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Understanding Metal Directed-Assembly Growth of Single-Crystal Organic Nanowires: Time-Resolved, In-Situ X-Ray Diffraction an...

by Kai Xiao, Mina Yoon, Adam J Rondinone, Edward A Payzant, David B Geohegan
Publication Type
Journal
Journal Name
Journal of the American Chemical Society
Publication Date
Page Numbers
14353 to 14361
Volume
134
Issue
35

The deterministic growth of oriented crystalline organic nanowires (CONs) from the vapor-solid chemical reaction (VSCR) between small-molecule reactants and metal nanoparticles has been demonstrated in several studies to date, however the growth mechanism has not yet been conclusively understood. Here, the VSCR growth of M-TCNQF4 (where M is Cu- or Ag-) nanowires is investigated both experimentally and theoretically with time-resolved, in-situ x-ray diffraction (XRD) and first-principles atomistic calculations, respectively, to understand how metals (M) direct the assembly of small molecules into CONs, and what determines the selectivity of a metal for an organic vapor reactant in the growth process. Analysis of the real-time growth kinetics data using a modified Avrami model indicates that the formation of CONs from VSCR follows a one-dimensional ion diffusion-controlled tip growth mechanism wherein metal ions diffuse from a metal film through the nanowire to its tip where they react with small molecules to continue growth. The experimental data and theoretical calculations indicate that the selectivity of different metals to induce nanowire growth depends strongly upon effective charge transfer between the organic molecules and the metal. Specifically, the experimental finding that Cu ions can exchange and replace Ag ions in Ag-TCNQF4 to form Cu-TCNQF4 nanowires is explained by the significantly stronger chemical bond between Cu and TCNQF4 molecules than for Ag, due to the strong spin-dependent electronic contribution of Cu. Understanding how to control the VSCR growth process may enable the synthesis of novel organic nanowires with axial or coaxial p/n junctions for organic nanoelectronics and solar energy harvesting.