Yes, you can apply an anti-reflective (AR) coating to an aspheric PMMA biconvex lens, but there are some specific technical considerations for PMMA (Acrylic) compared to glass or other plastics.

Because PMMA is a thermoplastic, it requires a "cold" coating process to ensure the lens doesn't warp or lose its aspheric precision during treatment.

The Coating Process for PMMA

Standard AR coating for glass involves high heat. For PMMA, the process is adapted:

• Vacuum Deposition: The coating is applied in a vacuum chamber using Physical Vapor Deposition (PVD).
• Low-Temperature Environment: The temperature must stay below the heat deflection point of PMMA (usually around 80°C to 90°C) to prevent deforming the aspheric curve.
• Hard Coating (Primer): PMMA is relatively soft. To make the AR coating stick and prevent it from cracking (crazing), a hard coat (HC) or lacquer primer is usually applied first. This acts as a bridge between the flexible plastic and the brittle AR minerals.

Challenges with Biconvex & Aspheric Shapes

Your specific lens geometry adds a few layers of complexity:

• Biconvex Uniformity: Since both sides are curved, the lens must be flipped or held in specialized "clocks" (fixtures) to ensure the coating thickness is even across both convex surfaces.
• Aspheric Steepness: Aspheric lenses often have varying steepness toward the edges. If the curve is very aggressive, the "throw" of the coating material in the vacuum chamber must be carefully managed so the edges get the same thickness as the center. If the thickness varies, you’ll see "color shifts" (e.g., the center looks green while the edges look purple).

Impact on Optical Performance

Adding AR to an aspheric PMMA lens is generally a great move for several reasons:

• Light Transmission: Standard PMMA transmits about 92% of light. A good AR coating can push this to 98% or 99%.
• Contrast Enhancement: For aspheric lenses (which are already designed to reduce spherical aberration), the AR coating further cleans up the image by removing "ghost images" caused by internal reflections between the two biconvex surfaces.
• Eliminating Glare: This is particularly helpful if the lens is being used in a lighted housing (like an LED magnifier), as it prevents the light source from reflecting off the lens surface into the user's eyes.