Phosphorus-containing ruthenacycles: exploring their potential in processes relevant to hydrophosphination.

Morrow, Krista Maria Elena

17 April 2012

Phosphorus-containing metallacycles formed from the [2+2] cycloaddition of unsaturated substrates at the Ru-P π-bond of [Ru(η5-indenyl)(PCy2)(PPh3)] (2) were examined as possible intermediates relevant to hydrophosphination. Reagents, intermediates, products, and by-products involved in the [2+2] cycloaddition were identified and analyzed for reactivity and stability. The products, metallacycles of the form [Ru(η5-indenyl)(κ2-RCHCH2PCy2)(PPh3)] (4), were found to undergo facile cycloreversion. An ethylene η2-coordination adduct was directly observed by low temperature 31P{1H} NMR as an intermediate in the [2+2] cycloaddition mechanism. Steric and electronic effects of alkene substituents on metallacycle formation and selectivity were investigated in detail through rate constant and activation parameter determination, as well as collaborative computational DFT analyses and the construction of a Hammett plot. Preliminary attempts at releasing phosphinated products from ruthenacycle complexes via protonolysis and phosphine substitution were conducted. An unexpected metallacyclic product of one of these attempts, [Ru(η5-indenyl)(κ2-CHCHPCy2)(PPh3)] (10), was identified and characterized. / Graduate

cycloaddition

metallacycles

ruthenium

P ligands

hydrophosphination

Understanding the Structure, Bonding and Reactivity of Unsaturated Metallacycles : A Computational Study

Roy, Subhendu

January 2013

Stabilization of highly strained organic species and altering normal reactivity norms of organic fragments by transition metals have been a triumphing feat of organometallic chemistry. A variety of saturated and unsaturated metallacycles result from the reactions of the transition metals with the organic entities. Understanding the structure and bonding of the metallacylces has been indispensable over the years in view of its involvement as intermediates or compounds for numerous synthetic and catalytic applications. In this context, Group 4 metallocenes have unlocked a fascinating chemistry by stabilizing strained unsaturated C4 organic fragments in the form of five-membered metallacyclomulenes, metallacyclopentynes and metallacycloallnes. These molecules do not conform to the existing bonding principles of chemistry. We have carried out a comprehensive theoretical study to understand the unsual stability and reactivity of these metallacycles. Our theoretical study reveals that the unique interaction of the internal carbon atoms along with the terminal carbon atoms with the bent metallocene moiety is the reason for unsual stability of the metallacycles. We have also investigated the mechanism of interesting C-C coupling and cleavage reactions involving metallacyocumulenes. It demonstrates unexpected reaction pathway for these metallacycles. Moreover, based on this understanding, we have predicted and unraveled the stabilization factors of a challenging four membered metallcycloallene complex. Indeed, our prediction about a four-membered heterometallacycle has been realized experimentally. This kind of bonding is intriguing from fundamental perspective and has great relevance in synthesizing unsual structures with interesting properties. Finally, the electronic structure and bonding of a metallocene-alkyne complex is analyzed to determine the nature of bonding. Our aim is to build a conceptual framework to understand these metallacycles and to exploit their chemistry.

Metallacycles

Transition Metal Complexes

Metallacycloallenes

Titanium Metallacyclocumulenes

Zirconium Metallacyclocumulenes

Heterometallacycles

Metallocene-Alkyne Complexes

Metallacycles - Bonding

Metallacycles - Structure

Organometallic Compounds

Organometallic Chemistry

Metallocenes

Metallacyclopentynes

Metallacycloallene

Metallacyclocumulenes

Organic Chemistry

Mononuclear and multinuclear palladacycles as catalysts

Swarts, Andrew John

03 1900

Thesis (MSc)--University of Stellenbosch, 2011. / Please refer to full text for abstract.

