Abstract
Crystal structure prediction has been one of the fundamental and challenging problems in materials science. It is computationally exhaustive to identify molecular conformations and arrangements in organic molecular crystals due to complexity in intra- and inter-molecular interactions. From a geometrical viewpoint, specific types of organic crystal structures can be characterized by ellipsoid packing. In particular, we focus on aromatic systems which are important for organic semiconductor materials. In this study, we aim to estimate the ellipsoidal molecular shapes of such crystals and predict them from single molecular descriptors. First, we identify the molecular crystals with molecular centroid arrangements that correspond to affine transformations of four basic cubic lattices, through topological analysis of the dataset of crystalline polycyclic aromatic molecules. The novelty of our method is that the topological data analysis is applied to arrangements of molecular centroids intead of those of atoms. For each of the identified crystals, we estimate the intracrystalline molecular shape based on the ellipsoid packing assumption. Then, we show that the ellipsoidal shape can be predicted from single molecular descriptors using a machine learning method. The results suggest that topological characterization of molecular arrangements is useful for structure prediction of organic semiconductor materials.
Highlights
Finding novel materials with desired properties often requires exhaustive search
Polycyclic aromatic hydrocarbons (PAHs) and their derivatives have been widely explored for organic semiconductors [41]
We selected polyaromatic crystals that consist of only one type of molecule from the Cambridge Structural Database (CSD) provided by Cambridge Crystallographic Data Centre (CCDC) [43]
Summary
Finding novel materials with desired properties often requires exhaustive search. Ab initio calculations based on density functional theory (DFT) have played a central role in analyzing physical properties of materials and testing the validity of experimental results. Ab initio calculations are powerful, versatile, and efficient, they are still computationally expensive for several important classes of problems [1]. An alternative approach is materials informatics which exploits data science and informatics for reducing computational cost in material research [2, 3]. Machine learning techniques have been increasingly leveraged to identify the hidden rules governing the structure-property-.
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