Have been reading this thread with interest and thought that I'd add some other points, which probably won't help but should add to the confusion lol...
Engine power is down to a number of things, the most important factor being engine design, i.e. the Clio's 4 cylinder 2 litre block ain't gonna generate a whole lot more power than when it was first designed without adding or replacing parts, turbos, superchargers, induction kits etc.
However, once you've got your engine fixed you can still do something to optimise the power by selecting the correct fuel. Unfortunately, as has been said previously, higher octane number doesn't directly result in higher power.
Petrol is a mixture of many different components. You don't just stick crude oil into a refinery and out pops some petrol. Each batch of petrol is blended at the refinery/terminal out of numerous different components. Hence each batch of 95 or 98 or 99 is different, but each will meet some basic specifications, one of which is octane number (its unlikely that a batch of petrol contains octane, its just a standard which measures knock resistance). Interstingly, the octane spec is a minimum spec, i.e. you could put 95 in your car and its actually 98! One of the critical elements of petrol, as well as octane number, is "energy density", i.e. how much energy is generated by burning a certain amount of petrol. Different components in the petrol have different energy densities. It is also typical that the higher octane number one of the components has, the higher the energy density. One of the best (and most expensive)components for increasing octane, is alkylate or reformate, both which have a slightly higher energy density than lower octane components, hence more bang for your buck.
The other interesting conundrum is ethanol, which is often blended into fuel (up to 10%) and is part of many governments "renewable energy plans" as it comes from crops rather than oil. Whlst ethanol has a high octane number, its energy density sucks compared to oil based petrol components. Hence, this will translate into a possible loss of power and/or worse fuel consumption. [Indy cars in the US that run on methanol compensate for this lack of energy density by utilising methanol's high octane number and running very high engine compression ratios.]
However, the final piece of confusion comes with premium fuels (aka super unleaded). Oil companies put a lot of research into fuels, particularly their premium fuels (v power, excellium, ultimate and the like) and its not just about increasing the octane number. The component mix may be different to improve fuel vapourisation characteristics, flame fronts, fuel burn profiles etc., the additive package will be more sophisticated, etc. Hence stick a premium fuel into a basic car and there should be an improvement in performance, but it will likely be unnoticeable unless on a rolling road. Stick it into a car designed for higher octane fuel and it should be notcieable on the road, albeit more obvious in forced induction cars (turbos and superchargers) than normally aspirated.
Hope you find this interesting.
