Synthesis and characterization of a CCC-NHC manganese complex and its catalytic activity in alpha-alkylation reactions of ketones using alcohols – acceptorless dehydrogenative coupling reaction

Nguyen, Thi Bao Tran

10 December 2021

N-heterocyclic carbenes are essential for the synthesis and stabilization of various metal complexes due to the tendency to act as sigma-donor of sp2 hybridized lone pair in carbene into sigma-accepting orbital of metals. Meanwhile, the electronic and steric properties of pincer complexes can be fine-tuned by modifying three sites bonded to the metals. Utilizing advantages of both NHCs and the pincer structures, NHCs-based pincer complexes have become increasingly developed in recent years. After the discovery of zirconium and rhodium complexes with CCC-NHC backbones reported in 2005, Hollis’s group has been interested in applying the CCC-NHC pincer precursor for other transition metals. Manganese, the third most abundant transition metal in the earth’s crust, has lower cost and less toxic features compared to most of the others. Herein, the CCC-NHCs manganese pincer complex is synthesized and characterized and its catalytic activity in alpha- alkylation reaction of ketones using alcohols was studied.

CCC-NHCs

Manganese

Organic Chemistry

Small molecule activation using electropositive metal N-heterocyclic carbene complexes

Turner, Zoe Rose

January 2011

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.

Silver N-Heterocyclic Carbenes

Garrison, Jered C.

26 September 2005

No description available.

Ag

NHCs

¿¿¿¿¿

PF6

CARBENES

silver NHC

SILVER

Unravelling the photochemistry of organometallic N-heterocyclic carbene complexes

Martin, Thomas Antony

January 2011

This thesis describes the synthesis, characterisation and reactivity of new manganese and rhenium(I) NHC complexes, which have been investigated both thermally and photochemically and the results contrasted with existing phosphine analogues in the literature. Cp’Mn(CO)2(NHC) (NHC = IEt2Me2 1, IMes 2, IiPr2Me2 3 and IPr 4) were synthesised and investigated by TRIR spectroscopy. Loss of CO was observed after 355 nm irradiation to form agostically stabilised intermediates, which reformed the parent species by recombination with CO on the nanosecond timescale. Loss of NHC was not observed, in contrast to Cp’Mn(CO)2(PPh3) which lost both CO and PPh3 upon photolysis. [Re(NHC)(Bpy)(CO)3]BAr4F (NHC = IEt2Me2 5, IMes 6) were synthesised and investigated by TRIR spectroscopy and UV/Vis absorption and emission spectrometry. Inclusion of an NHC altered the excited state manifold of the complexes, favouring population of the 3MLCT over the 3IL excited state. The lowest energy excited state for both 5 and 6 proved to be a 3MLCT excited state at 298 and 77 K. In contrast, [Re(PPh3)(Bpy)(CO)3]BAr4F exhibited 3MLCT at 298 K, but 3IL at 77 K. A series of complexes, M(NHC)(CO)4X and M(NHC)2(CO)3X (M = Re, X = Cl; M = Mn, X = Br) formed upon reaction of the corresponding M(CO)5X species and free NHC. The substitution pattern was dictated by the steric bulk of the NHC. Generation of the corresponding cations by halide abstraction was investigated. M(NHC)2(CO)3X was found to form agostic stabilised species upon halide abstraction by NaBAr4F in CH2Cl2. Under the same conditions, Re(IPr)(CO)4Cl was found to form the dichloromethane complex, [Re(IPr)(CO)4(η1-CH2Cl2)]BAr4F. In C6H5F solution under an atmosphere of dihydrogen, the CH2Cl2 ligand could be displaced by H2 to form the dihydrogen species, [Re(IPr)(CO)4(H2)]BAr4F.

547.05

The Medicinal Applications and Stability Evaluation of Silver (I) Carbene Complexes

Hindi, Khadijah M.

26 August 2008

No description available.

Chemistry

NMR

nanospheres

¿¿¿¿¿

broth/D2O

SILVER

NHCs

COMPLEXES

Cationic 5-phosphonio-substituted N-heterocyclic carbenes

Schwedtmann, Kai, Schoemaker, Robin, Hennersdorf, Felix, Bauzá, Antonio, Frontera, Antonio, Weiss, Robert, Weigand, Jan J.

