TY - JOUR
T1 - Watching Molecular Nanotubes Self-Assemble in Real Time
AU - Manrho, Marìck
AU - Krishnaswamy, Sundar Raj
AU - Kriete, Björn
AU - Patmanidis, Ilias
AU - de Vries, Alex H
AU - Marrink, Siewert J
AU - Jansen, Thomas L C
AU - Knoester, Jasper
AU - Pshenichnikov, Maxim S
PY - 2023/10/18
Y1 - 2023/10/18
N2 - Molecular self-assembly is a fundamental process in nature that can be used to develop novel functional materials for medical and engineering applications. However, their complex mechanisms make the short-lived stages of self-assembly processes extremely hard to reveal. In this article, we track the self-assembly process of a benchmark system, double-walled molecular nanotubes, whose structure is similar to that found in biological and synthetic systems. We selectively dissolved the outer wall of the double-walled system and used the inner wall as a template for the self-reassembly of the outer wall. The reassembly kinetics were followed in real time using a combination of microfluidics, spectroscopy, cryogenic transmission electron microscopy, molecular dynamics simulations, and exciton modeling. We found that the outer wall self-assembles through a transient disordered patchwork structure: first, several patches of different orientations are formed, and only on a longer time scale will the patches interact with each other and assume their final preferred global orientation. The understanding of patch formation and patch reorientation marks a crucial step toward steering self-assembly processes and subsequent material engineering.
AB - Molecular self-assembly is a fundamental process in nature that can be used to develop novel functional materials for medical and engineering applications. However, their complex mechanisms make the short-lived stages of self-assembly processes extremely hard to reveal. In this article, we track the self-assembly process of a benchmark system, double-walled molecular nanotubes, whose structure is similar to that found in biological and synthetic systems. We selectively dissolved the outer wall of the double-walled system and used the inner wall as a template for the self-reassembly of the outer wall. The reassembly kinetics were followed in real time using a combination of microfluidics, spectroscopy, cryogenic transmission electron microscopy, molecular dynamics simulations, and exciton modeling. We found that the outer wall self-assembles through a transient disordered patchwork structure: first, several patches of different orientations are formed, and only on a longer time scale will the patches interact with each other and assume their final preferred global orientation. The understanding of patch formation and patch reorientation marks a crucial step toward steering self-assembly processes and subsequent material engineering.
U2 - 10.1021/jacs.3c07103
DO - 10.1021/jacs.3c07103
M3 - Article
C2 - 37800477
SN - 0002-7863
VL - 145
SP - 22494
EP - 22503
JO - Journal of the American Chemical Society
JF - Journal of the American Chemical Society
IS - 41
ER -