Spelling suggestions: "subject:"nheterocyclic carbenes"" "subject:"heterocyclic carbenes""
1 |
A Stability Comparison and Antimicrobial Evaluation of Gold N-Heterocyclic Carbenes and Their Silver PrecursorsSiciliano, Tammy J. 26 August 2008 (has links)
No description available.
|
2 |
Small molecule activation using electropositive metal N-heterocyclic carbene complexesTurner, Zoe Rose January 2011 (has links)
The versatility of N-heterocyclic carbenes (NHCs) is demonstrated by numerous practical applications in homogeneous transition metal catalysis, organocatalysis and materials science. There remains a paucity of electropositive metal NHC complexes and so this chemistry is poorly developed with respect to that of the late transition metal and main group elements. This thesis describes the synthesis of new alkoxy-tethered NHC proligands, their use in the synthesis of reactive metal amide and metal alkyl complexes, and finally small molecule activation using these complexes. Chapter One introduces NHCs and discusses their use as supporting ligands for early transition metal and f-block complexes. Small molecule activation using organometallic complexes is examined alongside the use of electropositive metal NHC complexes in catalysis. Chapter Two contains the synthesis and characterisation of new alkoxy-tethered NHC proligands and a variety of electropositive MII (M = Mg and Zn), MIII (M = Y, Sc, Ce and U) and MIV (M = Ce and U) amide complexes. X-ray diffraction studies and a DFT study are used to probe the extent of covalency in the bonding of the MIV complexes. Chapter Three investigates the reactivity of the amide complexes prepared in Chapter Two. The MII complexes are shown to be initiators for the polymerisation of raclactide into biodegradable polymers. The MIII complexes are used to demonstrate additionelimination reactivity of polar substrates across the M-Ccarbene bond which allows the formation of new N-E (E = Si, Sn, P or B) bonds. Treatment of the UIII silylamide complex U(N{SiMe3}2)3 with CO results in the reductive coupling and homologation of CO to form an ynediolate core -OC≡CO- and the first example of subsequent reactivity of the ynediolate group. The MIV complexes are used to examine the potential for forming MIV cationic species and alkyl complexes. Chapter Four examines the synthesis of MIII (M = Ce and Sc) aminobenzyl complexes and MIII (M = Y, Sc and U) neosilyl and neopentyl alkyl complexes. The addition-elimination reactivity discussed in Chapter Three is extended to include C-E bond formation (E = Si, Sn, P, B, I or C). Chapter Five provides overall conclusions to the work presented within this thesis. Chapter Six gives experimental and characterising data for all complexes and reactions in this work.
|
3 |
NHCs in organocatalysis : azolium enolate generation and synthetic applicationsDouglas, James J. January 2012 (has links)
This thesis details investigations into organocatalytic reactions promoted by N Heterocyclic Carbenes (NHCs) that proceed via an assumed azolium enolate intermediate. Initial research focused on the catalytic asymmetric synthesis of β-lactones via an NHC-catalysed formal [2+2] cycloaddition of alkylarylketenes and chloral. This process operated in good yield (typically >70%) and moderate diastereoselectivity (typically ~75:25 dr, anti:syn) for a range of alkylarylketenes. The enantioselectivity was consistently high for the major anti diastereomer (typically >80% ee) and minor syn diastereomer (typically >70% ee). Interestingly, when a ketene bearing a 2 substituent on the aryl ring, or one that included an α-branched alkyl group was used, an exclusive asymmetric chlorination pathway was accessed. This is, to the best of our knowledge, the first use of chloral as an electrophilic chlorination agent. This methodology was found to be applicable to a range of 2-arylsubstituted alkylarylketenes in good yield and enantioselectivity (typically >70% yield and up to 92% ee). The scope of this reaction with respect to the aldehyde moiety was then analysed with 2-nitrobenzaldehyde providing β-lactone products in excellent dr (up to 94:6 syn:anti) and with good yield and enantioselectivity (typically >60% yield and >80% ee). Importantly these β-lactone products were amenable to further derivatisation with transformation to β-amino- and β-hydroxy acids. Following the identification of an NHC-catalysed chlorination reaction using chloral, the development of a general procedure was undertaken. Following a wide screen of electrophilic chlorination sources, 2,3,4,5,6,6 hexachlorocyclohexa 2,4 dienone was identified as optimal, operating in excellent yield (up to 97%) but in moderate to poor levels of enantioselectivity (21−61% ee). Efforts to expand the practicality of azolium enolate processes focused on the use of α-aroyloxyaldehydes as bench stable mono-substituted ketene surrogates. A range of differentially substituted α-aroyloxyaldehydes allowed access to δ-lactones via the NHC-catalysed [4+2] cycloaddition between azolium enolates and β,γ unsaturated α ketoesters. Following initial optimisation the reaction proceeded in exquisite diastereo- and enantiocontrol (typically >95:5 dr and >99% ee).