Organopalladium compounds

Heck coupling

Metallacycles

Cyclometallated complexes of palladium

Dissertations -- Chemistry

Theses -- Chemistry

Chemistry and Polymer Science

Designing supramolecular liquid-crystalline hybrids from pyrenyl-containing dendrimers and arene ruthenium metallacycles

Pitto-Barry, Anaïs, Barry, Nicolas P.E., Russo, V., Heinrich, B., Donnio, B., Therrien, B., Deschenaux, R.

24 November 2014

Yes / The association of the arene ruthenium metallacycle [Ru4(p-cymene)4(bpe)2(donq)2][DOS]4 (bpe = 1,2-bis(4-pyridyl)ethylene, donq = 5,8-dioxydo-1,4-naphtoquinonato, DOS = dodecyl sulfate) with pyrenyl-functionalized poly(arylester) dendrimers bearing cyanobiphenyl end-groups is reported. The supramolecular dendritic systems display mesomorphic properties as revealed by polarized optical microscopy, differential scanning calorimetry and small-angle X-ray scattering measurements. The multicomponent nature of the dendrimers and of the corresponding host–guest supramolecules (i.e., end-group mesogens, dendritic core, pyrene unit, aliphatic spacers, and metallacycle) leads to the formation of highly segregated mesophases with a complex multilayered structure due to the tendency of the various constitutive building-blocks to separate in different organized zones. The pyrenyl dendrimers exhibit a multilayered smectic A-like phase, thereafter referred to as LamSmA phase to emphasize this unaccustomed morphology. As for the corresponding Ru4–metallacycle adducts, they self-organize into a multicontinuous thermotropic cubic phase with the Im3̅m space group symmetry. This represents a unique example of liquid-crystalline behavior observed for such large and complex supramolecular host–guest assemblies. Models of their supramolecular organizations within both mesophases are proposed. / R.D. thanks the Swiss National Science Foundation (Grant No 200020-140298) for financial support.

Reactivity of metallacycles of palladium : experimental and computational studies

Van Niekerk, Daniel M. E.

03 1900

Thesis (MSc)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: Please refer to full text for abstract

Metallacycles

Palladacycles

C-N chelating ligands

Cationic palladacycles

Orthopalladated complexes

Dissertations -- Chemistry

Theses -- Chemistry

Chemistry and Polymer Science

Vinylanthracene and Triphenylamine Based Luminescent Molecular Systems : From Aggregation-Induced Emission to Explosive Detection

