First 10 minutes of this pod cast is a great explainer

Actually the whole thing is an excellent explanation

Well, yes interesting, CR, cyl. temp, valve angle, intake port sizes and shapes, flame speed, timing, very interesting. I missed the place where they mention about HI octane burning faster than LO octane. Just a quick google search, what burns faster Hi octane vs lo octane gasoline. On my computer, several different places says hi octane is refined more and creates a slower burning fuel. So still seems if the Lo and Hi octane fuels are ran through the same cyl. with sane valves, same valve angles, same comp., same intake components, same temps., the HI will burn slower than the LO. If you find a place that says different, please put it on here, it should be an interesting read.... I may listen to them again.

I enjoy this thread;fine tuning the ign. timing

Well, everything I've ever read is that the Octane rating of any fuel is a measure of resistance to knock aka detonation and nothing more. And the methodology used to determine octane rating doesn't measure anything else, including burn speed.

Pure ethanol has an octane rating of 109 has a faster linear (without turbulence) burn speed than 'pure' premium 91-94 octane gasoline. And 'pure' is in inverted commas because gasoline is a blended soup of hydrocarbons which can vary from refinery to refinery, brand to brand and even batch to batch. Not to mention what additives are added, or whether the gasoline is oxygenated or not.

Its not like back in the day they just added lead to the same fuel to raise octane. The chemistry is complicated.

Some higher octane fuels might burn slower than lower octane fuels, some might not. It depends on the fuel. And by burn speed we are talking about linear speed which is essentially how fast a flame would travel along a trail of gas poured on the ground. It's about a foot per second give or take an inch or two depending on the fuel and temperature.

To work in a spark ignited internal combustion engine that flame speed needs to be multiplied about 100 to 150 times. That's how more important turbulence is versus the linear flame speed of the fuel

While the difference between a slow burning high octane fuel vs a fast burn low octane fuel probably wouldn't be noticed (barring detonation) in the same engine, both fuels would still require around 28° advance in a Norton Commando and around 45° advance in an 85 Yamaha FZR750 because of differences in charge turbulence.

Which I guess is the point. Of all the variables that determine real world burn speed in any given engine, octane rating isn't really a biggie.
​​​
As to google searches. Have a look at this one
https://www.google.com/url?sa=t&source=web&rct=j&opi=89978449&url=https://www.speed-talk.com/forum/viewtopic.php%3Ft%3D42156&ved=2ahUKEwj66feVzKCFAxV eiVYBHYpGBvEQFnoECCgQAQ&usg=AOvVaw27JkD5vFvFYu-xaPYr9IVL

Yesterday I retarded the ignition by a few more degrees to the 750 and performance dropped off. The bike felt flatter in power delivery in a short test ride and I didn't do a pull chop. I did pull a plug, but it really hadn't run long enough to show any difference. I have returned the timing to the prior position, as I think I might have hit the sweet spot with my first adjustment. I'll do a few more experiments when I get the time to fine tune and post some pics and what the (subjective) results are.

I dun'no, Hemmings.com, not sure how they measure, Higher octane gas is processed through additional steps that farther refine the blend and cause it to burn more slowly than lower octane... No idea how they measure it and pretty sure they aren't talking racing fuel, think just pump gas. Also no way to know if Hemmings is telling the truth or not, nor if the folks telling me the same for yrs. and yrs were telling the truth. I can be sure LO octane pings and knocks (more like an explosion) and HI doesn't ping nor knock, seems less like an explosion.... Waaay too much for me to try to figure out.

Interesting you mentioned the FZR750 Yamaha. That head is one of the very worst I've ever come across for getting the charge burned. Not helped by the factory tolerances on the squish band meaning it's usually around 1.5mm clearance. The OW01 ignition has two advance peaks - 42 deg around 6500 rpm and 48 deg around 8500 to about 11000rpm where it drops to 30 deg. Presumably a rev limiter.
When the Loctite Yamaha team came here for the WSB rounds, I watched the team manager - Steve Parrish - blending fuel. Roughly 50/50 organiser supplied 100 octane and local 91 bought from the service station across the road from Manfield. I got talking to him as you do and told him I was aware of the poor combustion chamber shape and had a fair idea of why he was doing the blend - basically to speed up combustion and raise it's temperature for more complete combustion. He just laughed and said the dyno told them to do it.
Can't argue with that. I believe they were using Tony Scott engines so the squish would have been set up very tight.

The 5-valve Yamana Genesis engines were a bit a problem child. Cylinder filling was maximized to the detriment of combustion efficiency by virtually non-existent squish in the early engines and marginally more in later iterations. Kevin Cameron described them as follows:

"In practice, the five-valve FZR750 of 1985 experienced slow combustion; it needed quite early ignition timing of 45 degrees BTDC. Tuners noticed that this engine could be built either to accelerate or to deliver top-end, but not both. Strong acceleration requires high compression, but preventing knock may call for “squish”: areas of the piston crown which come very close to matching areas of the head at TDC. As such areas come together, with a typical clearance of 0.7mm, the mixture between them is rapidly “squished” out, creating jets that give the air-fuel charge a last-moment stir, helping accelerate combustion.

There was clearly some difference of opinion within Yamaha at the time they hired Valentino Rossi to ride their M1 MotoGP bike for the 2004 season. Masao Furusawa, the engineer assigned to provide the best possible ride for Rossi, had four bikes built for Vale to test; two with five valves, two with four valves, two with a flat (180-degree) crankshaft, and two with a crossplane (90-degree) crankshaft. Rossi liked best and went quickest on the four-valve/90-degree combo, so that’s how future M1s were built.

Later, Yamaha’s 1,000cc R1 production bike also switched from five to four valves, a design which continues to this day....

When Eddie Lawson won the 1993 Daytona 200 on a five-valve Yamaha, its valves had been relocated radially inward by clever welding and re-machining to form a tighter cluster around the central spark plug, possibly resulting in a faster-burning combustion chamber."


​

No, your're on to it. The reality is the burn speed isn't all that important, the ability for gasoline to take high compression without pinging/knocking is the important bit. That's what the octane number tells you.

I think I know why the octane number got associated with burn speed. Gasoline octane ratings are assigned to the fuel due it's knock resistance compared to a reference fuel. That reference fuel has two components, the hydrocarbon n-heptane which has poor knock resistance, and is assigned a 0 octane number and the hydrocarbon iso-octane which has excellent knock resistance and is assigned an octane rating of 100. These are the standards anti-knock resistance (the octane rating) is measured against.

If a gasoline has the same anti-knock characteristics of a reference mix of 91% iso-octane and 9% n-heptane, that gasoline is rated as 91 octane. If a gasoline has the same anti-knock characteristics of a reference mix of 89% iso-octane and 11% n-heptane the gasoline is rated as 89 octane.

What has been conflated or connected in folks minds is that the high reference hydrocarbon iso-octane rated at 100 octane burns slower than the low reference hydrocarbon n-heptane with 0 octane. Not because of their octane rating but because of the chemistry of the substances.

Indeed if the gasoline was only made from these two hydrocarbons (instead of the hydrocarbon soup that makes up the gasoline fraction of volatiles distilled at the refinery) then burn speed would slow as octane went up. But while it is true for the reference substances that are used to give octane ratings it isn't necessarily for the fuels that are quantified against them.

And that's the thing, a lot high octane gas may burn slower than lower octane gas. Or it might not... But the octane rating won't tell you for certain if they do.

Kind'f wish Hemmings hadn't made it so simple, that just makes it more confusing... They never mentioned sometimes HI will burn slower and sometimes faster.