Hannes Spillmann scite author profile

Metal-organic coordination networks (MOCNs) have attracted wide interest because they provide a novel route towards porous materials that may find applications in molecular recognition, catalysis, gas storage and separation. The so-called rational design principle-synthesis of materials with predictable structures and properties-has been explored using appropriate organic molecular linkers connecting to metal nodes to control pore size and functionality of open coordination networks. Here we demonstrate the fabrication of surface-supported MOCNs comprising tailored pore sizes and chemical functionality by the modular assembly of polytopic organic carboxylate linker molecules and iron atoms on a Cu(100) surface under ultra-high-vacuum conditions. These arrays provide versatile templates for the handling and organization of functional species at the nanoscale, as is demonstrated by their use to accommodate C(60) guest molecules. Temperature-controlled studies reveal, at the single-molecule level, how pore size and chemical functionality determine the host-guest interactions.

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Towards Surface‐Supported Supramolecular Architectures: Tailored Coordination Assembly of 1,4‐Benzenedicarboxylate and Fe on Cu(100)

Lingenfelder

Spillmann

Dmitriev

et al. 2004

Chemistry A European J

188

232

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We present a comprehensive investigation of the modular assembly of surface-supported metal-organic coordination systems with specific topologies and high structural stability formed by vapor deposition of 1,4-benzenedicarboxylic acid molecules and iron atoms on a Cu(100) surface under ultra-high vacuum conditions. By making use of the two carboxylate moieties available for lateral linkage to Fe atoms, we succeeded in the fabrication of distinct Fe-carboxylate coordination architectures at the surface by carefully adjusting the ligand and metal concentration ratio and the temperature of the post-deposition annealing treatment. The mononuclear, 1D-polymeric and fully 2D-reticulated metallosupramolecular arrangements obtained were characterized in situ at the single-molecule level by scanning tunneling microscopy.

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Deprotonation-Driven Phase Transformations in Terephthalic Acid Self-Assembly on Cu(100)

et al. 2004

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Self-assembled terephthalic acid adlayers on a Cu(100) surface have been studied by X-ray photoelectron spectroscopy, near-edge X-ray absorption fine structure, and scanning tunneling microscopy in the temperature range 190−400 K under ultrahigh vacuum conditions. We observe three distinct well-ordered phases evolving with increasing temperature. The combined data analysis reveals that thermally activated deprotonation of molecular carboxyl groups is decisive in the irreversible transformation of the respective structures. Their self-assembly is mediated by changing intermolecular hydrogen bond configurations, whereby a flat adsorption geometry is retained.

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