CO2 Binding and Induced Structural Collapse of a Surface-Supported Metal-Organic Network

Extensive efforts have been directed toward identifying catalytic material composites for efficiently transforming CO2 into valuable chemicals. Within this long-standing scientific challenge, the investigation of model systems is of particular interest to gain fundamental insight into the relevant processes and to synergistically advance materials functionalities. Inspired by the ubiquitous presence of metal organic active sites in the conversion of CO2 we study here the interaction of CO2 with a two-dimensional metal organic network synthesized directly on a metal surface as a model system for this class of compounds. The impact of individual CO2 molecules is analyzed using scanning tunneling microscopy supported by density functional theory calculations. Dosage of CO, gas to the thermally robust Fe-carboxylate coordination structure at low temperatures (100 K) leads to a series of substantial rearrangements of the coordination motif; accompanied by a collapse of the entire network structure. Several binding sites of weak and moderate strengths are identified for CO2 near the iron nodes leading to a moderate structural weakening of the existing coordination bonds in the adapted models with no indication of CO2 dissociation. The observations suggest a concerted reaction pathway involving both CO2 and ligand molecules starting at irregular coordination sites that may eventually lead to the collapse of the entire network structure. The electronic properties of the Fe atoms in the carboxylate environment are determinant for the response of the network toward CO2 which depends critically on the local coordination environment. The results highlight that finely tuned metal organic complexes and networks at surfaces present promising features to activate and transform CO2.

Bonding and Charge Transfer in Metal-Organic Coordination Networks on Au(111) with Strong Acceptor Molecules

Nan Jiang, Klaus Kern, Alexander Langner, Sebastian Stepanow

The geometric and electronic structure of two structurally similar metal organic networks grown on the Au(111) surface is investigated by scanning tunnelling microscopy (STM) and spectroscopy (STS) combined with density functional theory (DFT) calculations. The networks are composed of (i) F4TCNQ (C12F4N4, 2,3,5,6-tetrafluoro-7,7,8,8-tetracyanoquino-dimethane) molecules and Au adatoms segregated from the pristine metal surface, and (ii) TCNQ (C12H4N4, 7,7,8,8-tetracyanoquinodimethane) and codeposited Mn atoms. In both cases, the strong electron acceptor character of the molecules results in metal to-ligand charge transfer to the lowest unoccupied molecular orbital (LUMO). The amount of electrons donated from the 4-fold coordinated Mn atoms to TCNQ is higher compared to the 2-fold coordinated Au adatoms to F4TCNQ This behavior is reflected in the appearance of distinct spectral features in STS data in the energy region close to the Fermi level resulting from the intricate interplay between surface states, adatom states, and molecular orbitals. These observations are consistent with a picture in which the LUMO of the TCNQ acceptor molecule hybridizes with Mn and Au substrate metal states becoming practically filled, while the LUMO of F4TCNQ is only partially filled despite being the stronger electron acceptor. Our results reveal the importance of the type of bonding between the strong acceptor and the metal center (Au or Mn) as well as its coordination in the determination of the charge transfer to the adlayer, which is important for its electronic properties.

Amer Chemical Soc2012

Design of Surface-Supported Bio-inspired Networks for CO2 and O2 Activation at Room Temperature

