The chemistry and catalytic activity of dehydrogenative silylation and hydroboration of complexes bearing semirigid ligands with group 14 elements

Abeynayake, Niroshani S.

09 December 2022

Incorporation of silicon in the ligand backbone would yield electron-rich metal complexes upon coordination to transition metal complexes. The coordination chemistry of semirigid benzyl phosphines bearing a single or multiple phosphorus atoms and varying number of Si−H moieties has gained interest in recent years. This dissertation focuses on synthesizing silyl and germyl transition metal complexes of groups 9 and 10. Chapter II presents the synthesis of a family of four coordinated 14-electron rhodium complexes. The newly synthesized complexes were characterized in solution by multinuclear NMR spectroscopy and in the solid-state by single-crystal X-ray diffraction. These d6 complexes possess sawhorse geometry around the rhodium metal center. The catalytic activity of the synthesized Rh complexes and the analogous Ir complex towards hydrosilylation/ dehydrogenative silylation of alkenes is presented in this study. Importantly, it was observed that the selectivity of the catalytic reaction can modify the choice of the metal center, rendering hydrosilylation products upon the use of Rh or dehydrogenative silylated product upon the use of Ir. In chapter III, the results of our investigations on the catalytic activity in dehydrogenative silylation of alkenes by Rh2(OAc)4/ PPh3 system are presented. Sacrificial hydrogen acceptor, norbornene, and PPh3 play a key role in specificity favoring the dehydrogenative silylated product. The substrate scope and the possible mechanistic pathways are reviewed. Chapters IV and V present the synthesis of EP3-type (E = Si, Ge) tetradentate ligands. We describe the synthesis via E−H bond activation and characterization of their nickel and cobalt complexes by spectroscopic means. Additionally, the solid-state structures of the complexes were confirmed by X-ray crystallography. The catalytic activity of the synthesized nickel hydrides was investigated in the hydroboration of aldehydes by pinacolborane (HBpin). The catalytic activity of the synthesized cobalt(I) complex was studied in the presence of (EtO)3SiH with aldehydes and ketones bearing various functional groups under mild conditions. In Chapter VI, the syntheses of octahedral rhodium and iridium [(Ph2P-o-CH2-C6H4)3E]MClH (M = Rh, Ir: E = Si, Ge) complexes bearing EP3-type tetradentate ligands via EH bond activation are presented. We also describe the synthesis and characterization of platinum complexes supported by EP3-type tetradentate ligands.

chemistry

catalytic activity

hydrosilylation

hydroboration

group 14

transition metals

ligands

Inorganic Chemistry

Organic Chemistry

Heavy-Core Staffanes : A Computational Study of Their Fundamental Properties of Interest for Molecular Electronics

Sandström, Niclas

January 2007

<p>The basic building blocks in molecular electronics often correspond to conjugated molecules. A compound class consisting of rigid rod-like staffane molecules with the heavier Group 14 elements Si, Ge, Sn and Pb at their bridgehead positions has now been investigated. Herein these oligomers are called heavy-core or Si-, Ge-, Sn- or Pb-core staffanes. These compounds benefit from interaction through their bicyclo[1.1.1]pentane monomer units. Quantum chemical calculations were performed to probe their geometries, stabilities and electronic properties associated with conjugation.</p><p>The stabilities of the bicyclo[<i>n.n.n</i>]alkane and [<i>n.n.n</i>]propellanes (1 ≤ <i>n</i> ≤ 3) with C, Si, Ge and Sn at the bridgehead positions were studied by calculation of homodesmotic ring strain energies. The bicyclic compounds with <i>n</i> = 1 and Si, Ge or Sn at bridgehead positions have lower strain than the all-carbon compound.</p><p>A gradually higher polarizability exaltation is found as the bridgehead element is changed from C to Si, Ge, Sn or Pb. The ratio between longitudinal and average polarizability also increases gradually as Group 14 is descended, consistent with enhanced conjugation in the heavier oligomers.</p><p>The localization of polarons in C-, Si- and Sn-core staffane radical cations was calculated along with internal reorganization energies. The polaron is less localized in Si- and Sn-core than in C-core staffane radical cation. The reorganization energies are also lower for the heavier staffanes, facilitating hole mobility when compared to the C-core staffanes.</p><p>The effect of the bicyclic structure on the low valence excitations in the UV-spectra of compounds with two connected disilyl segments was also investigated. MS-CASPT2 calculations of 1,4-disilyl- and 1,4-bis(trimethylsilyl)-1,4-disilabicyclo[2.2.1]heptanes and 1,4-disilyl- and 1,4-bis(trimethylsilyl)-1,4-disilabicyclo[2.1.1]hexanes revealed that although the bicyclic cage separates the two disilyl chromophores, there is a strong red-shift of the lowest valence excitations when compared to an isolated disilane.</p>