|
4 |
Design, Synthesis and Catalytic Activity of Di-<i>N</i>-Heterocyclic Carbene Complexes of Nickel and PalladiumPaulose, Tressia Alias Princy 05 August 2009
<i>N</i>-heterocyclic carbenes (NHC) have widely been used as spectator ligands in organometallic chemistry. Chelating bidentate di-<i>N-</i>heterocyclic carbenes (diNHC) provide additional entropic stability to their complexes relative to monodentate analogues. The steric and electronic environment around the metal centre can be fine-tuned by varying the substituents on the nitrogen atoms of the diNHC ligand. Synthesis and characterization of air and moisture stable bis(diimidazolylidene)nickel(II) complexes, [(diNHC)2Ni]2+, and their corresponding silver(I) and palladium(II) analogues are described.<p>
Investigations into the catalytic potential of diNHC complexes of nickel as an alternative to palladium systems in carbon-carbon coupling reactions are discussed. In the Suzuki-Miyaura coupling reaction, the [(diNHC)2Ni]2+ complex was active for the coupling of aryl chlorides as well as aryl fluorides. The analogously synthesized Pd(II) complexes resulted in formation of (diNHC)PdCl2 species which were not active for the coupling of aryl fluorides. Transition-metal free coupling reactions were investigated and the results indicated that in the Mizoroki-Heck reaction, aryl iodides could be activated in the absence of nickel or palladium precatalysts when using Na2CO3 or NEt3 as base, while in the Suzuki-Miyaura reaction, aryl iodides and aryl bromides could be activated without any precatalyst when K3PO4 was used as base.<p>
A general route into the synthesis of non-symmetrically substituted ligand precursors has been developed. Synthesis and characterization of non-symmetrically substituted ligand precursors, and their corresponding silver(I), palladium(II) and nickel(II) complexes are described. The activity of one of the non-symmetrically substituted (diNHC)Pd(II) complexes in the Suzuki-Miyaura coupling reaction of bulky substrates has been investigated. Non-symmetrically substituted diNHC ligand precursors with a hemi-labile pyridine arm have been synthesized and their corresponding Ni(II) and Pd(II) complexes are described.<p>
Attempts to synthesize three-coordinate Pd(II) complexes using bulky â-diketiminato ligands are also discussed.
|
5 |
Synthesis of Chiral N-Heterocyclic Carbene Precursors and Key Intermediates for Catalytic Enantioselective Cyclizations of Conjugated TrienesWilkerson, Phillip D 29 March 2012 (has links)
Cocatalyzed reactions using Brønsted acids and chiral N-heterocyclic carbenes to yield highly enantioselective products have been reported recently in many journals. The development of new chiral N-heterocyclic carbenes is a competitive field among synthetic chemist. In a recent study we found that conjugated trienes could be cyclized using Brønsted acids and chiral N-heterocyclic carbenes. The synthesis of novel chiral N-heterocyclic carbene precursors, and the precursors to novel conjugated trienes are reported herein.
