A variable aperture stop with no moving parts is disclosed. The aperture stop comprises a first region comprising a first optically transmissive medium, a second region comprising a second optically transmissive medium, and an electro-optical structure adapted to selectively switch the second region between a first state of optical transmissivity and a second state of optical transmissivity upon application of an electric potential thereto. The electro-optical structure comprises a top optically transmissive conductor, a bottom optically transmissive conductor positioned below and parallel to the top conductor so as to define a space therebetween, the space including the first region and the second region, and an electric voltage applicator coupled to the top conductor and adapted to apply an electric voltage to the top conductor that creates the electric potential between the top and bottom conductors.An apodizable, variable aperture stop with no moving parts is also disclosed. The aperture stop comprises a conductor having a perimeter, and an electro-optical structure coupled to the conductor. The electro-optical structure defines a first region within the perimeter of the conductor and is adapted to selectively switch the first region between a first state of optical transmissivity and a second state of optical transmissivity upon application of an electric potential thereto. The aperture stop produces an aperture having variable, optically transmissive regions representing an apodization when the first region is in the second state of optical transmissivity. Methods for manufacturing both aperture stops are also disclosed.