New Candidate Multicomponent Chalcogenide Glasses for Supercontinuum Generation

Goncalves, Claudia; Kang, Myungkoo; Sohn, Byoung-Uk; Yin, Gufan; Hu, Juejun; Tan, Dawn T. H.; Richardson, Kathleen

doi:10.3390/app8112082

Cited by 39 publications

(32 citation statements)

References 94 publications

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“…Due to the nonhomogeneous nature of the parent glasses at high PbSe levels, a further description of the starting glass morphology examined here is warranted, as this morphology will define the postheat‐treated GCs microstructure and as will be shown, the evolution of novel optical properties. As previously reported and noted above, the base glass morphology across the (GeSe 2 –3As 2 Se 3 ) 1− x PbSe x series exhibits liquid–liquid phase separation, and glasses within the midrange of compositions ( x ≈ 10–40 mol% PbSe) are dominated by metastable phase separation (droplet/matrix morphology) with a narrow range of unstable (spinodal decomposition) morphology . This behavior will ultimately influence the probability of successful conversion from glass to a low‐optical‐loss GC, and the magnitude of postheat‐treated physical property change.…”

Section: Resultssupporting

confidence: 77%

“…Postheat treatment microstructure was investigated on select compositions in order to determine the type and morphology of crystals that formed and the impact of the precipitated crystals on both the nanocomposite's refractive index and dispersion change and its transmission loss/scattering. Since parent base glasses with 20 and 40 mol% PbSe possess two distinct, inverse starting morphologies, transmission electron microscopy (TEM) images were collected from post‐heat‐treated samples of the two compositions along with corresponding XEDS images and selected area electron diffraction (SAED) patterns, to examine the resulting GC's nanoscale microstruture across this composition space. Figure a shows a dark field (DF) TEM image collected from a GC with 20 mol% PbSe where highly asymmetric, bright particles are distributed in a dark matrix.…”

Section: Resultsmentioning

confidence: 99%

“…While absolute index change is important in consideration of use for GRIN applications, optical designers typically rely on a material's dispersion over the target spectral window of use. Refractive indices for the base GAP‐Se glasses and GC materials were measured at six wavelengths across the IR spectral range at wavelengths of 1.88, 3.3, 4.515, 7.968, 9.294, and 10.717 µm, and measured indices were subsequently fitted with a Sellmeier function

(n = \sqrt{A + \frac{B λ^{2}}{λ^{2} - C^{2}} + \frac{D λ^{2}}{λ^{2} - E^{2}}})

and its coefficients of A , B , C , D , and E were determined . These data are shown in Figure a,b.…”

Section: Resultsmentioning

confidence: 99%

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Infrared Glass–Ceramics with Multidispersion and Gradient Refractive Index Attributes

Sisken

Kang

Veras

et al. 2019

Adv Funct Materials

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Infrared (IR) glass-ceramics (GCs) hold the potential to dramatically expand the range of optical material solutions available for use in bulk and planar optical systems in the IR. Current material solutions are limited to single-or polycrystalline materials and traditional IR-transparent optical glasses. GCs that can be processed with spatial control and extent of induced crystallization present the opportunity to realize an effective refractive index variation, enabling arbitrary gradient refractive index elements with tailored optical function. This work discusses the role of the parent glass composition and morphology on nanocrystal phase formation in a multicomponent chalcogenide glass. Through a two-step heat treatment protocol, a Ge-As-Pb-Se glass is converted to an optical nanocomposite where the type, volume fraction, and refractive index of the precipitated crystalline phase(s) define the resulting nanocomposite's optical properties. This modification results in a giant variation in infrared Abbe number, the magnitude of which can be tuned with control of crystal phase formation. The impact of these attributes on the GCs' refractive index, transmission, dispersion, and thermo-optic coefficient is discussed. A systematic protocol for engineering homogeneous or gradient changes in optical function is presented and validated through experimental demonstration employing this understanding.

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Section: Resultssupporting

confidence: 77%

Section: Resultsmentioning

confidence: 99%

(n = \sqrt{A + \frac{B λ^{2}}{λ^{2} - C^{2}} + \frac{D λ^{2}}{λ^{2} - E^{2}}})

and its coefficients of A , B , C , D , and E were determined . These data are shown in Figure a,b.…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Infrared Glass–Ceramics with Multidispersion and Gradient Refractive Index Attributes

Sisken

Kang

Veras

et al. 2019

Adv Funct Materials

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“…Thorpe (Thorpe, 1983) in 1983. Chalcogenides have also emerged as the materials of choice for 3D-X-point memory devices(Intel 1 ; Malventano 2 ; Tang et al, 2009), phase-change memory (Raoux and Wuttig, 2009), Continuum emission in the IR (Goncalves et al, 2018;Tremblay et al, 2018), optical fibers, and waveguides (Tang et al, 2015;Chen et al, 2019). The interplay between these applications and underlying basic science including topological phases (TP) now offers new prospects to tune material functionality with applications.…”

