Originally posted by hitech
Mace can you briefly describe what causes this?
My guess is change in airfoil shape in relation to the air stream, I.E. cross section acrross the air flow?
This is caused by simple geometry. The effect is somewhat small for small sweeps but is easily demonstrated with highly swept wings. Consider an airplane with wings swept back 45 degrees. If you yaw the airplane to the left by 45 degrees the right wing "sees" all of the relative wind while the left wing "sees" none. In effect, the right wing becomes both longer (with respect to the relative wind) and greater in cord while the left wing becomes almost non-existant. The right wing develops lift, the left does not and so the airplane rolls left with the rudder input. This is of course a gross exageration but the principal remains the same for small wing-sweep or side-slip angles. Also, you also get the effect with a straight wing because of wing mounting (high, mid, or low), pressure on the side of the fuselage (related to mounting) and blanking of the wing due to the fuselage.
Then there is chord and span, and the loading. I've always been looking into the wing shape effecting stall in banking. Do you have some words on that?
I'm assuming your talking about a steady-state bank as opposed to rolling into or out of one so there are two major issues. First of course is increased overall wing loading but the important aspect here is the nature of the stall, i.e., where does it originate and how does it propogate. The other comments about taper ignore other aspects such as changes in the airfoil section, wing twist (washout) and structural weight.
As Charge mentioned, a pure elliptical wing stalls all at one time which is not good. It's preferable for the wing to stall at the root before the wingtip for a couple of reasons. Because the tips provide a greater lever arm for roll a tip stall can result in a snap departure, also, tip stalls affect aileron effectiveness.
You see several different kinds of aerodynamic "fixes" to ensure the stall progresses from the root to the tip including mechanical devices (i.e., small tabs designed to "trip" the airflow on the inboard section of the wing), washout at the wingtips (to lower the angle of incidence, delay stall onset, and reduce structural loads), and changes in the airfoil section.
Generally speaking designers want a lot of taper to provide lots of room inboard for landing gear, guns and fuel while still getting elliptical lift distribution and reduced cruise drag of a high aspect ratio...all this in a package that is not too heavy or complex to build. A problem that you run into with a tapered wing is that the Cl is higher at the tip (because of the shorter cord) than inboard which means that for the same AOA the wingtip will reach Cl max and stall sooner, just the opposite of what you want so you have to counter this with washout. The downside of washout is increased drag. You can also change the airfoil from root to tip but that adds complexity. Everything's a tradeoff so small changes in airfoil are combined with washout so that the combined effect gives you what you want with less penalties.
One of the more bizarre "fixes" for the stall problem was a 1950s USAF design (I think it was based on the F-84) that had a reverse taper where the wing had smaller cord inboard with long cord wingtips.
Mace
