Gradient Index Lenses

Holographic photopolymers were developed, as the name implies, for holography. ÌýHowever, they can be programmed with a variety of gradient index (GRIN) structures including diffractive and refractive lenses. ÌýThe polymers self develop in respnse to light, enabling complex 3D GRIN structure not possible with traditional processes that rely on diffusion. ÌýWe have created a number of specialized exposure systems operating from the micron to the 10 mm scale to implenent unusual optical functions, correct for aberrations or fabricate arbitrary arrays. ÌýThe polymers can be cast on to other optical components and areÌýnaturally soft, creating opportunities for in vivo medical imaging.

The team

  • David Glugla
  • Johnny Hergert
  • Adam Urness
  • Chunfang Ye

Learn more

  • A.C. Urness, K. Anderson, W. L. Wilson and R. R. McLeod,ÌýÌýOptics ExpressÌý23, pp. 264–273, 2015.
  • C. Ye, R. R. McLeod,Ìý, Optics Letters 33, 2575-2577, 2008.
  • Chunfang Ye, Doctor of Philosophy in Electrical Engineering,Ìý, University of Colorado, 2012

This work has been generously funded by

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NIH

Sample results

Picture showing parabolic profile of a GRIN lens

Quantative index measurment of a single GRIN lens obtained by scanning differential transmission microscopy. The profile is parabolic, implementing a traditional GRIN lens

Differential interference contrast microfraph of a 1mm thick polymer GRIN lens array

Differential interference contrast micrograph of a 1 mm thick polymer GRIN lens array. Each lenslet is formed by a single exposure with an approximately quadratic light intensity. The array is formed by stepping and repeating the exposure on a precision stage.

GRIN Fresnel

Differential interference contrast micrograph of a GRIN Fresnel lens exposed by projecting a gray-scale image from a DMD spatial light modulator.