All-Optical Broadband QDs Semiconductor Optical Amplifier (QDs-SOA): Inhomogeneous Broadening

Eyvazi, Mahdiyeh; Yadipour, Reza; Rostami, Ali

doi:10.1109/access.2024.3383019

IEEE Access

2024

DOI: 10.1109/access.2024.3383019

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All-Optical Broadband QDs Semiconductor Optical Amplifier (QDs-SOA): Inhomogeneous Broadening

Mahdiyeh Eyvazi,

Reza Yadipour,

Ali Rostami

Abstract: The escalating demand for increased traffic capacity and bandwidth in communication networks has spurred the exploration of innovative solutions. This article delves into the promising features of Quantum Dot Semiconductor Optical Amplifiers (QD-SOAs), specifically focusing on InAs0.4Sb0.6 quantum dots within an InP quantum well structure. The study utilizes optical pumping to achieve population inversion in the active region, thereby enhancing efficiency and overcoming challenges associated with electrical pu… Show more

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Surface‐Functionalization of Oleate‐Capped Nano‐Emitters for Stable Dispersion in 3D‐Printable Polymers

Pathak,

Kulkarni,

Chan

et al. 2024

Adv Funct Materials

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Two‐photon polymerization 3D‐printing is a well‐known technique for fabricating passive micro/nanoscale structures, such as microlenses and inversely designed polarization splitters. The integration of light emitting nanoparticle (NP) dopants, such as quantum dots (QDs) and rare‐earth doped nanoparticles (RENPs), into a polymer resist would enable 3D printing of active polymer micro‐photonic devices, including sensors, lasers, and solid‐state displays. Many NPs contain oleic acid ligands to prevent degradation, but oleate‐capped NPs (oc‐NPs) tend to agglomerate in nonpolar media despite the hydrophobicity of the ligand. This results in an uneven nanoparticle distribution and increased optical extinction. In this work, a general approach is proposed for dispersing oc‐NPs in commercial 3D printable polymers. Controlled growth of small carbon chains around the oc‐NPs is achieved by functionalizing them with methyl‐methacrylate monomers. The proposed approach is validated on RENPs (≈65 nm) and CdSe/ZnS quantum dots (≈12 nm) using commercial polymer resists (IP‐Dip and IP‐Visio). Dispersions of functionalized NPs (f‐NPs) have improved the NP density by an order of magnitude and are shown to be stable for several weeks with minimal impact on printing quality. The approach is generalizable to other oc‐NPs, enabling synthesis of functional resins for high‐quality polymer‐based optical and electronic devices.

show abstract

Surface‐Functionalization of Oleate‐Capped Nano‐Emitters for Stable Dispersion in 3D‐Printable Polymers

Pathak,

Kulkarni,

Chan

et al. 2024

Adv Funct Materials

View full text Add to dashboard Cite

show abstract

Accelerating gain and phase recovery in Quantum-Dot reflective Semiconductor optical Amplifier: Unraveling the influence of inhomogeneous broadening and pumping power for enhanced performance

Safari,

Matloub,

Connelly

2025

Optics & Laser Technology

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All-Optical Broadband QDs Semiconductor Optical Amplifier (QDs-SOA): Inhomogeneous Broadening

Cited by 2 publications

References 34 publications

Surface‐Functionalization of Oleate‐Capped Nano‐Emitters for Stable Dispersion in 3D‐Printable Polymers

Surface‐Functionalization of Oleate‐Capped Nano‐Emitters for Stable Dispersion in 3D‐Printable Polymers

Accelerating gain and phase recovery in Quantum-Dot reflective Semiconductor optical Amplifier: Unraveling the influence of inhomogeneous broadening and pumping power for enhanced performance

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