Lv, Qiang published the artcileLattice-mismatch-free growth of organic heterostructure nanowires from cocrystals to alloys, Recommanded Product: Coronene, the publication is Nature Communications (2022), 13(1), 3099, database is CAplus and MEDLINE.
Organic heterostructure nanowires, such as multiblock, core/shell, branch-like and related compounds, have attracted chemists¡ä extensive attention because of their novel physicochem. properties. However, owing to the difficulty in solving the lattice mismatch of distinct mols., the construction of organic heterostructures at large scale remains challenging, which restricts its wide use in future applications. In this work, we define a concept of lattice-mismatch-free for hierarchical self-assembly of organic semiconductor mols., allowing for the large-scale synthesis of organic heterostructure nanowires composed of the organic alloys and cocrystals. Thus, various types of organic triblock nanowires are prepared in large scale, and the length ratio of different segments of the triblock nanowires can be precisely regulated by changing the stoichiometric ratio of different components. These results pave the way towards fine synthesis of heterostructures in a large scale and facilitate their applications in organic optoelectronics at micro/nanoscale.
Nature Communications published new progress about 191-07-1. 191-07-1 belongs to catalysis-chemistry, auxiliary class Electronic Materials, name is Coronene, and the molecular formula is C24H12, Recommanded Product: Coronene.
Referemce:
https://courses.lumenlearning.com/boundless-chemistry/chapter/catalysis/,
Catalysis – Wikipedia