|
6 |
Design, Synthesis and Catalytic Activity of Di-<i>N</i>-Heterocyclic Carbene Complexes of Nickel and PalladiumPaulose, Tressia Alias Princy 05 August 2009 (has links)
<i>N</i>-heterocyclic carbenes (NHC) have widely been used as spectator ligands in organometallic chemistry. Chelating bidentate di-<i>N-</i>heterocyclic carbenes (diNHC) provide additional entropic stability to their complexes relative to monodentate analogues. The steric and electronic environment around the metal centre can be fine-tuned by varying the substituents on the nitrogen atoms of the diNHC ligand. Synthesis and characterization of air and moisture stable bis(diimidazolylidene)nickel(II) complexes, [(diNHC)2Ni]2+, and their corresponding silver(I) and palladium(II) analogues are described.<p>
Investigations into the catalytic potential of diNHC complexes of nickel as an alternative to palladium systems in carbon-carbon coupling reactions are discussed. In the Suzuki-Miyaura coupling reaction, the [(diNHC)2Ni]2+ complex was active for the coupling of aryl chlorides as well as aryl fluorides. The analogously synthesized Pd(II) complexes resulted in formation of (diNHC)PdCl2 species which were not active for the coupling of aryl fluorides. Transition-metal free coupling reactions were investigated and the results indicated that in the Mizoroki-Heck reaction, aryl iodides could be activated in the absence of nickel or palladium precatalysts when using Na2CO3 or NEt3 as base, while in the Suzuki-Miyaura reaction, aryl iodides and aryl bromides could be activated without any precatalyst when K3PO4 was used as base.<p>
A general route into the synthesis of non-symmetrically substituted ligand precursors has been developed. Synthesis and characterization of non-symmetrically substituted ligand precursors, and their corresponding silver(I), palladium(II) and nickel(II) complexes are described. The activity of one of the non-symmetrically substituted (diNHC)Pd(II) complexes in the Suzuki-Miyaura coupling reaction of bulky substrates has been investigated. Non-symmetrically substituted diNHC ligand precursors with a hemi-labile pyridine arm have been synthesized and their corresponding Ni(II) and Pd(II) complexes are described.<p>
Attempts to synthesize three-coordinate Pd(II) complexes using bulky â-diketiminato ligands are also discussed.
|
7 |
Development of Tetrathiafulvalene Fused N-Heterocyclic Carbene CompoundsRobinson, William J., III January 2020 (has links)
No description available.
|
8 |
SERS Study of N-heterocyclic Carbenes Absorbed on a Silver ElectrodeGe, Mengxin 26 September 2022 (has links)
SERS (surface-enhanced Raman spectroscopy) has the potential to be used in a variety of commercial and basic applications, which often rely on molecules that are bound to a nanostructured metal surface. Thiols are usually used as the intermediate to modify the substrate surface for SERS. In recent years, N-heterocyclic carbene (NHC) has been introduced as an alternative approach for metal surface modification. Nanostructured gold surfaces suitable for SERS had been modified by NHC species. Those studies showed the promising of the NHC modification route for the fabrication of a robust platform for SERS.
The objective of this work is to explore the SERS characteristics of NHC species on silver surfaces. The interactions between two different NHC molecules and a nanostructured silver surface, instead of a gold surface, were studied for the first time. The experiments were realized in electrochemical conditions, using a three-electrodes system, to fully test the stability of the NHC-modified surfaces. The SERS spectra were compared to theoretical calculations and normal Raman in order to identify the vibrational characteristics of the NHC molecules. The effects of different NHC molecule substituents on the electrochemical stability of the surface were also discussed. The results showed that NHC molecules can be decomposed on the silver surface easily under electrochemical conditions. This contrast with the observations in gold, where the NHC monolayers showed a high level of stability.
This work also discusses potential side products which may be derived from the decomposition of the NHC molecules. Raman spectra of potential side products were collected and compared to the NHC SERS collected under electrochemical control at different potentials.