Organic chemistry

conjugation

polarizability

Group 14 elements

cage compounds

electronic excitations

quantum chemistry

molecular electronics

Organisk kemi

Organic Heavy Group 14 Element Compounds : A Study of Their Chemical Bonding Properties Directed Towards Applications as Molecular Wires and in Synthesis

Tibbelin, Julius

January 2010

The research described herein includes synthesis, spectroscopy, and quantum chemical calculations with focus on the characteristic properties of compounds with bonds between carbon and the heavier Group 14 elements. The chapters based on the first four papers concern σ- and σ/π-conjugated compounds, although the focus of the first paper is on ring strain of bicyclo[1.1.1]pentanes with C, Si, Ge or Sn at the bridgeheads. The relationship between calculated homodesmotic ring strain energies and through-space distances between the bridgehead atoms was evaluated, and it was found that replacing one of the methylene bridges with phospha-methyl gave both low strain and short through-space distance. Two kinds of σ/π-interacting systems were analysed with the difference that the σ- and π-bonded segments were either allowed to rotate freely relative each other or frozen into a conformer with maximal σ/π-interaction. The freely rotating systems are star-shaped oligothiophenes linked by heavy alkane segments. Density functional theory (DFT) calculations of hole reorganization energies support the measured hole mobilites. In summary, longer central oligosilane linkages, when compared to shorter, facilitate intermolecular hole-transfer between oligothiophene units. In 1,4-disilacyclohexa-2,5-dienes, the strength of the π- and pseudo-π interaction depends on the substituents at Si. Vapour phase UV absorption spectroscopy of 2,3,5,6-tetraethyl-1,1,4,4-tetrakis(trimethylsilyl)-1,4-disilacyclohexa-2,5-diene reveals a strong absorption at 273 nm (4.50 eV). Time-dependent DFT calculations further indicate that octastannylated 1,4-disilacyclohexa-2,5-diene has is lowest excited state at 384 nm (3.23 eV). The electronic, geometric and optical properties of substituted 1,4-disilacyclohexa-2,5-dienes were compared with those of the correspondingly substituted siloles. It was found that the lowest excitations of siloles are less tunable than those of 1,4-disilacyclohexa-2,5-dienes. The final section concerns strongly reverse-polarised 2-amino-2-siloxysilenes formed thermally from carbamylpolysilanes, and their lack of reaction with alcohols. Instead, the carbamylsilane reacts with alcohols giving silyl ethers, leading to a new benign route for alcohol protection.

Silicon

Group 14 Elements

Silenes

Conjugation

Chemical Bonding

Electronic Structure

Protecting Group Chemistry

Physical organic chemistry

Fysikalisk organisk kemi

Heavy-Core Staffanes : A Computational Study of Their Fundamental Properties of Interest for Molecular Electronics

Sandström, Niclas

January 2007

The basic building blocks in molecular electronics often correspond to conjugated molecules. A compound class consisting of rigid rod-like staffane molecules with the heavier Group 14 elements Si, Ge, Sn and Pb at their bridgehead positions has now been investigated. Herein these oligomers are called heavy-core or Si-, Ge-, Sn- or Pb-core staffanes. These compounds benefit from interaction through their bicyclo[1.1.1]pentane monomer units. Quantum chemical calculations were performed to probe their geometries, stabilities and electronic properties associated with conjugation. The stabilities of the bicyclo[n.n.n]alkane and [n.n.n]propellanes (1 ≤ n ≤ 3) with C, Si, Ge and Sn at the bridgehead positions were studied by calculation of homodesmotic ring strain energies. The bicyclic compounds with n = 1 and Si, Ge or Sn at bridgehead positions have lower strain than the all-carbon compound. A gradually higher polarizability exaltation is found as the bridgehead element is changed from C to Si, Ge, Sn or Pb. The ratio between longitudinal and average polarizability also increases gradually as Group 14 is descended, consistent with enhanced conjugation in the heavier oligomers. The localization of polarons in C-, Si- and Sn-core staffane radical cations was calculated along with internal reorganization energies. The polaron is less localized in Si- and Sn-core than in C-core staffane radical cation. The reorganization energies are also lower for the heavier staffanes, facilitating hole mobility when compared to the C-core staffanes. The effect of the bicyclic structure on the low valence excitations in the UV-spectra of compounds with two connected disilyl segments was also investigated. MS-CASPT2 calculations of 1,4-disilyl- and 1,4-bis(trimethylsilyl)-1,4-disilabicyclo[2.2.1]heptanes and 1,4-disilyl- and 1,4-bis(trimethylsilyl)-1,4-disilabicyclo[2.1.1]hexanes revealed that although the bicyclic cage separates the two disilyl chromophores, there is a strong red-shift of the lowest valence excitations when compared to an isolated disilane.

