Bifunctional Systems in the Chemistry of Frustrated Lewis Pairs

Zhao, Xiaoxi

08 January 2013

Three classes of bifunctional compounds related to frustrated Lewis pair chemistry were studied. The first class, alkynyl-linked phosphonium borates, was strategically synthesized and the corresponding neutral alkynyl-linked phosphine boranes generated in solution. They were reacted with THF, alkenes and alkynes to undergo either ring-opening or multiple bond addition reactions, giving rise to zwitterionic macrocycles. In two select alkynyl-linked phosphonium borates, thermolysis resulted in unique rearrangements transforming the phosphino- and boryl-substituted alkynyl moieties into C4 chains. The alkynyl-linked phosphine boranes were further demonstrated to coordinate as η3-BCC ligands in Ni(0) complexes. The rigid nature of the coordination was confirmed by dimerization without cleavage of the Ni–B interaction upon the addition of acetonitrile or carbon monoxide. Moreover, reactions with Al-, Zn- and B-based Lewis acids prompted hydride transfer within the alkynyl-linked phosphonium borate and interesting functional group transfer reactions. The second class of the bifunctional systems, a series of gem-substituted bis-boranes, was subjected to reactions with tBu3P and CO2. The O-linked bis-borane was shown to coordinate the phosphino-carboxylate moiety with one B, while the methylene-linked bis-boranes were demonstrated to chelate the carboxyl group. The third bifunctional system class, vinyl-group tethered boranes, was examined to elucidate the mechanism of the frustrated Lewis pair addition reaction to olefins. Using a bis(pentafluorophenyl)alkylborane, the close proximity of the olefinic protons and the ortho-fluorine nuclei were evident by both NOE measurements and DFT calculations. Moreover, its reactions with phosphine bases suggested that an initial interaction between the highly electrophilic borane and the olefinic fragment precedes such frustrated Lewis pair addition reaction. Furthermore, a bis(pentafluorophenyl)alkoxyborane was synthesized and reacted with P-, N-, C- and H-based nucleophiles, demonstrating the wide range of Lewis bases that can be applied in olefin addition reactions with complementary regioselectivity.

inorganic chemistry

main group elements

phosphine

borane

frustrated Lewis pairs

small molecule activation

0488

Small Molecule Activation with Main Group Complexes

Dureen, Meghan Adrienne

16 March 2011

The synthesis of monodentate biphenyl-amido proligands is reported as well as a series of complexes of lithium with these ligand systems. The solid-state molecular structure of these lithium amides are described as well as their use as synthons in the preparation of amido-arene aluminum complexes. Structural and spectroscopic data suggest that these species exhibit weak arene to metal donation. Attempts to generate aluminum cations from these species are detailed. A new synthetic route to titanium “constrained geometry” precatalysts was utilized to prepare a series of titanium complexes with similar pendant arene groups. The homopolymerization activity of these catalyst systems with ethylene and styrene is detailed. Combination of a sterically encumbered phosphine and large, electrophilic borane was used to effect heterolytic cleavage of disulfides to afford novel thiophosphoniumthioborate salts. A series of exchange reactions demonstrated the facile reversal of this reaction. Similar phosphine-borane systems are found to exhibit divergent reactivity with terminal alkynes, affording either phosphonium-alkynylborate salts from deprotonation or phosphonium-vinyl-borate zwitterions from addition. The scope of Lewis acid, Lewis base and alkyne combinations used to effect similar reactivity is detailed. It was found that the reaction of pyrroles, boranes, and alkynes formed similar addition products that were found to undergo further reactivity to afford C-vinyl pyrroles and nitrogen-boron bicyclic compounds. The synthesis of N-alkyl-bis(pentafluorophenyl)boryl amidinates is presented. The reactivity of these compounds with a variety of small molecules is reported. Reaction with CO2, CO, di-iso-propylcarbodiimide, tert-butyl isocyanide, and benzaldehyde as well as thermally-induced intramolecular rearrangement of these compounds affords a variety of novel nitrogen-boron heterocycles.

