Issue 15, 2017

Reversible intercalation of iodine monolayers between on-surface synthesised covalent polyphenylene networks and Au(111)

Abstract

We report on post-synthetic decoupling of covalent polyphenylene networks from Au(111) by intercalation of a chemisorbed iodine monolayer. The covalent networks were synthesised by on-surface Ullmann polymerization of 1,3-bis(p-bromophenyl)-5-(p-iodophenyl)benzene precursors on Au(111) under ultra-high vacuum conditions. The present study relates to previous work, where successful detachment was demonstrated on Ag(111) by a combination of microscopic and spectroscopic techniques. On the more reactive Ag(111) surfaces, intercalation was readily accomplished by exposing the samples to iodine vapour at room temperature. On more noble Au(111), however, STM, XPS and NEXAFS consistently indicate that the same protocol merely results in co-adsorption of iodine on uncovered surface areas, whereas the covalent networks remain adsorbed on the metal. Yet, performing the iodine exposure at elevated surface temperatures similarly results in detachment of the organic networks via intercalation of an iodine monolayer also on Au(111) as evidenced by characteristic changes in STM. In addition, owing to the high thermal stability of the covalent networks and the comparatively low iodine desorption temperature, the reversibility of the process is demonstrated: sample annealing at 400 °C results in complete desorption of the iodine monolayer, whereby the covalent networks re-adsorb directly on Au(111).

Graphical abstract: Reversible intercalation of iodine monolayers between on-surface synthesised covalent polyphenylene networks and Au(111)

Supplementary files

Article information

Article type
Paper
Submitted
30 Jan 2017
Accepted
19 Mar 2017
First published
28 Mar 2017

Nanoscale, 2017,9, 4995-5001

Reversible intercalation of iodine monolayers between on-surface synthesised covalent polyphenylene networks and Au(111)

A. Rastgoo-Lahrood, M. Lischka, J. Eichhorn, D. Samanta, M. Schmittel, W. M. Heckl and M. Lackinger, Nanoscale, 2017, 9, 4995 DOI: 10.1039/C7NR00705A

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