High end scopes are now using high index lenses to reduce the number of surfaces the light has to pass thru. ED glass. Old camera lenses sometimes used thorium/radium doped glass.
Heavier glass with a higher index of refraction. I have a couple. After a few years they have to be de-yellowed with UV light.
Anyway there is a way to TEST your hypothesis without an optical bench. A digital camera that has the capability to create a histogram of the incoming light. You can adapt the camera to the eyepiece of the scope. Focus on a darkesh scene and have some off axis light that you can move and adjust. The histogram will show you more light coming in. That is how good the lens stops and antireflective coatings, and the 'BLACK' interior prevent this unwanted light.
Off axis light makes the scene appear brighter. More light is brighter but the desired image is washed out by this unwanted light. Take my word for it
it is unwanted.
My red light example can easily be duplicated with a digital camera at the eyepiece end of a rifle scope. Find a darkish area and set up a dozen rabbits in a row. Dead rabbits, frozen rabbits, or even paper rabbits
Make the row wider than your field of view at mid power on your scope.
Illuminate the rabbits with a green light. Use a Red light to illuminate the rabbits outside your field of view. Check the overall histogram of the camera output and look for off axis red light.
In this experiment Green is the desired image, Red just degrades it.
The sun and sometimes the moon can be big issues and easily noticed. Lesser light pollution might not be as noticeable but it does reduce image quality.
Most scopes, camera lenses are manufactured with marketable specifications.
A 6-24X50mm scope will likely LOOK better at less than maximum magnification.
The 50mm objective is 'good enough' out to the edge to be 'good enough' at maximum magnification. Center of lens sharpness is almost always better than edge sharpness.
Even with $30,000 camera lenses. Good Enough is good enough. Spend more get a little better Good Enough
There may be slightly better ways of designing scope optics, often with better types of glass, glass shapes, but for now black is good to help out the optic designs where they fall short.
Take a look into aperture reducers for large objectives and what they do for image sharpness and depth of field.
Find some on-line ray tracing diagrams showing a telescope (rifle scope). Straight lines from the object or total field of view to the objective lens sets the aperture of the scope. Nothing outside the aperture is desired. A 50mm objective rifle scope will have a shield about 58-60mm in diameter. This will limit viewing angle to just a few degrees. Stack two 4 inch long sun shields and you will Vignette as you decrease power on the scope. This cuts into the field of view. A dim area at the outside edges of the scope. By reducing the TOTAL amount of light entering the scope (losses at the edge) the remaining area appears brighter. Why? The eye adjusts to the total scene. Removing edge lighting and the eye adjusts to the remaining light.
It just might look brighter with the narrower illuminated spot zone.
The camera histogram will show less light but the center will be brighter than the edge.
