Engineering novel infrared glass ceramics for advanced optical solutions

K. Richardson, A. Buff, C. Smith, L. Sisken, J. David Musgraves, P. Wachtel, T. Mayer, A. Swisher, A. Pogrebnyakov, M. Kang, Carlo G. Pantano, Douglas Henry Werner, A. Kirk, S. Aiken, C. Rivero-Baleine

Research output: Chapter in Book/Report/Conference proceedingConference contribution

5 Citations (Scopus)

Abstract

Advanced photonic devices require novel optical materials that serve specified optical function but also possess attributes which can be tailored to accommodate specific optical design, manufacturing or component/device integration constraints. Multi-component chalcogenide glass (ChG) materials have been developed which exhibit broad spectral transparency with a range of physical properties that can be tuned to vary with composition, material microstructure and form. Specific tradeoffs that highlight the impact of material morphology and optical properties including transmission, loss and refractive index, are presented. This paper reports property evolution in a representative 20 GeSe2-60 As2Se3-20 PbSe glass material including a demonstration of a 1D GRIN profile through the use of controlled crystallization.

Original languageEnglish (US)
Title of host publicationAdvanced Optics for Defense Applications
Subtitle of host publicationUV through LWIR
EditorsPeter L. Marasco, Bjorn F. Andresen, Jay N. Vizgaitis, Jasbinder S. Sanghera, Miguel P. Snyder
PublisherSPIE
Volume9822
ISBN (Electronic)9781510600638
DOIs
StatePublished - Jan 1 2016
EventAdvanced Optics for Defense Applications: UV through LWIR - Baltimore, United States
Duration: Apr 17 2016Apr 19 2016

Other

OtherAdvanced Optics for Defense Applications: UV through LWIR
CountryUnited States
CityBaltimore
Period4/17/164/19/16

Fingerprint

Glass-ceramics
Glass ceramics
Infrared
engineering
ceramics
Infrared radiation
Engineering
glass
gradient index optics
optical materials
tradeoffs
Chalcogenide Glasses
Glass
Optical Materials
Photonic devices
Optical materials
Optical design
Optical Design
manufacturing
Crystallization

All Science Journal Classification (ASJC) codes

  • Electronic, Optical and Magnetic Materials
  • Condensed Matter Physics
  • Computer Science Applications
  • Applied Mathematics
  • Electrical and Electronic Engineering

Cite this

Richardson, K., Buff, A., Smith, C., Sisken, L., Musgraves, J. D., Wachtel, P., ... Rivero-Baleine, C. (2016). Engineering novel infrared glass ceramics for advanced optical solutions. 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 (Vol. 9822). SPIE. https://doi.org/10.1117/12.2224239
Richardson, K. ; Buff, A. ; Smith, C. ; Sisken, L. ; Musgraves, J. David ; Wachtel, P. ; Mayer, T. ; Swisher, A. ; Pogrebnyakov, A. ; Kang, M. ; Pantano, Carlo G. ; Werner, Douglas Henry ; Kirk, A. ; Aiken, S. ; Rivero-Baleine, C. / Engineering novel infrared glass ceramics for advanced optical solutions. Advanced Optics for Defense Applications: UV through LWIR. editor / Peter L. Marasco ; Bjorn F. Andresen ; Jay N. Vizgaitis ; Jasbinder S. Sanghera ; Miguel P. Snyder. Vol. 9822 SPIE, 2016.
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Richardson, K, Buff, A, Smith, C, Sisken, L, Musgraves, JD, Wachtel, P, Mayer, T, Swisher, A, Pogrebnyakov, A, Kang, M, Pantano, CG, Werner, DH, Kirk, A, Aiken, S & Rivero-Baleine, C 2016, Engineering novel infrared glass ceramics for advanced optical solutions. in PL Marasco, BF Andresen, JN Vizgaitis, JS Sanghera & MP Snyder (eds), Advanced Optics for Defense Applications: UV through LWIR. vol. 9822, SPIE, Advanced Optics for Defense Applications: UV through LWIR, Baltimore, United States, 4/17/16. https://doi.org/10.1117/12.2224239

Engineering novel infrared glass ceramics for advanced optical solutions. / Richardson, K.; Buff, A.; Smith, C.; Sisken, L.; Musgraves, J. David; Wachtel, P.; Mayer, T.; Swisher, A.; Pogrebnyakov, A.; Kang, M.; Pantano, Carlo G.; Werner, Douglas Henry; Kirk, A.; Aiken, S.; Rivero-Baleine, C.

Advanced Optics for Defense Applications: UV through LWIR. ed. / Peter L. Marasco; Bjorn F. Andresen; Jay N. Vizgaitis; Jasbinder S. Sanghera; Miguel P. Snyder. Vol. 9822 SPIE, 2016.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

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Richardson K, Buff A, Smith C, Sisken L, Musgraves JD, Wachtel P et al. Engineering novel infrared glass ceramics for advanced optical solutions. In Marasco PL, Andresen BF, Vizgaitis JN, Sanghera JS, Snyder MP, editors, Advanced Optics for Defense Applications: UV through LWIR. Vol. 9822. SPIE. 2016 https://doi.org/10.1117/12.2224239