Your search keyword '"optical amplification"' showing total 4 results

1. Optical Amplification at 1.5 µm in Er III Coordination Polymer-Doped Waveguides Based on Intramolecular Energy Transfer.

Author

Shi X, Man Y, He Y, Xu H, Zhang B, Yu D, Lin Z, Lv Z, Zhao Z, Zhang L, Chen Y, and Zhang D

Abstract

9,9-bis (diphenylphosphorylphenyl) fluorene (FDPO) and dibenzotetrathienoacene (DBTTA), are synthesized as the neutral and anionic ligands, respectively, to prepare the Er III coordination polymer [Er(DBTTA) 3 (FDPO)] n . Based on the intramolecular energy transfer, optical gains at 1.5 µm are demonstrated in [Er(DBTTA) 3 (FDPO)] n -doped polymer waveguides under excitations of low-power light-emitting diodes (LEDs) instead of laser pumping. A ligand-sensitization scheme between organic ligands and Er 3+ ions under an excitation of an ultraviolet (UV) LED is established. Relative gains of 10.5 and 8.5 dB cm -1 are achieved at 1.53 and 1.55 µm, respectively, on a 1-cm-long SU-8 channel waveguide with a cross-section of 2 × 3 µm 2 and a 1.5-µm-thick [Er(DBTTA) 3 (FDPO)] n -doped polymethylmethacrylate (PMMA) as upper cladding. The Er III coordination polymer [Er(DBTTA) 3 (FDPO)] n can be conveniently integrated with various low-loss inorganic waveguides to compensate for optical losses in the C-band window. Moreover, by relying on the intramolecular energy transfer and UV LED top-pumping technology, it is easy to achieve coupling packaging of erbium-doped waveguide amplifiers (EDWAs) with pump sources in planar photonic integrated chips, effectively reducing the commercial costs., (© 2024 The Author(s). Advanced Science published by Wiley‐VCH GmbH.)

Published

2024

2. Three-Dimensional Modeling of the Optical Switch Based on Guided-Mode Resonances in Photonic Crystals.

Author

Rehman AU, Khan Y, Irfan M, Choudri S, Khonina SN, Kazanskiy NL, and Butt MA

Abstract

Optical switching is an essential part of photonic integrated circuits and the focus of research at the moment. In this research, an optical switch design working on the phenomenon of guided-mode resonances in a 3D photonic-crystal-based structure is reported. The optical-switching mechanism is studied in a dielectric slab-waveguide-based structure operating in the near-infrared range in a telecom window of 1.55 µm. The mechanism is investigated via the interference of two signals, i.e., the data signal and the control signal. The data signal is coupled into the optical structure and filtered utilizing guided-mode resonance, whereas the control signal is index-guided in the optical structure. The amplification or de-amplification of the data signal is controlled by tuning the spectral properties of the optical sources and structural parameters of the device. The parameters are optimized first using a single-cell model with periodic boundary conditions and later in a finite 3D-FDTD model of the device. The numerical design is computed in an open-source Finite Difference Time Domain simulation platform. Optical amplification in the range of 13.75% is achieved in the data signal with a decrease in the linewidth up to 0.0079 µm, achieving a quality factor of 114.58. The proposed device presents great potential in the field of photonic integrated circuits, biomedical technology, and programmable photonics.

Published

2023

3. Soliton Microcomb on Chip Integrated Si 3 N 4 Microresonators with Power Amplification in Erbium-Doped Optical Mono-Core Fiber.

Author

Chen X, Sun S, Ji W, Ding X, Gao Y, Liu T, Wen J, Guo H, and Wang T

Abstract

Soliton microcombs, offering large mode spacing and broad bandwidth, have enabled a variety of advanced applications, particularly for telecommunications, photonic data center, and optical computation. Yet, the absolute power of microcombs remains insufficient, such that optical power amplification is always required. Here, we demonstrate a combined technique to access power-sufficient optical microcombs, with a photonic-integrated soliton microcomb and home-developed erbium-doped gain fiber. The soliton microcomb is generated in an integrated Si3N4 microresonator chip, which serves as a full-wave probing signal for power amplification. After the amplification, more than 40 comb modes, with 115-GHz spacing, reach the onset power level of >−10 dBm, which is readily available for parallel telecommunications , among other applications.

Published

2022

4. Recent Advances in Conjugated Polymer Materials for Disease Diagnosis.

Author

Lv F, Qiu T, Liu L, Ying J, and Wang S

Subjects

Animals, Humans, Diagnostic Imaging, Disease, Polymers chemistry

Abstract

The extraordinary optical amplification and light-harvesting properties of conjugated polymers impart sensing systems with higher sensitivity, which meets the primary demands of early cancer diagnosis. Recent advances in the detection of DNA methylation and mutation with polyfluorene derivatives based fluorescence resonance energy transfer (FRET) as a means to modulate fluorescent responses attest to the great promise of conjugated polymers as powerful tools for the clinical diagnosis of diseases. To facilitate the ever-changing needs of diagnosis, the development of detection approaches and FRET signal analysis are highlighted in this review. Due to their exceptional brightness, excellent photostability, and low or absent toxicity, conjugated polymers are verified as superior materials for in-vivo imaging, and provide feasibility for future clinical molecular-imaging applications. The integration of conjugated polymers with clinical research has shown profound effects on diagnosis for the early detection of disease-related biomarkers, as well as in-vivo imaging, which leads to a multidisciplinary scientific field with perspectives in both basic research and application issues., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016