Directional self-assembly of organic vertically superposed nanowires
Yingxin Ma, Xuedong Wang
Abstract
Organic crystal-based superimposed heterostructures with inherent multichannel characteristics demonstrate superior potential for manipulating excitons/photons at the micro/nanoscale for integrated optoelectronics. However, the precise construction of organic superimposed heterostructures with fixed superimposed sites remains challenging because of the random molecular nucleation process. Here, organic vertically superimposed heterostructures (OSHs) with fixed superimposed positions are constructed via semi-wrapped core/shell heterostructures with partially exposed cores, which provide preferential nucleation sites for further molecular epitaxial growth processes. Furthermore, the relative length ratio from 21.7% to 95.3% between interlayers is accurately adjusted by regulating the exposed area of the semi-wrapped core/shell heterostructures. Significantly, these OSHs with anisotropic optical characteristics demonstrate well regulation of excitation position-dependent waveguide behaviors and can function as photonic barcodes for information encryption. This strategy provides a facile approach for controlling the nucleation sites for the controllable preparation of organic heterostructures and advanced applications for integrated optoelectronics. Organic crystal-based superimposed heterostructures demonstrate potential for manipulating excitons/photons at the micro- or nanoscale for integrated optoelectronics but the precise construction of organic these heterostructures with fixed superimposed sites remains challenging. Here, the authors construct vertically superimposed organic heterostructures with fixed superimposed positions which possess preferential nucleation sites for molecular epitaxial growth processes.