Glass–polymer superlattice for integrated optics

Kakkar, Tarun; Bamiedakis, N.; Fernandez, Toney Teddy; Zhao, Zhanxiang; Irannejad, Mehrdad; Steenson, Paul; Jha, Animesh; Penty, R.V.; White, I.H.; Jose, Gin

doi:10.1117/1.oe.53.7.071818

Cited by 6 publications

(2 citation statements)

References 19 publications

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“…In the context of thin film fabrication, both the standard excimer at 193nm and 800nm Ti-sapphire lasers, pulsed in nano and femto second regimes, respectively were used [3][4][5]. The pulse width and repetition rates of excimer and Ti-sapphire lasers were in sub s and 1-20Hz and 100fs and 250-1KHz, respectively.…”

Section: Methodsmentioning

confidence: 99%

“…In this glass, the total rare-earth ion concentration can be several weight percent which for the pulsed laser deposition conditions were optimized at 1.1mol% Er 2 O 3 , 1.5mol% Yb 2 O 3 , and 0.9 mol% CeO 2 . The details of thin film deposition and characterization using excimer laser is described elsewhere [5,6]. For PDMS materials preparation and thin film deposition on silica substrate was attempted by controlling the cracks due to thermal mismatch [4], and then optimized by forming nanometer scale amorphous superlattice structures of PDMS with Er 3+ -ion doped phosphate modified tellurite glass [7].…”

Section: Methodsmentioning

confidence: 99%

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Photonic waveguide engineering using pulsed lasers — A novel approach for non-clean room fabrication!

Jha

Jose

Murray

et al. 2014

2014 16th International Conference on Transparent Optical Networks (ICTON)

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Over the last 25 years has seen an unprecedented increase in the growth of phonic components based on semiconductor and solid-state lasers, glass and polymer based optical fibres, and organic LEDs. Emerging technology for component engineering must embed dissimilar materials based devices into an integrated form which is more efficient. In this article, we demonstrate techniques for overcoming the materials related limitations by adopting thin-film deposition techniques based on nano-and femto-second pulsed laser deposition. Three examples of thin-film fabrication for near-IR devices using Er 3+ -ion doped glass-on-GaAs, Er 3+ -ion doped glass-polydimethyl silane (PDMS) polymer, and Tm 3+ -doped nano-silicon thin films and gain medium waveguides are discussed. The modelling tools are used a priori for waveguide engineering for ascertaining the extent to which the structural incompatibility due to mismatch strain can be minimized. The structure and spectroscopic properties of Er 3+ -ion doped thin films on silica, polymer, and semiconductor GaAs substrates were examined in detail and are reported. We demonstrate the formation of glass-polymer superlattice structures for waveguide fabrication for overcoming the solubility limits of Er 3+ -ions in PDMS polymers. For inscribing waveguides in superlattice structures and nano silicon structures, the ablation machining using fs-pulsed Ti-sapphire laser was used, and the resulting spectroscopic properties of waveguides are discussed.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Photonic waveguide engineering using pulsed lasers — A novel approach for non-clean room fabrication!

Jha

Jose

Murray

et al. 2014

2014 16th International Conference on Transparent Optical Networks (ICTON)

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Glasses for Photonic Integration

DeCorby

Irannejad

2017

Springer Handbook of Electronic and Photonic Materials

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Inorganic glasses form the backbone of dielectric materials in optics and photonic applications. In addition to offering a range of transparency windows, intrinsic physical properties of glass materials also offer flexibility of processing for the realization of fibers, films, and shaped optical elements. Traditionally, the main role of glass has been as an optically passive material. However, a significant attribute of glass as an optical medium is to host dopants such as nanoparticles or active ions in a unique chemical environment, which can be engineered via processing, by controlling the geometry to develop active and passive photonic devices, such as laser, amplification, storage media, optical switching, frequency conversion, and sensor media. For photonic integration, many of the attributes of glasses are particularly compelling. Glasses allow numerous options for thin film deposition and integration on arbitrary platforms. The possibility of controlling the thermal and flow properties, e.g., expansion coefficient, crystallization, and viscosity during film deposition of a glass may allow realization of extremely low-loss microphotonic waveguides, photonic crystals, and microcavities. The metastable nature of glass can enable the direct patterning of photonic elements by energetic beams. This chapter provides an overview of these unique properties of glasses, from the perspectives of the technology options they afford and the 41.1 Main Attributes of Glasses as Photonic Materials.

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Effect of ZnO nanoparticles on the Judd–Ofelt and radiative parameters of Sm3+ ions in sol–gel silica matrix

Dawngliana,

Bhujel,

Rai

2024

Appl. Phys. A

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Glass–polymer superlattice for integrated optics

Cited by 6 publications

References 19 publications

Photonic waveguide engineering using pulsed lasers — A novel approach for non-clean room fabrication!

Photonic waveguide engineering using pulsed lasers — A novel approach for non-clean room fabrication!

Glasses for Photonic Integration

Effect of ZnO nanoparticles on the Judd–Ofelt and radiative parameters of Sm3+ ions in sol–gel silica matrix

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Glass–polymer superlattice for integrated optics

Cited by 6 publications

References 19 publications

Photonic waveguide engineering using pulsed lasers &#x2014; A novel approach for non-clean room fabrication!

Photonic waveguide engineering using pulsed lasers &#x2014; A novel approach for non-clean room fabrication!

Glasses for Photonic Integration

Effect of ZnO nanoparticles on the Judd–Ofelt and radiative parameters of Sm3+ ions in sol–gel silica matrix

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Photonic waveguide engineering using pulsed lasers — A novel approach for non-clean room fabrication!

Photonic waveguide engineering using pulsed lasers — A novel approach for non-clean room fabrication!