Self-Patterning Tetrathiafulvalene Crystalline Films.
St John WhittakerMerritt McDowellJustin BendeskyZhihua AnYongfan YangHengyu ZhouYuze ZhangAlexander G ShtukenbergDilhan M KalyonBart KahrStephanie S LeePublished in: Chemistry of materials : a publication of the American Chemical Society (2023)
Tetrathiafulvalene (TTF) crystals grown from the melt are organized as spherulites in which helicoidal fibrils growing radially from the nucleation center twist in concert with one another. Alternating bright and dark concentric bands are apparent when films are viewed between crossed polarizers, indicating an alternating pattern of crystallographic faces exposed at the film surface. Band-dependent reorganization of the TTF crystals was observed during exposure to methanol vapor. Crystalline growth appears on bright bands at the expense of the dark bands. After a 24 h period of exposure to methanol vapor, the original spherulites were completely restructured, and the films comprise isolated, concentric circles of crystallites whose orientations are determined by the initial TTF crystal fibril orientation. While the surface of these outgrowths appears faceted and smooth, cross-sectional SEM images revealed a semiporous inner structure, suggesting solvent-vapor-induced recrystallization. Collectively, these results show that crystal twisting can be used to rhythmically redistribute material. Crystal twisting is a common and often controllable phenomenon independent of molecular or crystal structure and therefore offers a generalizable path to spontaneous pattern formation in a wide range of materials.
Keyphrases
- room temperature
- crystal structure
- ionic liquid
- cross sectional
- carbon dioxide
- solid state
- epithelial mesenchymal transition
- high glucose
- deep learning
- single cell
- convolutional neural network
- machine learning
- optical coherence tomography
- diffusion weighted imaging
- single molecule
- oxidative stress
- stress induced
- cell fate