Organic chemistry

conjugation

polarizability

Group 14 elements

cage compounds

electronic excitations

quantum chemistry

molecular electronics

Organisk kemi

Interaktivní tabule ve výuce anorganické chemie na SŠ - IV.A (14. skupina) / Interactive Whiteboard in Inorganic Chemistry Teaching - Group 14 of the Periodic Table of Elements Secondary Education

Studničková, Zuzana

January 2013

1 Abstract The subject of this thesis was creating of teaching material for an interactive whiteboard using the SMART Notebook program. The material was created in form of interactive presentations designed to be used in chemistry lessons at secondary schools. The unifying theme of presentations was the 14th group of the periodic table of elements. The thesis also includes a description of the way the presentations were made and instructions for teachers how to work with them. It also introduces some advantages and disadvantages of working with the SMART Notebook software. Key words: Interactive whiteboard, SMART Notebook, group 14 of the periodic table of elements, presentations, carbon, silicon, tin, lead, germanium

Topological analysis of the cd → β-Sn phase transition of group 14 elements

Matthies, Olga

31 January 2018

To understand the mechanism of a pressure-induced structural phase transition, it is important to know which bonding changes lead to the stabilization of the new structure. A useful approach in this regard is the quantum chemical topology, which provides a large variety of indicators for the characterization of interatomic interactions. In this work, a number of topological indicators are used to analyze the bonding changes during the pressure-induced phase transition from the cubic diamond (cd) to the β-Sn-type structure of the elements of the 14th group of the periodic table. The ability of these indicators to reflect the presence of the cd → β-Sn transition in experiment for Si, Ge and Sn and its absence for carbon is investigated. Furthermore, the effect of pressure on the interatomic interactions in the cd- and β-Sn-type structures is examined. It is observed that the energy change along the cd → β-Sn transformation pathway correlates with the evolution of certain parameters of the electron density and the electron localizability indicator (ELI-D). Accordingly, criteria of structural stability were formulated based on characteristics of interatomic interactions. These results can serve as guidelines for the investigation of other solid-state phase transformations by the topological methods.

Quantenchemische Topologie

Bindungstheorie

Elemente der 14. Gruppe

Phasenübergänge

Quantum Chemical Topology

Bond theory

Group 14 elements

Phase transitions

ddc:540

rvk:VE 5657

Topological analysis of the cd → β-Sn phase transition of group 14 elements

Matthies, Olga

19 December 2017

To understand the mechanism of a pressure-induced structural phase transition, it is important to know which bonding changes lead to the stabilization of the new structure. A useful approach in this regard is the quantum chemical topology, which provides a large variety of indicators for the characterization of interatomic interactions. In this work, a number of topological indicators are used to analyze the bonding changes during the pressure-induced phase transition from the cubic diamond (cd) to the β-Sn-type structure of the elements of the 14th group of the periodic table. The ability of these indicators to reflect the presence of the cd → β-Sn transition in experiment for Si, Ge and Sn and its absence for carbon is investigated. Furthermore, the effect of pressure on the interatomic interactions in the cd- and β-Sn-type structures is examined. It is observed that the energy change along the cd → β-Sn transformation pathway correlates with the evolution of certain parameters of the electron density and the electron localizability indicator (ELI-D). Accordingly, criteria of structural stability were formulated based on characteristics of interatomic interactions. These results can serve as guidelines for the investigation of other solid-state phase transformations by the topological methods.

info:eu-repo/classification/ddc/540

ddc:540