main group

small molecule activation

catalysts

ethylene polymerzation

alkynes

disulfides

0488

Small Molecule Activation with Main Group Complexes

Dureen, Meghan Adrienne

16 March 2011

The synthesis of monodentate biphenyl-amido proligands is reported as well as a series of complexes of lithium with these ligand systems. The solid-state molecular structure of these lithium amides are described as well as their use as synthons in the preparation of amido-arene aluminum complexes. Structural and spectroscopic data suggest that these species exhibit weak arene to metal donation. Attempts to generate aluminum cations from these species are detailed. A new synthetic route to titanium “constrained geometry” precatalysts was utilized to prepare a series of titanium complexes with similar pendant arene groups. The homopolymerization activity of these catalyst systems with ethylene and styrene is detailed. Combination of a sterically encumbered phosphine and large, electrophilic borane was used to effect heterolytic cleavage of disulfides to afford novel thiophosphoniumthioborate salts. A series of exchange reactions demonstrated the facile reversal of this reaction. Similar phosphine-borane systems are found to exhibit divergent reactivity with terminal alkynes, affording either phosphonium-alkynylborate salts from deprotonation or phosphonium-vinyl-borate zwitterions from addition. The scope of Lewis acid, Lewis base and alkyne combinations used to effect similar reactivity is detailed. It was found that the reaction of pyrroles, boranes, and alkynes formed similar addition products that were found to undergo further reactivity to afford C-vinyl pyrroles and nitrogen-boron bicyclic compounds. The synthesis of N-alkyl-bis(pentafluorophenyl)boryl amidinates is presented. The reactivity of these compounds with a variety of small molecules is reported. Reaction with CO2, CO, di-iso-propylcarbodiimide, tert-butyl isocyanide, and benzaldehyde as well as thermally-induced intramolecular rearrangement of these compounds affords a variety of novel nitrogen-boron heterocycles.

main group

small molecule activation

catalysts

ethylene polymerzation

alkynes

disulfides

0488

Main group semiconducting materials : boron arsenide and an ester-functionalized salophen aluminum polymer

Swingle, Sarah Faye

12 September 2013

Boron arsenide is a compound main group semiconductor with a theoretical band gap in the range of 1.1 to 1.6 eV. Despite this ideal band gap, experimental studies of boron arsenide are very limited. In the present work, single source precursors with covalent bonds between boron and arsenic and labile ligands have been designed and synthesized. These precursors underwent thermal or chemical treatment to produce boron arsenide materials. Boron arsenide has also been prepared as a thin layer deposited on a boron substrate and a p-type photoelectrode was prepared from this material. The structure of the product was identified on the basis of X-ray diffraction and scanning electron microscopy, and the surface composition was determined by means of X-ray photoelectron spectroscopy. The electrode was found to be photoactive under both visible and UV-visible light irradiation and displayed a photocurrent of approximately 0.1 mA/cm² under UV-visible light irradiation at an applied potential of -0.25 V vs. Ag/AgCl. The valence band was estimated to be -5.1 eV. The indirect band gap, as determined from incident photo-to-electron conversion efficiency plots, is 1.46 eV. An ester-fuctionalized salophen aluminum complex that features a polymerizable bithiophene as the ester R group has been designed and synthesized. Metallopolymers of this type offer the additional advantages of processability and uniformity of the resulting films. The new salophen complex exhibited emission in the blue region at 491 nm with a quantum yield of 8.19%, which is significantly larger than that of the isolated ligand. Electropolymerization of this complex on a platinum button electrode resulted in the formation of an electrically conductive polymer that is also ionically conductive at low scan rates. In the polymeric form, the emission wavelength was found to be red-shifted to 505 nm. / text

Main group

Semiconductor

Boron arsenide

Aluminum salophen

Single source precursor

Blue emission

Investigations into the Reactivity and Structure of Phosphinophosphonium Cations and Related Species

Carpenter, Yuen-ying S.

07 December 2010

Carbon and phosphorus have often been compared owing to their diagonal relationship on the periodic table. However, relative to carbon, there remains an enormous breadth of polyphosphorus chemistry that is unexplored, particularly in the area of cationic phosphorus. A key step in the systematic and rational development of larger catenated organo-polyphosphorus cations is a fundamental understanding of the reactivity of small cationic building blocks. The smallest catenated framework in this context is the phosphinophosphonium monocation [R3P-PR2]+ (or phosphine-stabilized phosphenium cation), which can be prepared with a variety of functional groups at either phosphorus centre. This dissertation explores the diverse reactivity of chloro-substituted phosphinophosphonium cations, with a particular focus on reductive coupling as a synthetic route to novel catena-phosphorus systems. The resulting cationic frameworks are comprehensively described in terms of their diasteroisomerism, solution dynamics, and solid-state structural features. Additionally, fundamental electrochemical investigations of these diphosphorus cations are outlined as a tool for understanding and quantifying the reactivity of phosphenium cations. Finally, extension of reductive coupling methodology to the first chlorostibinophosphonium cations presents a promising outlook towards the catenation of the heavier pnictogen cations.

phosphorus

antimony

cations

inorganic chemistry

synthetic chemistry

electrochemistry

main group chemistry

Small Molecule Activation and Transformation using Aluminum-based Frustrated Lewis Pairs

