Raman and CT scan mapping of chalcogenide glass diffusion generated gradient index profiles

G. P. Lindberg; R. H. Berg; J. Deegan; R. Benson; P. S. Salvaggio; N. Gross; B. A. Weinstein; D. Gibson; S. Bayya; J. Sanghera; V. Nguyen; M. Kotov

doi:10.1117/12.2223775

Raman and CT scan mapping of chalcogenide glass diffusion generated gradient index profiles

G. P. Lindberg
, R. H. Berg
, J. Deegan
, R. Benson
, P. S. Salvaggio
, N. Gross
, B. A. Weinstein
, D. Gibson
, S. Bayya
, J. Sanghera
, V. Nguyen
, M. Kotov

Physics

Rochester Precision Optics, LLC
SUNY Buffalo
Naval Research Laboratory
KeyW Corporation

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

11 Scopus citations

Abstract

Metrology of a gradient index (GRIN) material is non-trivial, especially in the realm of infrared and large refractive index. Traditional methods rely on index matching fluids which are not available for indexes as high as those found in the chalcogenide glasses (2.4-3.2). By diffusing chalcogenide glasses of similar composition one can blend the properties in a continuous way. In an effort to measure this we will present data from both x-ray computed tomography scans (CT scans) and Raman mapping scans of the diffusion profiles. Proof of concept measurements on undiffused bonded sheets of chalcogenide glasses were presented previously.1 The profiles measured will be of axially stacked sheets of chalcogenide glasses diffused to create a linear GRIN profile and nested tubes of chalcogenide glasses diffused to create a radial parabolic GRIN profile. We will show that the x-ray absorption in the CT scan and the intensity of select Raman peaks spatially measured through the material are indicators of the concentration of the diffusion ions and correlate to the spatial change in refractive index. We will also present finite element modeling (FEM) results and compare them to post precision glass molded (PGM) elements that have undergone CT and Raman mapping.

Original language	English
Title of host publication	Advanced Optics for Defense Applications
Subtitle of host publication	UV through LWIR
Editors	Peter L. Marasco, Bjorn F. Andresen, Jay N. Vizgaitis, Jasbinder S. Sanghera, Miguel P. Snyder
Publisher	SPIE
ISBN (Electronic)	9781510600638
DOIs	https://doi.org/10.1117/12.2223775
State	Published - 2016
Event	Advanced Optics for Defense Applications: UV through LWIR - Baltimore, United States Duration: Apr 17 2016 → Apr 19 2016

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	9822
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Advanced Optics for Defense Applications: UV through LWIR
Country/Territory	United States
City	Baltimore
Period	04/17/16 → 04/19/16

Keywords

Chalcogenide
Glass
Gradient Index Optics (GRIN)
Lenses
Metrology

Access to Document

10.1117/12.2223775

Cite this

Lindberg, G. P., Berg, R. H., Deegan, J., Benson, R., Salvaggio, P. S., Gross, N., Weinstein, B. A., Gibson, D., Bayya, S., Sanghera, J., Nguyen, V., & Kotov, M. (2016). Raman and CT scan mapping of chalcogenide glass diffusion generated gradient index profiles. In P. L. Marasco, B. F. Andresen, J. N. Vizgaitis, J. S. Sanghera, & M. P. Snyder (Eds.), Advanced Optics for Defense Applications: UV through LWIR (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 9822). SPIE. https://doi.org/10.1117/12.2223775

Lindberg, G. P. ; Berg, R. H. ; Deegan, J. et al. / Raman and CT scan mapping of chalcogenide glass diffusion generated gradient index profiles. Advanced Optics for Defense Applications: UV through LWIR. editor / Peter L. Marasco ; Bjorn F. Andresen ; Jay N. Vizgaitis ; Jasbinder S. Sanghera ; Miguel P. Snyder. SPIE, 2016. (Proceedings of SPIE - The International Society for Optical Engineering).

@inproceedings{014072b046124caf8452634fdf2fe6fe,

title = "Raman and CT scan mapping of chalcogenide glass diffusion generated gradient index profiles",

abstract = "Metrology of a gradient index (GRIN) material is non-trivial, especially in the realm of infrared and large refractive index. Traditional methods rely on index matching fluids which are not available for indexes as high as those found in the chalcogenide glasses (2.4-3.2). By diffusing chalcogenide glasses of similar composition one can blend the properties in a continuous way. In an effort to measure this we will present data from both x-ray computed tomography scans (CT scans) and Raman mapping scans of the diffusion profiles. Proof of concept measurements on undiffused bonded sheets of chalcogenide glasses were presented previously.1 The profiles measured will be of axially stacked sheets of chalcogenide glasses diffused to create a linear GRIN profile and nested tubes of chalcogenide glasses diffused to create a radial parabolic GRIN profile. We will show that the x-ray absorption in the CT scan and the intensity of select Raman peaks spatially measured through the material are indicators of the concentration of the diffusion ions and correlate to the spatial change in refractive index. We will also present finite element modeling (FEM) results and compare them to post precision glass molded (PGM) elements that have undergone CT and Raman mapping.",

keywords = "Chalcogenide, Glass, Gradient Index Optics (GRIN), Lenses, Metrology",

author = "Lindberg, \{G. P.\} and Berg, \{R. H.\} and J. Deegan and R. Benson and Salvaggio, \{P. S.\} and N. Gross and Weinstein, \{B. A.\} and D. Gibson and S. Bayya and J. Sanghera and V. Nguyen and M. Kotov",