Section: Introductionmentioning

confidence: 99%

Evidence for a Correlation of Melt Fragility Index With Topological Phases of Multicomponent Glasses

et al. 2019

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Scores of glass compositions in the equimolar Ge x As x Se 100−2x ternary system are synthesized across the 0 < x < 26% range, and their homogeneity tracked by ex-situ Raman profiling. In synthesis, we alloyed the starting materials to homogenize until the variance, < ×> Ge , in Ge content "x," across a 1.5-g sized batch composition of <0.01% was realized. We undertook Modulated-DSC, Raman scattering, and molar volume experiments as a function of composition. Trends in T g (x) increase monotonically with x over the examined range, but the non-reversing enthalpy of relaxation at T g , H nr (x), displays a sharp square-well like reversibility window over the 9.5(2)% < x < 17.0(2)% range even in rejuvenated glasses. Trends in melt fragility index, m(x), established by measuring the T-dependence of the enthalpy relaxation time across T g , show a Gaussian-like variation with m(x) < 20 in the 9.5(2)% < x < 17.0(2)% range, and m > 20 outside that range, thus establishing a fragility window. The close correlation between the variations of m(x) and H nr (x) underscores that super-strong melts formed in the fragility window form Intermediate Phase (IP) glasses in the reversibility window, while fragile melts formed at non-IP compositions give rise to either flexible or stressed-rigid glasses. Molar volumes of glasses reveal a global reduction for IP glass compositions, thereby underscoring the compacted nature of the isostatically rigid networks formed in that phase. Evidence for specific dynamic features of the different phases is provided by molecular dynamics simulations, which indicate that the diffusivity is minuscule for x > 17% and increases substantially in the flexible phase. These results show that liquid dynamics and fragility encode glass topological phases in this ternary chalcogenide. The optimization of the glass-forming tendency for IP compositions, the stress-free nature of these networks, and the qualitative suppression of aging, are features that all point to their ideal nature. These ideas of IP glasses as ideal glasses are at variance with the notion that ideal glasses possess a low configurational entropy and form at T g values that approach the Kauzmann temperature. IP networks display, adaptability, high glass-forming tendency, stress-free nature, and high configurational entropy of networks.

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“…These considerations have a close bearing on their Topological phases (Mantisi et al, 2015;Boolchand and Goodman, 2017). In recent years these materials have found a niche in select advanced applications as phase change memory materials (Raoux, 2009), in 3D X-point memory 1 (Tang et al, 2009;Malventano, 2017), as materials of choice for optical fibers and waveguides in infrared optics and Supercontinuum emission (Goncalves et al, 2018;Tremblay et al, 2018), amongst many others. In these investigations, it would appear that glass functionality is apparently tied to their chemical composition, and more generally to the underlying Topological phases.…”

Section: Introductionmentioning

confidence: 99%

Correlating Melt Dynamics and Configurational Entropy Change With Topological Phases of AsxS100–x Glasses and the Crucial Role of Melt/Glass Homogenization

et al. 2019

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Melt dynamics and glass Topological phases of especially dry and homogenized binary As x S 100−x melts/glasses are examined in Modulated-DSC, Raman scattering, and volumetric experiments. In the S-rich glasses (12% < x < 23%), direct evidence for the elusive 537 cm −1 stretch vibrational mode of the Quasi-Tetrahedral (QT), S = As(S 1/2 ) 3 , local structure is observed in FT-Raman scattering once melts are homogenized and glasses cycled through T g +10 • C for an extended period. The enthalpy of relaxation at T g , H nr (x), fragility index, m(x), Molar volumes, V m (x) each display three distinct regimes of variation. Specifically, m(x) displays a Gaussian like global minimum (fragility window), and H nr (x) displays an abrupt square-well like variation (reversibility window), while V m (x) displays a Gaussian-like local minimum (Volumetric window) in the isostatically rigid phase (22.5% < x < 28.5%). At low x (<20%) in the Flexible phase, glasses are segregated with a S 8 -rich nanophase that decouples from the As-S glassy backbone. At medium x (22.5% < x < 28.5%) glassy backbones form an isostatically rigid phase displaying a vanishing H nr (x) term, and compacted structures with corresponding melts being superstrong (m < 20). At high x (28.5% < x < 40%) in the Stressed-Rigid phase, glasses possess an increasing H nr (x) term, and melts become increasingly fragile, with m(x)>20 as x increases. Taken together, these results underscore that superstrong melts yield isostatically rigid glasses, while fragile ones form either Flexible or Stressed-rigid glasses upon cooling. The onset of the rigidity transition near = 2.22, instead of the usual value of = 2.40, is identified with presence of QT local structures in addition to Pyramidal As(S 1/2 ) 3 local structures in the glassy backbone, and with a small but finite fraction of polymeric S n chains being decoupled from the backbone.

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New Candidate Multicomponent Chalcogenide Glasses for Supercontinuum Generation

Cited by 39 publications

References 94 publications

Infrared Glass–Ceramics with Multidispersion and Gradient Refractive Index Attributes

Infrared Glass–Ceramics with Multidispersion and Gradient Refractive Index Attributes

Evidence for a Correlation of Melt Fragility Index With Topological Phases of Multicomponent Glasses

Correlating Melt Dynamics and Configurational Entropy Change With Topological Phases of AsxS100–x Glasses and the Crucial Role of Melt/Glass Homogenization

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