Menard, Gabriel

09 August 2013

While hundreds of papers have been published on frustrated Lewis pairs (FLPs) – the combination of bulky Lewis acids and bases which cannot form adducts – few of these use aluminum-based Lewis acids. The research outlined in this thesis expands the small molecule activation chemistry of FLPs to include Al.Combinations of bulky phosphines and AlX3 (X = halide or C6F5) with CO2 leads to the rapid activation to form the complexes R3P(CO2)(AlX3)2 (R = otol, Mes). Subsequent treatment with ammonia borane (AB) results in the rapid reduction of the CO2 fragment to methanol after water quench. Subsequent reactivity studies have established that AB adducts of AlX3, which react with CO2, are key intermediates in this chemistry. Further studies with Mes3P(CO2)(AlX3)2 revealed that these can reduce exogenous CO2 to CO, along with the generation of Mes3P(C(OAlX2)2O)(AlX3) and [Mes3PX][AlX4]. Detailed experimental and theoretical mechanistic investigations outline a possible mechanism involving direct CO2 insertion into free AlX3, followed by nucleophilic attack by PMes3 resulting in the expulsion of CO. Reactions with olefins were also investigated. While addition products of the type R3P(CH2CH2)AlX3 could be obtained with ethylene, C–H bond activation occurred with bulkier olefins. The resulting allyl species underwent subsequent C–C bond forming reactions with other olefins or CO2. Hydrogen was also activated using PR3/AlX3 FLPs to form species of the general formula, [R3PH][(H)(AlX3)2] (X = I, C6F5). These were found to reduce unactivated olefins, generating the redistributed products [R3PH][AlX4] and RAlX2 (R = alkyl). Attempts to circumvent this redistribution and favour alkyl protonation, thus generating a catalytic hydrogenation catalyst, are also discussed. Finally, the activation of N2O was also examined. While addition products could be formed, unexpected aromatic or benzylic C–H bond activation chemistry occurred in the presence of excess Al. A radical reaction pathway is proposed

Frustrated Lewis pairs

Aluminum

small molecule activation

CO2

N2O

H2

main group

phosphine

0488

Bifunctional Systems in the Chemistry of Frustrated Lewis Pairs

Zhao, Xiaoxi

08 January 2013

Three classes of bifunctional compounds related to frustrated Lewis pair chemistry were studied. The first class, alkynyl-linked phosphonium borates, was strategically synthesized and the corresponding neutral alkynyl-linked phosphine boranes generated in solution. They were reacted with THF, alkenes and alkynes to undergo either ring-opening or multiple bond addition reactions, giving rise to zwitterionic macrocycles. In two select alkynyl-linked phosphonium borates, thermolysis resulted in unique rearrangements transforming the phosphino- and boryl-substituted alkynyl moieties into C4 chains. The alkynyl-linked phosphine boranes were further demonstrated to coordinate as η3-BCC ligands in Ni(0) complexes. The rigid nature of the coordination was confirmed by dimerization without cleavage of the Ni–B interaction upon the addition of acetonitrile or carbon monoxide. Moreover, reactions with Al-, Zn- and B-based Lewis acids prompted hydride transfer within the alkynyl-linked phosphonium borate and interesting functional group transfer reactions. The second class of the bifunctional systems, a series of gem-substituted bis-boranes, was subjected to reactions with tBu3P and CO2. The O-linked bis-borane was shown to coordinate the phosphino-carboxylate moiety with one B, while the methylene-linked bis-boranes were demonstrated to chelate the carboxyl group. The third bifunctional system class, vinyl-group tethered boranes, was examined to elucidate the mechanism of the frustrated Lewis pair addition reaction to olefins. Using a bis(pentafluorophenyl)alkylborane, the close proximity of the olefinic protons and the ortho-fluorine nuclei were evident by both NOE measurements and DFT calculations. Moreover, its reactions with phosphine bases suggested that an initial interaction between the highly electrophilic borane and the olefinic fragment precedes such frustrated Lewis pair addition reaction. Furthermore, a bis(pentafluorophenyl)alkoxyborane was synthesized and reacted with P-, N-, C- and H-based nucleophiles, demonstrating the wide range of Lewis bases that can be applied in olefin addition reactions with complementary regioselectivity.

inorganic chemistry

main group elements

phosphine

borane

frustrated Lewis pairs

small molecule activation

0488

Small Molecule Activation and Transformation using Aluminum-based Frustrated Lewis Pairs

