One-dimensional coordination polymers on surfaces: towards single molecule devices

Formation of infinite structures based on the combination of metals and organic ligands, known as coordination polymers (CPs), gives rise to materials with a rich structural diversity and interesting physical and/or chemical properties. Most of the efforts towards applications of CPs have been focus...

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Published inChemical Society reviews Vol. 39; no. 11; pp. 422 - 4233
Main Authors Mas-Ballesté, Rubén, Gómez-Herrero, Julio, Zamora, Félix
Format Journal Article
LanguageEnglish
Published England 19.10.2010
Subjects
catalytic activity
Chemistry, Physical
coordination polymers
Electrodes
Gold - chemistry
ligands
metals
nanowires
physicochemical properties
Polymers - chemistry
Surface Properties
topology
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Summary:Formation of infinite structures based on the combination of metals and organic ligands, known as coordination polymers (CPs), gives rise to materials with a rich structural diversity and interesting physical and/or chemical properties. Most of the efforts towards applications of CPs have been focused on catalysis and gas-storage/separation properties. A novel approach into this field is the organization of CPs on surfaces in the search of nanomaterials with potential technological applications such as nanoelectronics, spintronics or nanosensing. Advances on surface organization of discrete metallo-organic compounds and 2D coordination polymers have been the subject of recent reviews. This tutorial review will fill up a remaining gap in the current literature: a review on one-dimensional coordination polymers on surfaces. First publications on this field appeared in 2005 and, from then, this area experienced a formidable blossoming. One of the main interests of one-dimensional systems arises from their potential use in nanoelectronics as molecular wires. This review summarizes the strategies for the isolation and structural and morphological characterization of several topologies of 1D coordination polymers on surfaces. Several parameters that affect the organization of these systems on surfaces have been taken into account from both experimental and theoretical points of view. This tutorial review will fill up a remaining gap in the current literature: a review on one-dimensional coordination polymers on surfaces.
Bibliography:Rubén Mas-Ballesté (left) was born in Barcelona (Catalonia, Spain) in October of 1975. In 2004 he got his PhD under the supervision of Prof. Pilar González-Duarte and Prof. Agustí Lledós. From June 2004 to November 2007 he was working in Lawrence Que's group at the University of Minnesota (USA) as a postdoctoral associate. At the present he is an associate professor under the "Ramón y Cajal" program at the Universidad Autónoma de Madrid (Spain). His research is focused on the reactivity of metal chalcogenides, synthesis and reactivity of structural and functional models of metalloproteins and inorganic compounds of interest in nanotechnology.
Félix Zamora (centre) was born in 1967 in Cuenca (Spain). In 1994 he obtained the PhD in Inorganic Chemistry at Universidad Autónoma de Madrid. He moved to University of Dortmund (Germany) to work with Professor B. Lippert. He is currently "Profesor Titular" in the Inorganic Chemistry Department at the Universidad Autónoma de Madrid. From 2004 he focused on new nanomaterials based on inorganic systems. His group has developed novel methods to organize coordination polymers on surfaces toward the characterization of their electrical, magnetic and molecular-recognition properties by means of methods based on Atomic Force Microscopy.
Julio Gómez-Herrero (right) was born in 1963 in Madrid, Spain. He obtained his PhD in the Universidad Autónoma de Madrid and then he moved first to Berkeley, to work with Professor Miquel Salmeron and then to Purdue where he worked in Professor Reinfenberger's group. He is currently a full Professor at the Universidad Autónoma de Madrid. His main research lines are scanning probe microscopy and electrical transport at the nanoscale.
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ISSN:0306-0012
1460-4744
1460-4744
DOI:10.1039/c001965h