Low-loss chalcogenide waveguides for chemical sensing in the mid-infrared

Ma, Pan; Choi, Duk‐Yong; Yu, Yi; Gai, Xin; Yang, Zhiyong; Debbarma, Sukanta; Madden, Steve; Luther‐Davies, Barry

doi:10.1364/oe.21.029927

Cited by 159 publications

(99 citation statements)

References 30 publications

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“…A good CE of -30 dB is obtained over 20 nm of total bandwidth. The dispersion estimated from the conversion bandwidth is D = -183 ps/(nm km), and compares well with the value D = -196 ps/(nm km) retrieved from COMSOL simulations, where we used the actual fiber geometry and Sellmeier equation for Ge 11.5 As 24 Se 64.5 [10]. Fig.2b shows CE values at different pump power levels for a 6 nm pump-signal detuning.…”

Section: Introductionsupporting

confidence: 76%

Small core Chalcogenide photonic crystal fiber for mid-infrared wavelength conversion: experiment and design

Xing

Grassani

Kharitonov

et al. 2016

Conference on Lasers and Electro-Optics

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Section: Introductionsupporting

confidence: 76%

Small core Chalcogenide photonic crystal fiber for mid-infrared wavelength conversion: experiment and design

Xing

Grassani

Kharitonov

et al. 2016

Conference on Lasers and Electro-Optics

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“…The recently demonstrated suspended Ge membrane devices hold the potential to fully utilize the broad transparency band of Ge, although optical functions of these devices at >3-μm wavelength are yet to be realized [29,30]. Infrared-transparent chalcogenides and halides, on the other hand, can be monolithically deposited on Si or dielectric substrates via thermal evaporation or sputtering, with waveguides defined by using two compositions of different indices as core and cladding layers ( Figure 3K-L) [16,[31][32][33][34][35][36][37][38]. Compared to Si or Ge, the drawback of this approach is that chalcogenides and halides are generally not considered compatible with CMOS foundry processes.…”

Section: Waveguides and Passive Devicesmentioning

confidence: 99%

Mid-infrared integrated photonics on silicon: a perspective

et al. 2017

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Abstract:The emergence of silicon photonics over the past two decades has established silicon as a preferred substrate platform for photonic integration. While most silicon-based photonic components have so far been realized in the near-infrared (near-IR) telecommunication bands, the mid-infrared (mid-IR, 2-20-μm wavelength) band presents a significant growth opportunity for integrated photonics. In this review, we offer our perspective on the burgeoning field of mid-IR integrated photonics on silicon. A comprehensive survey on the state-of-the-art of key photonic devices such as waveguides, light sources, modulators, and detectors is presented. Furthermore, on-chip spectroscopic chemical sensing is quantitatively analyzed as an example of mid-IR photonic system integration based on these basic building blocks, and the constituent component choices are discussed and contrasted in the context of system performance and integration technologies.

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“…A few of these ChG materials such as As 2 S 3 , As 2 Se 3 , Ge 11.5 As 24 S 64.5 and Ge 11.5 As 24 Se 64.5 glasses are highly suitable for making active and passive devices in the MIR region. Amongst them Ge 11.5 As 24 Se 64.5 glass has excellent film-forming properties with high thermal and optical stability under intense illumination [10]. Recently interest has grown in designing and optimizing planar waveguides made from Ge 11.5 As 24 Se 64.…”

Section: Introductionmentioning

confidence: 99%

Mid-infrared supercontinuum generation using dispersion-engineered Ge_115As_24Se_645 chalcogenide channel waveguide

Karim¹,

Rahman²,

Agrawal³

2015

Opt. Express

104

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This is the accepted version of the paper.This version of the publication may differ from the final published version. Permanent repository link Abstract:We numerically investigate mid-infrared supercontinuum (SC) generation in dispersion-engineered, air-clad, Ge 11.5 As 24 Se 64.5 chalcogenide-glass channel waveguides employing two different materials, Ge 11.5 As 24 S 64.5 or MgF 2 glass for their lower cladding. We study the effect of waveguide parameters on the bandwidth of the SC at the output of 1-cm-long waveguide. Our results show that output can vary over a wide range depending on its design and the pump wavelength employed. At the pump wavelength of 2 µm the SC never extended beyond 4.5 µm for any of our designs. However, supercontinuum could be extended to beyond 5 µm for a pump wavelength of 3.1 µm. A broadband SC spanning from 2 µm to 6 µm and extending over 1.5 octave could be generated with a moderate peak power of 500 W at a pump wavelength of 3.1 µm using an air-clad, all-chalcogenide, channel waveguide. We show that SC can be extended even further when MgF 2 glass is used for the lower cladding of chalcogenide waveguide. Our numerical simulations produced SC spectra covering the wavelength range 1.8-7.7 µm (> two octaves) by using this geometry. Both ranges exceed the broadest SC bandwidths reported so far. Moreover, we realize it using 3.1 µm pump source and relatively low peak power pulses. By employing the same pump source, we show that SC spectra can cover a wavelength range of 1.8-11 µm (> 2.5 octaves) in a channel waveguide employing MgF 2 glass for its lower cladding with a moderate peak power of 3000 W.

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Low-loss chalcogenide waveguides for chemical sensing in the mid-infrared

Cited by 159 publications

References 30 publications

Small core Chalcogenide photonic crystal fiber for mid-infrared wavelength conversion: experiment and design

Small core Chalcogenide photonic crystal fiber for mid-infrared wavelength conversion: experiment and design

Mid-infrared integrated photonics on silicon: a perspective

Mid-infrared supercontinuum generation using dispersion-engineered Ge_115As_24Se_645 chalcogenide channel waveguide

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