Your search keyword '"Jonathan Link"' showing total 3 results

1. Structure Determination in a new Type of Amorphous Molecular Solids with Different Nonlinear Optical Properties: A Comparative Structural Analysis

Author

Vasco, Jonathan Link, Stellhorn, Jens Ruediger, Klee, Benjamin Danilo, Paulus, Benedict, Belz, Juergen, Haust, Johannes, Hosokawa, Shinya, Hayakawa, Shinjiro, Volz, Kerstin, León, Iran Rojas, Christmann, Jan, Dehnen, Stefanie, and Pilgrim, Wolf-Christian

Subjects

Condensed Matter - Materials Science, Condensed Matter - Disordered Systems and Neural Networks

Abstract

The microscopic structure of two amorphous materials with extreme nonlinear optical properties has been studied. One of these materials exhibits second harmonic generation, while another material of similar molecular structure emits brilliant white light if being irradiated with a simple IR laser diode. Structural differences were investigated using X-ray scattering and EXAFS combined with molecular RMC. Transmission electron microscopy and scanning precession electron diffraction were used to understand specific structural differences on all length scales, from mesoscopic down to mutual molecular arrangements. Characteristic differences were found at all scales. Close core-core spacing between {SnS} clusters as well as characteristic cluster distortions appear to be characteristic features of the white light emitting material. In the other material, cores are undistorted and core distances are larger. There, the formation of nanocrystalline structures in the amorphous matrix could also be identified as reason for the WLG suppression., Comment: 12 pages, 8 figures

Published

2023

2. White-light generating molecular materials: correlation between the amorphous/crystalline structure and nonlinear optical properties

Author

Haust, Johannes, Belz, Jürgen, Müller, Marius, Klee, Benjamin Danilo, Vasco, Jonathan Link, Hüppe, Franziska, Léon, Irán Rojas, Christmann, Jan, Beyer, Andreas, Dehnen, Stefanie, Rosemann, Nils W., Pilgrim, Wolf-Christian, Chatterjee, Sangam, and Volz, Kerstin

Subjects

Condensed Matter - Materials Science

Abstract

Amorphous materials are integral part of todays technology, they commonly are performant and versatile in integration. Consequently, future applications increasingly aim to harvest the potential of the amorphous state. Establishing its structure-property relationship, however, is inherently challenging using diffraction-based techniques yet is extremely desirable for developing advanced functionalities. In this article, we introduce a set of transmission electron microscopy-based techniques to locally quantify the structure of a material. This unique approach allows to clearly identify the spatial distribution of amorphous and crystalline regions and to quantify atomic arrangements of amorphous regions of a representative model system. We study an ensemble of well-defined, functionalized adamantane-type cluster molecules exhibiting exceptionally promising nonlinear optical properties of unclear origin. The nanoscopic structure for three model compounds ([(PhSn)4S6], [(NpSn)4S6], [(CpSn)4S6]) correlates with their characteristic optical responses. These results highlight the advantageous properties of amorphous molecular materials when understanding the microscopic origin., Comment: 19 pages, 13 figures

Published

2022

3. Origin of Crystallization Suppression in a New Amorphous Molecular White-Light-Generating Material

Author

Klee, Benjamin Danilo, Paulus, Benedict, Vasco, Jonathan Link, Dehnen, Stefanie, Pilgrim, Wolf-Christian, Hosokawa, Shinya, Stellhorn, Jens Rüdiger, and Hayakawa, Shinjiro

Subjects

Condensed Matter - Materials Science, 82D30

Abstract

The microscopic structure of a new infrared-driven amorphous white-light-generating material was explored by X-ray diffraction, EXAFS and Reverse Monte Carlo simulation. In this material, structural disorder appears to be prerequisite for this nonlinear optical effect. The results are consistent with quantum chemical predictions, but it is also found that the molecular cores are distorted, which is identified as a crystallization inhibitor. Sulfur atoms thereby form a uniform vibrational network, which may be responsible for the high capability of the material to absorb infrared radiation., Comment: 5 pages, 5 figures, 1 table

Published

2022