note = "Publisher Copyright: {\textcopyright} 2016 SPIE.; Advanced Optics for Defense Applications: UV through LWIR ; Conference date: 17-04-2016 Through 19-04-2016",

year = "2016",

doi = "10.1117/12.2223775",

language = "English",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Marasco, \{Peter L.\} and Andresen, \{Bjorn F.\} and Vizgaitis, \{Jay N.\} and Sanghera, \{Jasbinder S.\} and Snyder, \{Miguel P.\}",

booktitle = "Advanced Optics for Defense Applications",

address = "United States",

}

Lindberg, GP, Berg, RH, Deegan, J, Benson, R, Salvaggio, PS, Gross, N, Weinstein, BA, Gibson, D, Bayya, S, Sanghera, J, Nguyen, V & Kotov, M 2016, Raman and CT scan mapping of chalcogenide glass diffusion generated gradient index profiles. in PL Marasco, BF Andresen, JN Vizgaitis, JS Sanghera & MP Snyder (eds), Advanced Optics for Defense Applications: UV through LWIR. Proceedings of SPIE - The International Society for Optical Engineering, vol. 9822, SPIE, Advanced Optics for Defense Applications: UV through LWIR, Baltimore, United States, 04/17/16. https://doi.org/10.1117/12.2223775

Raman and CT scan mapping of chalcogenide glass diffusion generated gradient index profiles. / Lindberg, G. P.; Berg, R. H.; Deegan, J. et al.
Advanced Optics for Defense Applications: UV through LWIR. ed. / Peter L. Marasco; Bjorn F. Andresen; Jay N. Vizgaitis; Jasbinder S. Sanghera; Miguel P. Snyder. SPIE, 2016. (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 9822).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Raman and CT scan mapping of chalcogenide glass diffusion generated gradient index profiles

AU - Lindberg, G. P.

AU - Berg, R. H.

AU - Deegan, J.

AU - Benson, R.

AU - Salvaggio, P. S.

AU - Gross, N.

AU - Weinstein, B. A.

AU - Gibson, D.

AU - Bayya, S.

AU - Sanghera, J.

AU - Nguyen, V.

AU - Kotov, M.

PY - 2016

Y1 - 2016

N2 - Metrology of a gradient index (GRIN) material is non-trivial, especially in the realm of infrared and large refractive index. Traditional methods rely on index matching fluids which are not available for indexes as high as those found in the chalcogenide glasses (2.4-3.2). By diffusing chalcogenide glasses of similar composition one can blend the properties in a continuous way. In an effort to measure this we will present data from both x-ray computed tomography scans (CT scans) and Raman mapping scans of the diffusion profiles. Proof of concept measurements on undiffused bonded sheets of chalcogenide glasses were presented previously.1 The profiles measured will be of axially stacked sheets of chalcogenide glasses diffused to create a linear GRIN profile and nested tubes of chalcogenide glasses diffused to create a radial parabolic GRIN profile. We will show that the x-ray absorption in the CT scan and the intensity of select Raman peaks spatially measured through the material are indicators of the concentration of the diffusion ions and correlate to the spatial change in refractive index. We will also present finite element modeling (FEM) results and compare them to post precision glass molded (PGM) elements that have undergone CT and Raman mapping.

AB - Metrology of a gradient index (GRIN) material is non-trivial, especially in the realm of infrared and large refractive index. Traditional methods rely on index matching fluids which are not available for indexes as high as those found in the chalcogenide glasses (2.4-3.2). By diffusing chalcogenide glasses of similar composition one can blend the properties in a continuous way. In an effort to measure this we will present data from both x-ray computed tomography scans (CT scans) and Raman mapping scans of the diffusion profiles. Proof of concept measurements on undiffused bonded sheets of chalcogenide glasses were presented previously.1 The profiles measured will be of axially stacked sheets of chalcogenide glasses diffused to create a linear GRIN profile and nested tubes of chalcogenide glasses diffused to create a radial parabolic GRIN profile. We will show that the x-ray absorption in the CT scan and the intensity of select Raman peaks spatially measured through the material are indicators of the concentration of the diffusion ions and correlate to the spatial change in refractive index. We will also present finite element modeling (FEM) results and compare them to post precision glass molded (PGM) elements that have undergone CT and Raman mapping.

KW - Chalcogenide

KW - Glass

KW - Gradient Index Optics (GRIN)

KW - Lenses

KW - Metrology

UR - https://www.scopus.com/pages/publications/84984710518

U2 - 10.1117/12.2223775

DO - 10.1117/12.2223775

M3 - Conference contribution

AN - SCOPUS:84984710518

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Advanced Optics for Defense Applications

A2 - Marasco, Peter L.

A2 - Andresen, Bjorn F.

A2 - Vizgaitis, Jay N.

A2 - Sanghera, Jasbinder S.

A2 - Snyder, Miguel P.

PB - SPIE

T2 - Advanced Optics for Defense Applications: UV through LWIR

Y2 - 17 April 2016 through 19 April 2016

ER -

Lindberg GP, Berg RH, Deegan J, Benson R, Salvaggio PS, Gross N et al. Raman and CT scan mapping of chalcogenide glass diffusion generated gradient index profiles. In Marasco PL, Andresen BF, Vizgaitis JN, Sanghera JS, Snyder MP, editors, Advanced Optics for Defense Applications: UV through LWIR. SPIE. 2016. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.2223775

Raman and CT scan mapping of chalcogenide glass diffusion generated gradient index profiles

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Keywords

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