MATERIALS SCIENCE AND CHEMISTRY

Understanding the response of silicon and diamond to shear deformation is crucial to improve the performance of nanodevices and low friction coatings. Atomic length scale simulations show that the two materials differ significantly in their amorphization-mediated wear behavior: Externally applied pressure favors the wear of silicon, while it reduces the wear of diamond. For silicon, a shear-induced recrystallization process opposes amorphization. By choosing suitable orientations of two silicon crystals in the sliding contact, the combination of both phase transformations can be exploited to grow silicon crystals with nanoscale precision.

Synthetic or biological amphiphiles self-assemble into spatially modulated structures on the nanoscale with applications ranging from etch masks in semiconductor fabrication, over porous membranes for separation or energy applications, to the compartmentalization of living cells. Often, such systems do not reach thermal equilibrium but, instead, the structures are dictated by processing and kinetic pathways. These molecular simulations provide insight into the correlation between molecular structure and collective dynamics that alter the self-assembly. Two results are being highlighted: (i) the kinetically accessible states in the course of directed self-assembly and (ii) the kinetic pathway of the fusion of two apposing lipid membranes.

As most notorious greenhouse gas, CO₂ emissions prevail as high as about 364 million tons carbon with the concentration reaching over 400 ppm in the atmosphere. A drastic reduction of CO₂ is urgently necessary for sustainable growth and to fight climate change. The electrochemical reduction of CO₂ (CO2RR) is a promising approach to utilize renewable electricity to convert CO₂ into chemical energy carriers at ambient conditions and in small-scale decentralized operation. Researchers from Technical University of Munich have employed an active-site screening approach and proposed carbon-rich molybdenum carbides as a promising CO2RR catalyst to produce methanol.

It is well-known that the catalytic properties of metals may extend beyond their melting point. Recently, this has been exploited to grow high-quality 2D materials such as graphene. To improve our understanding of the growth mechanism on liquid metal catalysts, researchers at the Technical University of Munich have employed a multi-scale modelling approach. Here, detailed simulations of various building blocks for the final graphene sheet such as simple hydrocarbons and smaller graphene flakes on solid and liquid Cu surfaces have been carried out. The insights from these simulations were then used to propose a mesoscopic model for the dynamics of graphene growth on molten Cu based on capillary and electrostatic interactions.

A supramolecular polymer (SMP) has functional groups which interact with each other to form a physical bond. In contrast to chemical bonds, the bond formation in an SMP is reversible and the resulting aggregate morphology in a SMP melt thermally fluctuates. For functional groups allowing only a pairwise association, a ring aggregate is highly important as a ring topologically reduces the mobility of surrounding linear polymers by threading. Using molecular dynamics simulations of SMPs, the effect of ring aggregates on the system relaxation time governing rheological response was investigated. It was shown that the presence of ring aggregates slows down rheological response as measured by a reduction of the so-called entanglement length.

Roughness of many natural and engineered surfaces follows a scaling law called self-affine scaling. In project chka18, the origins of self-affine have been investigated using Molecular Dynamics simulations. It was shown that the self-affine roughness emerges naturally during deformation of initially flat surfaces in different materials.

This group from the Helmholtz-Institute Erlangen-Nürnberg performed simulations, both on a coarse-grained and a molecular level of detail, elucidating how so-called antagonistic salts, consisting of a large anion and a small cation, trigger the spontaneous formation of highly regular, nanometer sized structures in water/oil mixtures. Due to their size difference the small cations accumulate in the water phase while the large anions go to the oil phase. The resulting electrostatic interactions between the phases can lead to long-range ordering.