Chowdhury, Aniket

January 2016

In the last few years, considerable efforts have been given to develop sensitive and effective sensors for explosive materials and to generate systems which exhibit high luminescence in both solution and solid-state. The increasing number of terrorist activities around the world have prompted scientists to design effective ways to detect and disarm even the trace amount of explosives. The nitroaromatics (NACs) are the common constituents of most of the explosives due to high explosive velocity and ease of availability. The NACs were extensively used as the main constituents in landmines until World War II. Apart from their explosive behavior, the NACs are well-known environmental pollutants. The industrial waste and the leakages from unexploded landmines are the major contributors towards the soil and ground water contamination. Presently for effective detection of trace amount of explosives, skilled canines and metal based detectors are commonly used. The canines are trained for a specific type of explosives which limit their ability to detect different types of substrates. The chemical sensors that work on the principle of colorimetric and/or fluorimetric detection techniques have emerged as suitable alternative due to cheap production cost, portability and sensitivity. Different types of materials including conjugated polymers, metal-organic frameworks (MOFs), and quantum-dots have been reported as efficient chemosensors for NACs. However, poor solubility in the common organic solvents, low solid-state fluorescence, very high molecular weight and lack of signal amplification have restricted the application of these material for in-field testing. Renewed interests have been invested in small molecule based systems; and metal-organic discrete molecular architectures due to precise control over their photophysical properties and the supramolecular interaction among neighboring molecules that facilitates energy migration among the molecular backbone. On the other hand, recently post-synthetic modification of different molecular systems including MOFs and polymers has emerged as a potential technique to incorporate desired functional groups into the system and to tune their properties with the retention of basic structures. Reports on the post-synthetic modification of discrete metal-organic architectures are rare due to the delicate nature of the metal-organic bonds that ruptures on mild environmental changes. Therefore, post-synthetic functionalization of discrete molecular systems using mild reaction conditions will open up a myriad of possibilities to generate new systems with desired characteristics. Chapter 1 of the thesis will briefly discuss the history of different explosive materials including different detection methodologies that are widely used. It will also include a brief discussion on different small molecular systems with high solid-state luminescence. In Chapter 2, design and synthesis of triphenylamine-based two Platinum(Pt)(II) molecules functionalized with carboxylic acid and ester groups including their organic analogues have been discussed. The triphenylamine core was chosen due its unique non-planarity and luminescence. On the other hand, Pt(II) center was incorporated to increase intermolecular spacing in solid-state that can induce high luminescence. Scheme 1. Schematic representation of fluorescence quenching using small molecules. All the four molecules were found to be highly sensitive towards NACs including picric acid and dinitrophenol. Although the molecules exhibited similar sensitivity in solution, the carboxylic acid analogues demonstrated superior sensitivity in solid-state. Careful observation of the crystal structures of the systems revealed the acid analogues were oriented in a 2-D grid-like pattern that facilitated energy migration among neighboring molecules (Scheme 1.). Chapter 3 describes design, synthesis, and NACs sensing behavior of anthracene-based four purely organic small molecules. The molecules exhibited high selectivity towards picric acid only. All the molecules were found to be highly emissive in both solution and solid-state due to the vinylanthracene backbone (Scheme 2.). Scheme 2. Schematic representation of fluorescence quenching and solid-state sensing behavior. Chapter 4 discusses the strategy to develop mechano-fluorochromic and AIE active triphenylamine-based Pt(II) complex and its organic analogue. The twisted triphenylamine backbone restricted molecular close packing in solid-state; and weak C-H-- interactions were utilized to hinder the motion of the phenyl rings. As a result, the molecules were highly emissive in solid-state. Grinding disrupted the intermolecular interactions and thus mechano-fluorochromic behavior was observed. Due to twisted backbone, the molecules were also found to be AIE active. Both the systems containing terminal aldehyde groups were finally utilized for selective detection of biomolecule cysteine (Scheme 3.). Scheme 3. Mechano-fluorochromic and AIE behavior of the triphenylamine based Pt(II) complex. In Chapter 5 vinylanthracene-based linear donor was used in combination with carbazole-based 90° and triphenylamine-based 120° Pt(II) acceptors to generate (4+4) and (6+6) molecular squares and hexagons, respectively. The vinylanthracene backbone imparts high solution and solid-state luminescence to the system as well as made them AIE active. The molecules were further investigated for the solution and solid-state sensing for NACs and found to be effective for trinitrotoluene (TNT) and dinitrotoluene (DNT) (Scheme 4.). Scheme 4. Schematic representation of AIE active molecular square and its NACs sensing. Chapter 6 describes the formation of Pd3 self-assembled molecular trinuclear barrels containing triphenylamine imidazole donors and Pd(II) acceptors. Using Knoevenagel condensation the aldehyde group present in the barrel was post-synthetically functionalized with Meldrum’s acid. From spectroscopic characterization, it was proved that the structural integrity remained intact after the post-modification treatment (Scheme 6.). Surprisingly, pre-synthetic modification of the donor alone with Meldrum’s acid followed by self-assembly treatment with the Pd(II) ion did not yield trigonal barrel 6.8. Scheme 6. Post-synthetic functionalization of trinuclear barrels using Knoevenagel condensation.(For colour pictures pl see the abstract pdf file)

Luminescent Molecular Systems

Vinylanthracene Sensors

Explosive Materials

Triphenylamine Sensors

Chemical Sensors

Small Molecule Sensors

Aggregation Induced Emission

Explosive Detection

Nitroaromatics (NACs)

Electron-Rich Sensors

Metal Organic Frameworks

Conjugated Polymers

Self-Assembled Molecular Architectures

PtII Luminogen

Platinum(II) Metallacycles

Picric Acid Detection

Inorganic Chemistry