I'll go along with some of this... Here are some notes.Is this your speculation or is there a link? It’s interesting but I just don’t think it’s correct (I don’t have a link either). The idea that the prop might be cavitating could be somewhat plausible if the hp delivered were on the order of 10X but we are only talking about a 5 to 10 hp outboard here.
I got sold on what you are saying at one time from internet posts so have tried both high thrust and conventional swept back props and just don’t think its true at all that the swept back conventional blade prop cavitate. When props cavitate, you can feel it in a loss of power. I have a 9.8 hp with a conventional swept back blade prop and have slowly increased the throttle to see if some sort of cavatation can be felt - I’m fairly sure it just doesn’t happen.
I have also measured peak speed with both types of props on the same outboard / boat over a month period. The high thrust prop got the top speed of the boat about 4% higher. I.e., both props took the boat to theoretical hull speed. I think the high thrust prop got the boat up to slightly higher speed just because it allowed the outboard to turn at a higher rpm where it developed a little more hp. The high thrust prop however resulted in a lot more noise and vibration also because of the higher rpm. I took it off the outboard and went back to the conventional prop.
Any measured data saying the high thrust prop does something better on the displacement hull in forward and on these small hp outboards?
High thrust props are clearly better in reverse.
Once you get a displacement hull to hull speed, increases in power will provide diminishing returns as far as speed, but that energy will transfer into higher amplitude bow and stern waves. The waterline length holds the wave at a fixed wavelength, which can't go any faster through the water. Inputting more power thus causes increase of amplitude of bow and stern wave. In large ships, this can lead to unsupported areas amidships, and possible hull damage (this info from Chapmans.)
You are probably right, that the small outboard prop probably won't cavitate. However, I will stand behind my assertion that a high thrust prop of larger diameter, higher surface area blades, and lower pitch will provide benefits to a displacement hull. I will also agree that if a 5 or 6 hp motor will get a 21 foot displacement hull to hull speed at less than WOT, a 9.9hp won't help you much. If your motor can't get you to hull speed at WOT when you are bucking a strong wind, then in that case a higher HP motor probably can, since it may be spec'd with a different pitch prop (but, in these small sizes, probably not a bigger diameter prop.) Less pitch will allow RPM to build more quickly and provide more pushing power, but less high end speed.
I disagree that more horsepower will help bucking a current, because we will be talking about hull speed through the water. If your boat has a max hull speed of 5 knots, it will be awfully hard to buck a current of 5 knots. The energy of the current and the outboard will still be trying to move the boat through the water at 5 knots (even if speed over land was 0,) creating the bow and stern wavelength dependent on the waterline length. Increasing power to marginally increase speed over land will also increase wave amplitude while not materially increasing wave speed. Therefore, I feel it's easier for more HP to overcome windage than current.
I will also agree that a larger diameter prop can make for more vibration. I can feel a thum-thum-thum vibration with a high thrust prop that was not there with the speed prop. I can't say this is caused by the blade tips on the larger diameter high thrust being closer to the anti-ventilation plate, or the shape of the elephant ear blades, or what... My guess is that a blade tip vortex is now close enough to vibrate against the anti-ventilation plate...
Also, I think the typical spec prop will have increased blade rake. This has the effect of lifting the bow, which I don't feel is desirable in a displacement hull. The Evinrude doc referenced blow states this is desirable in a smaller planing hull to lift the bow and reduce drag from wetted surface area. My high thrust prop definitely has less rake.
There is a lot of info on pitch, rake, etc. in this Evinrude prop document. http://www.evinrude.com/Content/Pdf/en-US/propeller_selection_guide_767064.pdf#zoom=100 (I'm using this Evinrude doc because I had looked them up regarding previous posts discussing the Bombardier purchase of OMC, and the killing off of the Johnson brand in 2007.)
I still stand by my assertion that most smaller outboards are spec'd and intended for planing hull boats, like lightweight aluminum fishing boats. Our displacement sailboats will benefit from lower pitch, larger diameter, bigger blade area, less rake, and higher RPMs into optimal operating ranges. (Optimal operating ranges can see benefits in cleaner burning spark plugs with less fouling.)
One thing I have learned, regardless of prop pitch, is that many novice helmsmen find the boat moves too fast at idle, and they come in to the dock too hot. There is an easy way to control this with motors that have transmissions: shifting into neutral, and forward for bursts of power, will keep speeds at manageable levels. I've taught several people this technique, as my Grandfather taught me, and they find it makes docking so much easier than coming in mach 5 with their hair on fire...