05 April 2017

2-Phosphanyl-substituted imidazolium salts 2-PR2(4,5-Cl-Im)[OTf] (9a,b[OTf]) (4,5-Cl-Im = 4,5-dichloro-1,3-bis(2,6-di-isopropylphenyl)-imidazolium) (a: R = Cy, b: R = Ph) are prepared from the reaction of R2PCl (R = Cy, Ph) with NHC 8 (4,5-dichloro-1,3-bis(2,6-di-isopropylphenyl)-imidazolin-2-ylidene) in the presence of Me3SiOTf. 5-Phospanyl-substituted imidazolium salts 5-PR2(2,4-Cl-Im)[OTf] (10a,b[OTf]) are obtained in quantitative yield when a slight excess of the NHC 8 is used. 5-Phosphonio-substituted imidazolium salts 5-PR2Me(2,4-Cl-Im)[OTf]2 (14a,b[OTf]2) and 5-PR2F(2,4-Cl-Im)[OTf]2 (16a,b[OTf]2) result from methylation reaction or oxidation of 10a,b[OTf] with XeF2 and subsequent fluoride abstraction. According to our quantum chemical studies the Cl1 atom at the 2-position at the imidazolium ring of dication 14b2+ carries a slightly positive charge and is therefore accessible for nucleophilic attack. Accordingly, the reaction of 14a,b[OTf]2 and 16a,b[OTf]2 with R3P (R = Cy, Ph) affords cationic 5-phosphonio-substituted NHCs 5-PR2Me(4-Cl-NHC)[OTf] (17a,b[OTf]) and 5-PR2F(4-Cl-NHC)[OTf] (18a,b[OTf]) via a SN2(Cl)-type reaction. A series of transition metal complexes such as [AuCl(5-PPh2Me(4-Cl-NHC))][OTf] (19[OTf]), [CuBr(5-PPh2Me(4-Cl-NHC))][OTf] (20[OTf]), [AuCl(5-PPh2F(4-Cl-NHC))[OTf] (21[OTf]) and [RhCl(cod)(5-PPh2Me(4-Cl-NHC))][OTf] (23[OTf]) are prepared to prove the coordination abilities of carbenes 17b[OTf] and 18b[OTf]. The isolation of a rare example of a tricationic bis-carbene silver complex [Ag(5-PPh2Me(4-Cl-NHC))2][OTf]3 (22[OTf]3) is achieved by reacting 14b[OTf] with Cy3P in the presence of AgOTf. NHC 17b[OTf] represents a very effective dehydrocoupling reagent for secondary (R2PH, R = Ph, Cy, iBu) and primary (RPH2, R = Ph, Cy) phosphanes to give diphosphanes of type R4P2 (R = Ph, Cy, iBu) and oligophosphanes R4P4, R5P5 (R = Ph, Cy), respectively. Methylation of 17b+ and subsequent deprotonation reaction with LDA affords the cationic NHO (N-heterocyclic olefin) 35+ of which the gold complex 36+ is readily accessible via the reaction with AuCl(tht).

N-heterocyclischen Carbenen (NHCs)

elektrophile PIII-Verbindung

anorganische Chemie

N-heterocyclic carbenes (NHCs)

electrophilic PIII compounds

inorganic chemistry

Cationic 5-phosphonio-substituted N-heterocyclic carbenes

Schwedtmann, Kai, Schoemaker, Robin, Hennersdorf, Felix, Bauzá, Antonio, Frontera, Antonio, Weiss, Robert, Weigand, Jan J.

05 April 2017

2-Phosphanyl-substituted imidazolium salts 2-PR2(4,5-Cl-Im)[OTf] (9a,b[OTf]) (4,5-Cl-Im = 4,5-dichloro-1,3-bis(2,6-di-isopropylphenyl)-imidazolium) (a: R = Cy, b: R = Ph) are prepared from the reaction of R2PCl (R = Cy, Ph) with NHC 8 (4,5-dichloro-1,3-bis(2,6-di-isopropylphenyl)-imidazolin-2-ylidene) in the presence of Me3SiOTf. 5-Phospanyl-substituted imidazolium salts 5-PR2(2,4-Cl-Im)[OTf] (10a,b[OTf]) are obtained in quantitative yield when a slight excess of the NHC 8 is used. 5-Phosphonio-substituted imidazolium salts 5-PR2Me(2,4-Cl-Im)[OTf]2 (14a,b[OTf]2) and 5-PR2F(2,4-Cl-Im)[OTf]2 (16a,b[OTf]2) result from methylation reaction or oxidation of 10a,b[OTf] with XeF2 and subsequent fluoride abstraction. According to our quantum chemical studies the Cl1 atom at the 2-position at the imidazolium ring of dication 14b2+ carries a slightly positive charge and is therefore accessible for nucleophilic attack. Accordingly, the reaction of 14a,b[OTf]2 and 16a,b[OTf]2 with R3P (R = Cy, Ph) affords cationic 5-phosphonio-substituted NHCs 5-PR2Me(4-Cl-NHC)[OTf] (17a,b[OTf]) and 5-PR2F(4-Cl-NHC)[OTf] (18a,b[OTf]) via a SN2(Cl)-type reaction. A series of transition metal complexes such as [AuCl(5-PPh2Me(4-Cl-NHC))][OTf] (19[OTf]), [CuBr(5-PPh2Me(4-Cl-NHC))][OTf] (20[OTf]), [AuCl(5-PPh2F(4-Cl-NHC))[OTf] (21[OTf]) and [RhCl(cod)(5-PPh2Me(4-Cl-NHC))][OTf] (23[OTf]) are prepared to prove the coordination abilities of carbenes 17b[OTf] and 18b[OTf]. The isolation of a rare example of a tricationic bis-carbene silver complex [Ag(5-PPh2Me(4-Cl-NHC))2][OTf]3 (22[OTf]3) is achieved by reacting 14b[OTf] with Cy3P in the presence of AgOTf. NHC 17b[OTf] represents a very effective dehydrocoupling reagent for secondary (R2PH, R = Ph, Cy, iBu) and primary (RPH2, R = Ph, Cy) phosphanes to give diphosphanes of type R4P2 (R = Ph, Cy, iBu) and oligophosphanes R4P4, R5P5 (R = Ph, Cy), respectively. Methylation of 17b+ and subsequent deprotonation reaction with LDA affords the cationic NHO (N-heterocyclic olefin) 35+ of which the gold complex 36+ is readily accessible via the reaction with AuCl(tht).