Daniel Eduardo Hurtado Salinas

The structure of a biological system defines its function. Therefore, nature has developed sophisticated systems that catalyze chemical reactions that are vital for life on earth. For instance, the photosynthesis is a biological process that is partially regulated by the metallo-enzyme RuBisCO (Ribulose-1,5-bisphosphate carboxylase/oxygenase), whose function is to catalyze the capture and transfer of CO2 into organic molecules. This carboxylation reaction occurs at the active site, where a magnesium ion (Mg2+) is bound to organic molecules with carboxylate (COO-) and amine (NH2) functional groups. In the last decades, supramolecular chemistry has proven to be a valid approach to replicate the structural characteristics of these natural metal-organic systems. Metal atoms and organic molecules are used as building blocks to form two-dimensional (2D) metal-organic networks (MONs) on metal surfaces, through a self-assembly process that occurs spontaneously. In these systems the molecules bind to the metal centers and control their oxidation states that, as found in metallo-enzymes, is crucial to perform a catalytic task. Therefore, these supramolecular assemblies show promising features to be explored for heterogeneous catalysis. The main objective of this thesis is to reverse the structure-function equation, that is: instead of finding specific functions of well-known 2D structures for future applications, 2D structures are designed to reproduce the specific functions of well-known bio-systems. Thus, inspired in the structure of the active site of RuBisCO, 2D Mg-based supramolecular assemblies are rationally designed on Cu(100) or Mg(0001) surfaces at room temperature (RT) as a platform for CO2 adsorption. This work is the first study of self-assembly of alkaline earth metal atoms (Mg) with organic molecules ((1,4-benzenedicarboxylic acid (TPA) and 2,4,6-tris(4-aminophenyl)-1,3,5-triazine (TAPT)) on metal surfaces. The first part of this thesis investigates the self-assembly of TAPT molecules. Scanning Tunneling Microscopy (STM) and High Resolution X-ray Photoemission Spectroscopy (HR-XPS) demonstrate that the molecules typically semi-deprotonate to form MONs with the adatoms from the host substrates. The exposure of these structures to CO2 results in the carboxylation of the amino groups. The second part proves that the COOH moieties of TPA molecules fully-deprotonate to form homo-molecular structures. The incorporation of Mg adatoms result in ionic MONs, which reproduce the carboxylate environment of the active site of RuBiSCO. STM, XPS and Density Functional Theory (DFT) analyze the structural changes, the chemical reactions and charge transfer during either the CO2 or O2 adsorption on the Mg2+ centers. The last part focusses on the co-deposition of both molecules to form 2D metallic-hetero-molecular networks with Mg2+ centers. The role of the Mg2+ centers as active sites for molecular adsorption and model systems for gas storage is studied. STM reveals that CO2 partially modifies the network towards a configuration that resembles the active site of RuBisCO. The formation of 3D structures to enhance CO2 adsorption is also evaluated.

EPFL2018

Scanning tunneling microscopy on large bio-molecular systems on surfaces

Sebastian Koslowski

The ever growing demand for the development of new technologies and materials has led to extensive studies inspired by biological functional complexes. Peptides with their outstanding ability to efficiently self-assemble can express a broad spectrum of intriguing functionalities. A key question in mimicking their assembly and function is the precise understanding of the specific interactions between the contained amino acids on the level of a sub-molecular length scale. An excellent tool to probe samples at these length scales is available with scanning tunneling microscopy (STM) and its operation under the controlled conditions of ultra-high vacuum (UHV) and low temperature. Within this thesis it is demonstrated how high-resolution studies by STMin combination with a controlled sample preparation by electrospray ion beam deposition (ES-IBD) under UHV conditions allows for the structural determination of peptides on surfaces. Furthermore the results presented here contribute to the development of a method capable of directly identifying individual amino acids within a peptide sequence. The structural and electronic properties of molecules on surfaces crucially depend on their interaction with the underlying substrate. Implementing a thin dielectric layer on the metallic surface, electronically decouples molecules from the substrate and enables an unperturbed observation of the molecular electronic structure. In Chapter 2 the properties of hexagonal boron nitride (h-BN) on Rh(111) as decoupling layer are assessed on behalf of the structural and electronic properties of the molecular model system pentacene adsorbed on it. In a second part of this chapter the discovery and the characterization of a new phase of h-BN/Rh(111) is described. In Chapter 3, we gained insight into the properties of amino acids on metal surfaces by utilizing the capability of the STM to probe the structure and the electronic characteristics in high resolution imaging and scanning tunneling spectroscopy (STS). As a second important aspect of this chapter, the modification of STM tips with amino acids is investigated as a method to enhance the structural and electronic resolution. An experimental protocol allowing to adhere amino acids on the STM tip be could developed. Using functional STM tips in STS experiments on amino acids enabled the observation of specific molecular resonances. An obstacle in investigating large bio-polymers, such as natural peptides, is their high structural complexity and conformational freedom. Therefore the utilization of custom designed synthetic sequences tailored towards a specific property is a good approach. In Chapter 4 studies performed on two synthetic peptide sequences deposited by ES-IBD on an Au(111) surface are discussed. The first sequence assembled in ordered two-dimensional networks. A folded gas-phase conformation could be utilized to rationalize the observed structures in the networks. Subsequently it was shown that the self-assembly behavior of the peptide could be steered towards chain-like assemblies by modifying the sequence at the peptide C-terminal. Using specific amino acid functionalized STM tips a sensitivity towards an amino acid of the same type in the peptide sequence could be observed. Thereby a partial sequencing of the synthetic peptide was enabled.