Ion Exchange Technologies

Kilislioğlu, Ayben

doi:10.5772/2925

Cited by 29 publications

(4 citation statements)

References 157 publications

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“…Success has been obtained with many other transition metal salts, for example, palladium(II) [4–5], rhodium(III) [6], copper(II) [7], silver(I) [8], and gold(I)/(III) [9–12]. While less toxic than mercury, such catalysts are still environmental hazards and tend to be costlier [13–14]. The iodine-mediated hydration described herein is a viable solution to these issues [15–16].…”

Section: Resultsmentioning

confidence: 99%

Iodine-mediated hydration of alkynes on keto-functionalized scaffolds: mechanistic insight and the regiospecific hydration of internal alkynes

Lee

Jones

Nkengbeza

et al. 2019

Beilstein J. Org. Chem.

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An iodine-mediated hydration reaction of alkynes serves as a green alternative to metal-catalyzed procedures. Previous work has shown that this method works well with terminal alkynes on keto-functionalized scaffolds, including 1,3-dicarbonyls and their heteroatom analogues. It was hypothesized that the reaction proceeds through a 5-exo-dig neighboring group participation (NGP) cyclization and an α-iodo intermediate. The work described herein probes the existence of the intermediate through NMR investigations and explores the scope of the hydration process with internal alkynes. The NMR experiments confirm the existence of the α-iodo intermediate, and methodology studies demonstrate that alkyl-capped, asymmetric, internal alkynes undergo a regiospecific hydration, also via the 5-exo-dig NGP pathway.

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Section: Resultsmentioning

confidence: 99%

Iodine-mediated hydration of alkynes on keto-functionalized scaffolds: mechanistic insight and the regiospecific hydration of internal alkynes

Lee

Jones

Nkengbeza

et al. 2019

Beilstein J. Org. Chem.

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“…Over the last few decades, many studies in doping metal nanoparticles into a glass substrate investigated the thermal ion-exchange (IE) process. − In this process, the glasses are covered by molten salt, including metal ions, which replace alkali ions in the glass matrix during a thermal process. − Penetration of metal ions such as silver ions (Ag + s) into a glass induces positive stress due to the different ionic radius and polarizability from those of sodium ions (Na + s), accompanied by modification of its refractive index. − Changing the molten salt composition makes it possible to manipulate the refractive index of the glass induced by the IE process …”

Section: Introductionmentioning

confidence: 99%

“…The refractive index of Ag + /Na + ion-exchanged glasses depends on the concentration of Ag + s introduced into the glass matrix. − Ag + s, driven into the glass matrix from molten salt by a thermal process, penetrate a few micrometers into the glass matrix, but they are not often uniformly distributed through the glass . Therefore, the concentration of silver in the glass matrix can be represented by a gradient profile, which rapidly decreases inward .…”

Section: Introductionmentioning

confidence: 99%

“…One of the significant challenges of using ion-exchanged glasses as a waveguide is coupling the light beam into the waveguides. ,, Among different coupling mechanisms, the prism coupling approach and periodic nanostructures are the most appropriate methods for coupling the light beam into ion-exchanged glasses. ,,, In the prism coupling technique, a high-index prism guides incident light into the waveguide. For this purpose, phase matching must occur between the incident wave and guided mode .…”

Section: Introductionmentioning

confidence: 99%

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Coupling Light in Ion-Exchanged Waveguides by Silver Nanoparticle-Based Nanogratings: Manipulating the Refractive Index of Waveguides

Aslani

Talebi

Vashaee

2022

ACS Appl. Nano Mater.

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We report the fabrication and properties of ion-exchanged optical waveguides based on low-cost soda-lime glasses embedded with silver ions and nanoparticles. Using the thermal ion-exchange process, we embed silver ions into soda-lime glasses by covering the glasses with different ratios of AgNO3:NaNO3 molten salt (2:98, 4:96, and 6:94) at 350 °C. The ion-exchanged glasses containing silver nanoparticles were characterized by using X-ray fluorescence spectroscopy, UV–visible spectroscopy, the X-ray diffraction technique, X-ray photoelectron spectroscopy, and atomic force microscopy of the surface. It is shown that the ion-exchanged glasses make low-loss optical waveguides. Furthermore, we evaluate the refractive index of ion-exchanged waveguides by laser coupling into the waveguide. For this purpose, the ion-exchanged glasses were coated with a silver chloride thin film loaded with silver nanoparticles (Ag-AgCl). When the Ag-AgCl layer is irradiated by a polarized coherent light beam, silver nanograting is formed on the surface of the ion-exchanged glass, and the light beam is simultaneously coupled into the glass. The line-space of nanograting determines the effective refractive index of the ion-exchanged glass. Although we expected the sample with the highest ratio of AgNO3:NaNO3 salt (6:94) to have the largest refractive index, our results demonstrate that the ion-exchanged sample with 4% AgNO3 has the largest effective refractive index, which is due to the penetration of more silver ions and nanoparticles in the glass matrix. Therefore, it is further demonstrated that using a Ag-AgCl layer on an ion-exchanged waveguide is an effective method for coupling light into the waveguides and measuring its refractive index. The mentioned coupling technique in combination with easily fabricated ion-exchanged waveguide has served as an excellent platform for applications in integrated optical circuits.

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