Richard D. Rallison scite author profile

Richard D. Rallison

5Publications

27Citation Statements Received

1Citation Statement Given

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Affiliations

Wasatch Photonics (United States), Inotek Pharmaceuticals (United States), Unifor

Publications

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Holographic polarization-separation elements

Dickson¹,

Rallison²,

Yung

1994

Appl. Opt.

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Volume holographic optical elements exhibit a property that we call bidiffringence, in which the diffraction efficiency of the element is strongly dependent on the polarization of the incident beam. Dualelement, volume holographic polarization separators utilizing bidiffringence can provide high extinction ratios, and they can provide greater angular separation of the polarized beams and greater flexibility in the beam-separation parameters than conventional birefringent elements. We designed and constructed holographic polarization separators using dichromated gelatin as the holographic medium. Experimental results are compared with the results predicted by the Kogelnik coupled wave theory.

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Fabrication and testing of large area VPH gratings

Rallison¹,

Rallison²,

Dickson³

2003

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Remote detection of Raman scattering by use of a holographic optical element as a dispersive telescope

et al. 2000

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<title>Polarization properties of gelatin holograms</title>

Rallison¹,

Schicker²

1992

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Dichromated gelatin (DCG) exhibits variable changes in effective refractive index (n) from 1.54 before exposure to less than 1.25 as it expands during processing. This aerogel like effect causes aberrations in diffractive optics and Kogelnik's theory predicts strong polarization separation in gratings at many different angles other than 90 degrees1. The diffraction efficiency of both S and P polarizations at any angle is dependent on the product of thickness and index modulation while the angle inside the medium is dependent on n. We investigated predicted conditions where only one polarization would be diffracted and subsequently proved n varies from about 1.4 to 1.2 after processing and depends on the film thickness and processing procedures. Transmission gratings made at angles from 36 to 66 degrees were fit to mathematical models as proof of the phenomena,some performed with extinction ratios greater than 100: 1 . We were also able to demonstrate a similar range in conformal reflection structures and to design a novel polarizer. The calculation of exposure geometries for display holograms becomes more accurate when index change is included in the formulas but some results remain hard to explain.

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Cryogenic VPH gratings for the CELT/TMT

Blais-Ouellette

Guzman

Elgamil

et al. 2004

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Characterization of Volume Phase Holographic gratings at cryogenic temperatures have been conducted using a new test facility at Caltech. The new test bench includes a cryostat that allows large angles for incident and diffracted light. Gratings under tests are shielded from thermal background, and precisely and uniformly temperature controlled. Preliminary results are presented and show little temperature dependence of the efficiency function.

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