Menard, Gabriel

09 August 2013

While hundreds of papers have been published on frustrated Lewis pairs (FLPs) – the combination of bulky Lewis acids and bases which cannot form adducts – few of these use aluminum-based Lewis acids. The research outlined in this thesis expands the small molecule activation chemistry of FLPs to include Al.Combinations of bulky phosphines and AlX3 (X = halide or C6F5) with CO2 leads to the rapid activation to form the complexes R3P(CO2)(AlX3)2 (R = otol, Mes). Subsequent treatment with ammonia borane (AB) results in the rapid reduction of the CO2 fragment to methanol after water quench. Subsequent reactivity studies have established that AB adducts of AlX3, which react with CO2, are key intermediates in this chemistry. Further studies with Mes3P(CO2)(AlX3)2 revealed that these can reduce exogenous CO2 to CO, along with the generation of Mes3P(C(OAlX2)2O)(AlX3) and [Mes3PX][AlX4]. Detailed experimental and theoretical mechanistic investigations outline a possible mechanism involving direct CO2 insertion into free AlX3, followed by nucleophilic attack by PMes3 resulting in the expulsion of CO. Reactions with olefins were also investigated. While addition products of the type R3P(CH2CH2)AlX3 could be obtained with ethylene, C–H bond activation occurred with bulkier olefins. The resulting allyl species underwent subsequent C–C bond forming reactions with other olefins or CO2. Hydrogen was also activated using PR3/AlX3 FLPs to form species of the general formula, [R3PH][(H)(AlX3)2] (X = I, C6F5). These were found to reduce unactivated olefins, generating the redistributed products [R3PH][AlX4] and RAlX2 (R = alkyl). Attempts to circumvent this redistribution and favour alkyl protonation, thus generating a catalytic hydrogenation catalyst, are also discussed. Finally, the activation of N2O was also examined. While addition products could be formed, unexpected aromatic or benzylic C–H bond activation chemistry occurred in the presence of excess Al. A radical reaction pathway is proposed

Frustrated Lewis pairs

Aluminum

small molecule activation

CO2

N2O

H2

main group

phosphine

0488

Schiff's bases as solvent extraction reagents

Richardson, Ralph Alan

January 1972

The solvent extraction of metal chelates has been used for a long time for separation and determination of metal ions. The first quantitative description of the extraction process was, however, not made until 1941 when Kolthoff and Sandell compared experimental data with theoretical predictions for the extraction of metal dithizonates. They found that the theory they proposed was valid under wide experimental conditions. However, the systems used by Kolthoff and Sandell were simple ones and hence relatively simple theory was used to successfully explain their behaviour. In practice solvent extraction systems are complicated by other factors, e.g. hydrolysis, polymerisation and complex formation in the aqueous phase. It has subsequently become apparent that such factors have an important influence on the solvent extraction of chelates. Several authors have published reports since 1941 on the theory of solvent extraction of metal chelates which take these factors into account. In particular two publications by Irving, Rossotti and Williams and Stary (chapter 3) should be noted for their comprehensive treatment of the subject. The influence of these factors will be discussed in the following sections.

Aspects of the chemistry of titanium dioxide in fused salt solvents

Udy, David John

January 1973

An investigation into the chemistry of solutions of titanium dioxide in fused alkali metal borates has been made, with the emphasis on the ability of the alkali borate melts to dissolve TiO2 and subsequently crystallize TiO2 and/or complex alkali metal titanates. The preparation and properties of potassium titanates with K2O/TiO2 mol ratio ≤1 has been studied. In addition the thermal decomposition of potassium hexafluorotitanate monohydrate (reported to yield potassium tetratitanate) has been investigated. The decomposition product has been identified as an oxyfluorotitanate. The compounds crystallized on slow cooling of alkali borate + TiO2 melts have been identified. The titanium containing product(s) have been correlated with the concentration of borate groups containing non-bridging oxygens, which depends on the alkali metal cation. Phase diagrams for the M2O.B2O3 + TiO2 (M = Na, K) systems have been obtained. Mass transport in M2O.2B2O3 + TiO2 (M = Li, Na, K) systems has been studied, via measurements of electrical conductivity, as a function of temperature and TiO2 concentration. Additional information on the alkali borate melts has been obtained from measurements of the optical basicity of M2O + B2O3 (M = Li, Na, K, Rb, Cs) glasses, using Pb(II) as probe ion. The results of these measurements have confirmed that the nature of the alkali metal cation significantly affects the basicity of fused alkali borate solvents. Extraction of TiO2 from ilmenite and titaniferous slag, using selected low-basicity alkali borate solvents has been attempted. The results indicate that TiO2 may be separated from ilmenite in essentially a one-step process.