This study provides insights into the influence of the substituents at the NHC on their stability under the electrochemical condition, which should guide the development of future applications. / Graduate
|
9 |
Synthesis and reactivity of low coordinate nickel(I) complexes bearing ring expanded N-heterocyclic carbene ligandsPoulten, Rebecca January 2015 (has links)
This thesis describes the development of nickel(I) complexes incorporating ring expanded N-heterocyclic carbene (RE NHC) ligands and examines their electronic characterisation, activation of O2, reactivity and catalytic applications. A series of three coordinate, paramagnetic Ni(I) complexes of the form Ni(RE NHC)(PPh3)Br (1 – 10) were prepared by comproportionation of Ni(COD)2 and Ni(PPh3)2Br2 in the presence of RE NHCs. The RE NHCs employed varied in the degree of ring expansion (6-, 7- and 8-membered), extent of N-substituent steric bulk (Mes, oTol, oAnis) and the donor/acceptor properties of the carbene (diamino vs. diamido). EPR and DFT electronic characterisation of 1 – 10 confirmed that the unpaired electron was located on the nickel ion in a mixed orbital of predominantly 3dz2 character. Yellow solutions of 1 or 6 (RE NHC = 6Mes and 7Mes respectively) immediately became purple in the presence of O2 due to O2 activation and incorporation of the oxygen atoms as bridging ligands resulting from C-H activation/oxygenation of an RE NHC N-substituent. This generated the dimeric Ni(II) complexes Ni(6/7Mes)Br(µ-OH)(µ-O-6/7Mes)’NiBr (6Mes = 13; 7Mes = 14). Mass spectrometry demonstrated that the doubly activated complexes [NiBr(µ-O-6/7Mes)’]2 (15 and 16 respectively) were also formed in the reactions. UV-vis spectroscopy revealed the reactions took place rapidly, even at 190 K. Contrasting reactivity was observed when 2 or 7, bearing the less sterically encumbered N-oTol substituents 6oTol and 7oTol respectively, were exposed to O2, which led to the ligand redistribution products NiII(6/7oTol)(PPh3)Br2 (17 and 18 respectively). The less electron rich diamido analogue containing 6MesDAC (5), underwent dissociation and oxidation of the RE NHC and PPh3 ligands. Attempts to abstract the bromide from 1 generated novel two and three coordinate Ni(I) products. Reaction with additional 6Mes produced the two coordinate cation [Ni(6Mes)2]+ (19), which could be reduced with KC8 to Ni(6Mes)2 (20). SQUID analysis of 19 revealed it to be the first example of a nickel containing mononuclear single molecular magnet (SMM). Addition of [Et3Si]+ to 1 followed by work up in toluene led to the isolation of the Ni(I)-(η2-toluene) complex [Ni(6Mes)(η2-C6H5CH3)]+ (21). Mesitylene generated the analogous [Ni(6Mes)(η2-C6H3(CH3)3)]+ (23), but neither 1,4-xylene nor naphthalene gave isolable products. In all cases, cocrystallisation of [6MesH]+…arene was observed in variable amounts, which compromised reaction studies of the Ni-arene complexes. Removal of bromide from 1 with TlPF6 in THF generated the solvent coordinated cationic species [Ni(6Mes)(PPh3)(THF)]+ (24). Attempts to remove the ligated THF molecule were unsuccessful, however, it could be directly substituted by CO to form [Ni(6Mes)(PPh3)(CO)]+ (26). Similarly to 1, complex 24 activated O2, generating a dimer analogous to the singly activated complex 13 (Ni(6Mes)(PPh3)(µ-OH)(µ-O-6Mes)’NiBr (25)). Reactivity of 1 with NaBH4 produced [Ni(6Mes)(κ2-BH4)]2 (28), a Ni(I) dimer bridged by two BH4 ligands. The catalytic efficiency of neutral 1 in Kumada cross-coupling of aryl halides and PhMgCl or MesMgBr was probed. Of note was the high activity towards both aryl chlorides and aryl fluorides. Comparisons with cationic 24, larger 7- (7) and 8-membered ring (8 and 9) variants and the Ni(II) complexes Ni(6Mes/6oTol/7oTol)(PPh3)Br2 (29, 17 and 18 respectively) revealed that 1 exhibited the highest reactivity of all the precursors.
