Your search keyword '"König, Tobias A. F."' showing total 6 results

1. Ultrasonic Control of Polymer-Capped Plasmonic Molecules

Author

Cai, Yingying, Sarkar, Swagato, Peng, Yuwen, König, Tobias A. F., and Vana, Philipp

Abstract

Plasmonic molecules (PMs) composed of polymer-capped nanoparticles represent an emerging material class with precise optical functionalities. However, achieving controlled structural changes in metallic nanoparticle aggregation at the nanoscale, similar to the modification of atomic structures, remains challenging. This study demonstrates the 2D/3D isomerization of such plasmonic molecules induced by a controlled ultrasound process. We used two types of gold nanoparticles, each functionalized with hydrogen bonding (HB) donor or acceptor polymers, to self-assemble into different ABN-type complexes via interparticle polymer bundles acting as molecular bonds. Post-ultrasonication treatment significantly shortens these bonds from approximately 14 to 2 nm by enhancing HB cross-linking within the bundles. This drastic change in the bond length increases the stiffness of the resulting clusters, facilitating the transition from 2D to 3D configurations in 100% yield during drop-casting onto substrates. Our results advance the precise control of PMs’ nanoarchitectures and provide insights for their broad applications in sensing, optoelectronics, and metamaterials.

Published

2024

2. Directional Amplified Photoluminescence through Large-Area Perovskite-Based Metasurfaces

Author

Aftenieva, Olha, primary, Brunner, Julius, additional, Adnan, Mohammad, additional, Sarkar, Swagato, additional, Fery, Andreas, additional, Vaynzof, Yana, additional, and König, Tobias A. F., additional

Published

2023

3. Gold-Based Cubic Nanoboxes with Well-Defined Openings at the Corners and Ultrathin Walls Less Than Two Nanometers Thick

Author

Sun, Xiaojun, primary, Kim, Junki, additional, Gilroy, Kyle D., additional, Liu, Jingyue, additional, König, Tobias A. F., additional, and Qin, Dong, additional

Published

2016

4. Plasmonic Library Based on Substrate-Supported Gradiential Plasmonic Arrays

Author

Müller, Mareen B., primary, Kuttner, Christian, additional, König, Tobias A. F., additional, Tsukruk, Vladimir V., additional, Förster, Stephan, additional, Karg, Matthias, additional, and Fery, Andreas, additional

Published

2014

5. Electrically Tunable Plasmonic Behavior of Nanocube–Polymer Nanomaterials Induced by a Redox-Active Electrochromic Polymer

Author

König, Tobias A. F., primary, Ledin, Petr A., additional, Kerszulis, Justin, additional, Mahmoud, Mahmoud. A., additional, El-Sayed, Mostafa A., additional, Reynolds, John R., additional, and Tsukruk, Vladimir V., additional

Published

2014

6. Macroscopic Strain-Induced Transition from Quasi-infinite Gold Nanoparticle Chains to Defined Plasmonic Oligomers.

Author

Steiner AM, Mayer M, Seuss M, Nikolov S, Harris KD, Alexeev A, Kuttner C, König TAF, and Fery A

Abstract

We investigate the formation of chains of few plasmonic nanoparticles-so-called plasmonic oligomers-by strain-induced fragmentation of linear particle assemblies. Detailed investigations of the fragmentation process are conducted by in situ atomic force microscopy and UV-vis-NIR spectroscopy. Based on these experimental results and mechanical simulations computed by the lattice spring model, we propose a formation mechanism that explains the observed decrease of chain polydispersity upon increasing strain and provides experimental guidelines for tailoring chain length distribution. By evaluation of the strain-dependent optical properties, we find a reversible, nonlinear shift of the dominant plasmonic resonance. We could quantitatively explain this feature based on simulations using generalized multiparticle Mie theory (GMMT). Both optical and morphological characterization show that the unstrained sample is dominated by chains with a length above the so-called infinite chain limit-above which optical properties show no dependency on chain length-while during deformation, the average chain length decrease below this limit and chain length distribution becomes more narrow. Since the formation mechanism results in a well-defined, parallel orientation of the oligomers on macroscopic areas, the effect of finite chain length can be studied even using conventional UV-vis-NIR spectroscopy. The scalable fabrication of oriented, linear plasmonic oligomers opens up additional opportunities for strain-dependent optical devices and mechanoplasmonic sensing.

Published

2017