Wellthe best news is that you are not alone on this issue, it has been beat to death so much by so many that a few simple googl;es like
light wavelengths absorbed by mirror
and
efficiency of mirror reflecting light
brought up several mj forum post lots of ask a scientist, lots of yahoo answers making it difficult to find real or good answers,,,,,,,,,,,,,,,,,,
But I found them
from Edmonds a company that selld optics and mirrors
An example of a second surface mirror is a common bathroom mirror. A second surface mirror is usually not preferred over a first surface mirror in most applications due to many inherent characteristics. A second surface mirror suffers from lower reflectivity due to absorption by the glass (especially in the UV and IR). In addition, there are often ghost images due to two reflections (one from the glass, one from the coating) and an increased optical path length since light passes through the glass twice (once to reach the coating and once to reflect back). A second surface mirror does have the advantage of increased protection of the coating. If the coating is very delicate or the environment is harsh, a second surface
link,
http://74.125.155.132/search?q=cache:3Rx-jeuqLm8J:www.edmundoptics.com/technical-support/optics/gratings-and-fibers/mirrors/faq-on-optics-part-2-polarizers/+efficiency+of+mirror+reflecting+light&cd=55&hl=en&ct=clnk&gl=us
this was interesting,,
No, regular mirrors reflect the
entire range of visible light. With no tinting to absorb extraneous wavelengths, mirrors will take any wavelength of light and bounce it back off their surface. Just as any "white" object would do. The difference, though, is this: mirrors bounce light back in a very specific pattern.
So if you put a piece of white paper and a mirror next to each other on a table, they certainly won't look the same. The piece of paper will bounce electromagnetic radiation back in a scattered, haphazard fashion, one that our brain perceives as white. The mirror will bounce the exact same range of electromagnetic radiation back off its surface, but will do so in an organized fashion that produces a reflection of the light source, rather than white light. But the simple fact is that neither the mirror nor the paper is absorbing anything along the visible spectrum of electromagnetic radiation. So in terms of how we normally define color, they're both "white."
found here,
http://everything2.com/title/What+color+is+a+mirror%3F
this statement was made in context in a paper about making a better mirror
Ordinary mirrors of silver-coated glass reflect light from different directions, but aren't very efficient because they absorb some of the light as well as reflect it.
link
http://www.photonicsonline.com/article.mvc/3M-Creates-Highly-Efficient-Polymer-Based-Mir-0002?VNETCOOKIE=NO
My own experiment was very simple and did not involve a light meter (so I am curious about other posters test),,,I took a very bright flashlight and shined at a mirror and at a sheet of mylar, the mirror reflected the beam of light back at me and it showed on the opisite wall as a beam.
The mylar simply just lit up no beam was visible on the mylar or the opisite wall and (most notable) the entire sheet of mylar lit up the mirror did not
I would suggest that it is well known that there is a benefit to have UVB in our areas and since mirrors absorb uv rays I would guess that it is the reason that mirrors are considered bad?
of the light being reflected directly on the wall (in your case a square) then take a piece of white cardboard or even better mylar... and you will see that it reflects lights evenly and prob lite up the room a bit this is not my cooked up or copied conclusion its FACT, if mirrors were better for reflecting light wouldnt they be used in pro grow ops in europe?... you would have heard via word of mouth that mirrors reflect/disperse light "best". Dont get me wrong thinking outside the box is needed but.... which is better a nickle plated piece of glass or something made by those silly people who fly into space?? 