|
10 |
A General Approach to Cis-Fused Sesquiterpene Quinones and Synthesis, Characterization, and Catalytic Applications of Bis(Imino)-N-Heterocyclic Carbene Complexes of IronKaplan, Hilan January 2014 (has links)
Thesis advisor: James P. Morken / Sesquiterpene quinones are a prolific class of marine natural products that are particularly interesting due to their antibacterial, antiviral, and anti-inhibitory properties. Hundreds of these biologically active molecules are based on decalin frameworks, both cis- as well as trans-fused, however, significantly less synthetic work has focused on targeting the cis-fused series of compounds. In this chapter, progress towards an asymmetric, general route to various sesquiterpene quinones in the cleordane family of natural products will be described. The key steps of the synthesis include a highly convergent and diastereoselective reductive alkylation to forge both the requisite cis-ring fusion well as the all carbon quaternary center, as well as a scandium-catalyzed ring expansion of a 6,5-ring system to deliver the decalin core of the molecule. Additionally, the chapter includes the development and substrate scope of both methodologies utilized in the key complexity building reactions. Iron complexes ligated by bis(imino)pyridine ligands are remarkably active catalysts for a vast range of organic transformations including polymerization, hydrogenation, hydrosilylation, and hydroboration. Whereas much work has been done to probe the importance of the imine-substituents on catalysis, significantly less information is known about the nature of the central pyridine donor. To study the effects of a more donating ligand in which the pyridine is replaced with an N-heterocyclic carbene, a series of novel ligands and their corresponding iron complexes were synthesized and characterized. Whereas imidazole-derived complexes exhibited exclusively bidentate binding modes, 4,5,6-trihydropyrimidylidene-based ligands adopted a tridentate pincer conformation analogous to complexes of bis(imino)pyridines. Bonding in the five-coordinate bis(imino)-N-heterocyclic carbene complex displayed considerably contracted iron-ligand bond distances compared to the analogous bis(imino)pyridine iron complex. The study of physical and electronic structure and bonding in organometallic compounds is a critical for understanding and predicting complex behavior and reactivity. Having synthesized a completely new type of N-heterocyclic carbene (NHC) ligand and the corresponding iron complex, a rigorous study of metal-NHC bonding, magnetism, and redox activity in bis(imino)-NHC (or carbenodiimine, CDI) complexes of iron was carried out. A series of oxidation and reduction reactions on CDI complexes of iron were performed, enabling access to complexes spanning from formally iron(0) to iron (III) oxidation states. A battery of spectroscopic and computational methods, including X-ray crystallography, Mössbauer spectroscopy, SQUID magnetometry, and EPR spectroscopy established the CDI ligand as a redox active chelator. Additionally, a unique iron-carbene interaction was discovered, in which the metal center antiferromagnetically couples with the carbon of the NHC. Intent on developing CDI complexes of iron into practical catalysts for both synthetic organic transformations and polymerization, a series of stoichiometric as well as catalytic reactions were carried out to evaluate the reactivity profile of the novel complexes. Halide atom abstraction generated a new cationic species, which demonstrated different coordination chemistry compared to the bis(imino)pyridine analogue. Furthermore, the addition of a hydride or alkyl lithium reagent to the parent (CDI)FeCl2 species resulted in interesting and unexpected reactivity involving the carbene ligand. Preliminary catalytic hydrogenation experiments established (CDI)FeCl2 as a competent catalyst for the reduction of simple alkenes in the presence of Na(Hg) as a reductant under 80 psi of hydrogen. Additionally, the dichloride species could be readily converted into bis(aryloxide) complexes that were active for the polymerization of lactide to produce poly(lactic acid). The polymerization is very controlled (PDI values are <1.3), and polymers with molecular weights of around 35 kDa can be obtained after 3 hours at room temperature. / Thesis (PhD) — Boston College, 2014. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.
|
Page generated in 0.0712 seconds