adequate extraction of hot air flows in both static and dynamic conditions.

Huge work was lavished on honing the fluid-dynamics of the brake ventilation ducts. At the front, the air intakes are on either side of the water radiator intake on the bumper, while at the rear, cooling demands required separate ducts. Part of the air flow is drawn in through an intake on the sill, while a second air flow is directed through an aperture in the rear bodywork, just ahead of the fixed wing.

The 296 Challenge’s cockpit benefits from Ferrari’s experience in both the single-make series and GT racing.

The ergonomic Ferrari 488 Challenge Evo steering wheel design has been retained with ad hoc improvements and other modifications.

In compliance with the international FIA racing standards, the roll cage has been meticulously designed down to the last detail, using the most sophisticated computation technologies.

The circular air con vents deliver an optimal flow to improve occupant comfort and can be adjusted in all directions, while the seat, which is derived from the 296 GT3, was developed to further improve ergonomics, particularly in the head, shoulder and elbow areas.

Record-breaking technology combined with brake-by-wire ABS Evo Track gives the 296 Challenge unrivalled braking performance.

The 296 Challenge’s braking system sets a new performance benchmark thanks to the world first adoption of CCM-R PLUS for the brake discs (408mm diameter at the front, 390 mm at the back). This solution is derived directly from the most extreme applications in motorsport, not least Formula 1, and towers above other carbon-ceramic brakes used in racing.

The manufacturing technology uses long carbon fibres in a 3D, multi-directional matrix to deliver a tangible increase in durability (a two-times improvement) and thermal conductivity (a three-times improvement) compared to a traditional CCM solution. The braking surface also has a special silicon carbide (SiC) ceramic coating which improves durability and delivers an excellent coefficient of friction in the most extreme conditions of use.

Disc cooling is by way of a complex layout of ventilation ducts, employing cutting-edge CFD computation techniques to optimise their geometry. The lifespan of the CCM-R PLUS disc is around three times that of the CCM version, with no tapering of performance whatsoever across its entire lifespan.

The ABS EVO Track brake-by-wire control system, introduced for the first time on the 296 GTB, has been evolved specifically for track use on the 296 Challenge. This new controller uses the information from the 6-way Chassis Dynamic Sensor (6w-CDS) to obtain a very precise estimation of speed and thus determine the target slip for all four wheels and optimise braking distribution. This in turn allows the longitudinal force of the tyres to be better exploited when braking in a straight line and on switchbacks (braking on turn-in), when the rear axle is subject to the natural compromise between braking performance and lateral stability.

At the same time, more accurate estimation allows repeatability of the manoeuvre around the target value to be maximised, reducing variations due to the tolerances of the components or the natural variability of test conditions, such as tarmac temperature. The combination of this version of the ABS EVO Track and the innovative CCM-R PLUS discs means the 296 Challenge delivers previously unthinkable performance in terms of both average deceleration and repeatability of performance, thus enhancing the car’s performance on the track.