Mid-infrared supercontinuum generation in a varying dispersion waveguide for multi-species gas spectroscopy

Torre, Alberto Della; Armand, Rémi; Sinobad, Milan; Fiaboe, Kokou Firmin; Luther‐Davies, Barry; Madden, Steve; Mitchell, Arnan; Nguyen, Thach G.; Moss, David J.; Hartmann, Jean‐Michel; Reboud, V.; Fédéli, Jean-Marc; Grillet, Christian

doi:10.1109/jstqe.2022.3185169

Cited by 12 publications

(5 citation statements)

References 43 publications

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“…In this work, we chose the Si 3 N 4 platform since it has shown a good compatibility for hybrid integration of 2D GO films. [52,56,68] Compared to silicon that has a relatively small bandgap of ≈1.1 eV, [69,70] Si 3 N 4 has a large bandgap of ≈5.0 eV [48,71] that yields low TPA in the near infrared region. We fabricated Si 3 N 4 waveguides in a process based on chemical-physical multistep annealing, encapsulation, and a tailored fluorocarbon dry etching, as reported previously.…”

Section: Device Design and Fabricationmentioning

confidence: 99%

Enhanced Supercontinuum Generation in Integrated Waveguides Incorporated with Graphene Oxide Films

Zhang

Yang

et al. 2023

Adv Materials Technologies

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Enhanced supercontinuum generation (SCG) is experimentally demonstrated in integrated silicon nitride (Si3N4) waveguides incorporating highly nonlinear graphene oxide (GO) in the form of 2D films. On‐chip integration of the 2D GO films with precise control of their thickness is realized by using a transfer‐free and layer‐by‐layer coating method. The control of the film length and coating position is achieved via window opening in the upper silica cladding of the photonic integrated chips. Detailed SCG measurements are performed using the fabricated devices with different waveguide geometries and GO film thicknesses, and the results are compared with devices without GO. Significantly improved spectral broadening of ultrashort optical pulses with ultrahigh peak powers exceeding 1000 W is observed for the hybrid devices, achieving up to 2.4 times improvement in the spectral bandwidth relative to devices without GO. Theoretical analyses for the influence of GO film thickness, coating length, coating position, and waveguide geometry are also provided by fitting the experimental results with theory, showing that there is still significant room for further improvement. This work opens up a new avenue toward improving the SCG performance of photonic integrated devices by incorporating functional 2D materials.

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Section: Device Design and Fabricationmentioning

confidence: 99%

Enhanced Supercontinuum Generation in Integrated Waveguides Incorporated with Graphene Oxide Films

Zhang

Yang

et al. 2023

Adv Materials Technologies

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“…We designed a multi stage waveguide (anomalous dispersion section followed by a varying width section resulting in a varying dispersion from anomalous to normal) to simultaneously increase the bandwidth of the generated SC and improve its spectral flatness. We exploited such SC for a proof-of-principle demonstration of multi-species gas (water vapour and carbon dioxide) spectroscopy in our laboratory environment [5]. We are currently exploring heterogeneous integration schemes with phase change material to dynamically control the waveguide dispersion state and therefore the supercontinuum spectral and temporal properties (Figure 3).…”

Section: Ge-based Light Sourcesmentioning

confidence: 99%

Photonic ge-based platforms for mid-infrared applications

Reboud,

Hartmann,

Serna

et al. 2024

Photoniques

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Silicon photonics, initially developed for data communications in the near infrared (NIR), has been extended over the last ten years to the mid-infrared (MIR) region. Efforts have been made to fully integrate MIR functions at chip level on Ge and Si planar substrates, to achieve greater reliability and higher performance at lower cost. The fields of application are vast, ranging from IR imaging of biological tissues to environmental monitoring, control of industrial processes, security and many more.

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“…In both dispersion regimes, the spectral bandwidth saturated after a propagation distance of ∼20 mm, as a consequence of the waveguide dispersion, and of the linear and nonlinear losses. Recently, the same group proposed a two-stage design ( Figure 12(e) ), in order to combine the broad bandwidth provided by the anomalous dispersion with the flatter spectral shape typical of SCG in the ANDi regime [ 88 ]. The authors demonstrated a 40% increase in the SCG efficiency with such a dispersion-managed waveguide, and harnessed the improved spectral properties of the SC for the simultaneous detection of water vapor and CO 2 ( Figure 12(f) ).…”

Section: Supercontinuum Generation In Si-photonicsmentioning

confidence: 99%

“…By immersing the waveguide in chloroform solutions, the overtone absorption peak centered at 1695 nm was used to quantify the performance of the device, providing a proof-of-principle of such combined platform, albeit with limited performance at this point owing to the high loss of the waveguide and the weak evanescent field. The potential of MIR SCG in SiGe waveguides for direct absorption spectroscopy was also demonstrated with a proof-of-principle experiment [ 88 ]. Using 2.5–5 μm light directly emitted by SCG in dispersion engineered SiGe waveguides, the absorption fingerprint of both water and CO 2 could be detected and identified in parallel.…”

Section: Applications Of Chip-based Supercontinuummentioning

confidence: 99%

Supercontinuum in integrated photonics: generation, applications, challenges, and perspectives

et al. 2023

Self Cite

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Frequency conversion in nonlinear materials is an extremely useful solution to the generation of new optical frequencies. Often, it is the only viable solution to realize light sources highly relevant for applications in science and industry. In particular, supercontinuum generation in waveguides, defined as the extreme spectral broadening of an input pulsed laser light, is a powerful technique to bridge distant spectral regions based on single-pass geometry, without requiring additional seed lasers or temporal synchronization. Owing to the influence of dispersion on the nonlinear broadening physics, supercontinuum generation had its breakthrough with the advent of photonic crystal fibers, which permitted an advanced control of light confinement, thereby greatly improving our understanding of the underlying phenomena responsible for supercontinuum generation. More recently, maturing in fabrication of photonic integrated waveguides has resulted in access to supercontinuum generation platforms benefiting from precise lithographic control of dispersion, high yield, compact footprint, and improved power consumption. This Review aims to present a comprehensive overview of supercontinuum generation in chip-based platforms, from underlying physics mechanisms up to the most recent and significant demonstrations. The diversity of integrated material platforms, as well as specific features of waveguides, is opening new opportunities, as will be discussed here.

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Mid-infrared supercontinuum generation in a varying dispersion waveguide for multi-species gas spectroscopy

Cited by 12 publications

References 43 publications

Enhanced Supercontinuum Generation in Integrated Waveguides Incorporated with Graphene Oxide Films

Enhanced Supercontinuum Generation in Integrated Waveguides Incorporated with Graphene Oxide Films

Photonic ge-based platforms for mid-infrared applications

Supercontinuum in integrated photonics: generation, applications, challenges, and perspectives

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