Jing Becker scite author profile

Organic thin-film lasers (OLAS) are promising optical sources when it comes to flexibility and small-scale manufacturing. These properties are required especially for integrating organic thin-film lasers into single-mode waveguides. Optical sensors based on single-mode ridge waveguide systems, especially for Lab-on-a-chip (LoC) applications, usually need external laser sources, free-space optics, and coupling structures, which suffer from coupling losses and mechanical stabilization problems. In this paper, we report on the first successful integration of organic thin-film lasers directly into polymeric single-mode ridge waveguides forming a monolithic laser device for LoC applications. The integrated waveguide laser is achieved by three production steps: nanoimprint of Bragg gratings onto the waveguide cladding material EpoClad, UV-Lithography of the waveguide core material EpoCore, and thermal evaporation of the OLAS material Alq3:DCM2 on top of the single-mode waveguides and the Bragg grating area. Here, the laser light is analyzed out of the waveguide facet with optical spectroscopy presenting single-mode characteristics even with high pump energy densities. This kind of integrated waveguide laser is very suitable for photonic LoC applications based on intensity and interferometric sensors where single-mode operation is required.

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Numerical simulation of hollow waveguide arrays as polarization converting elements and experimental verification

Helfert

Seiler

Jahns

et al. 2017

Opt Quant Electron

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Blue-light-emitting polymer lasers with non-periodic circular Bragg resonators

Wellinger

Pflumm

Becker

et al. 2008

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Distributed feedback ridge waveguide lasers fabricated by CNP process

Becker

Cehovski

Caspary

et al. 2017

Microelectronic Engineering

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Learning from Self‐Sealing Deformations of Plant Leaves: The Biomimetic Multilayer Actuator

Becker

Speck

Göppert

et al. 2022

Advanced Intelligent Systems

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During evolution, plants have developed various functional principles for sealing and healing wounds. Prime examples are succulent leaves of Delosperma cooperi that seal external injuries within 60 min. Cross sections of intact leaves show a centripetal multilayer structure consisting of five tissues alternately under tensile and compressive prestress. Injuries destroy this mechanical equilibrium causing a deformation of the entire leaf until a new equilibrium is reached, and the wound edges meet, thereby sealing the fissure. Following this functional principle of D. cooperi leaves, a planar three‐layer materials system consisting of a sheet of shape memory polymer (SMP) with programmed temporary geometry sandwiched between two polydimethylsiloxane (PDMS) sheets is developed. After the individual sheets are bonded at room temperature, the application of heat treatment without mechanical constraints results in a prestressed multilayer system. The damage‐triggered bending behavior of the three‐layer system is described by means of an analytical model and feasibility tests establishing the self‐sealing functionality of the system. Thus, a biomimetic materials system with a self‐sealing function within the framework of a biomimetic biology push process is developed. However, the discussion herein has gone beyond the biological model, because the self‐sealing three‐layer materials system can additionally serve as an actuator.

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Jing Becker

Single-Mode Polymer Ridge Waveguide Integration of Organic Thin-Film Laser

Numerical simulation of hollow waveguide arrays as polarization converting elements and experimental verification

Blue-light-emitting polymer lasers with non-periodic circular Bragg resonators

Distributed feedback ridge waveguide lasers fabricated by CNP process

Learning from Self‐Sealing Deformations of Plant Leaves: The Biomimetic Multilayer Actuator

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