Exploiting anionically-tethered N-heterocyclic carbene complexes for small molecule activation

McMullon, Max William

January 2018

N-heterocyclic carbenes (NHCs) can be used as ligands for organometallics complexes, which can then facilitate numerous catalytic applications, such as, C-H activation, small molecule activation and numerous materials applications. The use of anionically-tethered NHCs for usage with electropositive metals has been pioneered by the Arnold group within the last decade. This thesis describes the synthesis of both aryloxide- and amide-tethered NHC organometallic complexes of s-, p-, d- and f-block metals to provide a platform for small molecule activation. Once synthesised, the reactivity of some of these complexes were tested by reaction with CO2 with the aim of turning a molecule considered a harmful (environmentally), waste product into value added products, potentially providing an alternative fuel source. Chapter One introduces the use of anionically-tethered NHCs for use in a number of organometallic complexes as well as their current potential as catalysts for a number of important small molecules. This chapter focuses upon the differences between complexes tethered with anionic O, N, P, S elements, f-element NHC complexes and the use of d-block NHC complexes for catalysis. Chapter Two contains the synthesis and characterisation of a number of aryloxy-tethered NHC p-, d- and f-block organometallic complexes using the ligand H2(LArO R)2. The synthesis of SnII complexes including the synthesis of new ‘normal’ ‘abnormal’ complexes given enough steric bulk around the Sn centre due to the lone pair present in Sn complexes, preventing one of the ligands binding through the classical carbene position and therefore binding through the backbone C4 carbon. The synthesis of MII (Zn, Co and Fe) complexes to compare the solid-state structure and binding mode of the carbenes. The synthesis and characterisation of MIII (Ce and Eu) complexes to assess the solid-state structure and binding modes within f-bock complexes. Chapter Three investigates the reactivity of the MII complexes (Sn, Zn, and Fe) with CO2. Successful reactions were characterised using NMR and further treated with alkynes to target catalytic reactions. Chapter Four contains reactions to target a number of amide-tethered bis (NHC) s-, p-, d- and f-block organometallic complexes using the proligand, H4(LN Mes)Cl3. Deprotonation studies undertaken with a number of bases to give the MI (Li and K) salts and MII (Mg) salts and proved to be unsuccessful upon isolation. Reactions to synthesise the p-, d- and f-block complexes were then undertaken using in situ free carbene production as well as the attempted isolation of the free carbene, both of which also proved unsuccessful. Chapter Five provides an overall conclusion to the work presented in Chapters Two, Three and Four within this thesis. Chapter Six gives the experimental and characterising data for the complexes and reactions.

Silver(I) and Gold(I) N-Heterocyclic Carbene Complexes

Durmus, Semih

January 2006

No description available.

Chemistry, Inorganic

NHCs

CARBENES

SILVER(I) NHC

GOLD(I) NHC

ANTIMICROBIALS

ANTICANCER

HISTAMINE

HISTIDINE

UROCANIC ACID

Synthèse, fonctionnalisation et applications de métallo-NHC du groupe 11 / Synthesis, functionalisation and applications of coinage metals N-Heterocyclic carbenes

Gibard, Clémentine

05 December 2014

Les carbènes N-hétérocycliques (NHC) sont utilisés comme ligands pour les métaux de transition. Les complexes résultants présentent principalement des applications en catalyse, ainsi que dans la conception de nouveaux candidats médicaments. Dans ce travail, nous discuterons une simplification des méthodes de synthèse des sels d’imidazoliniums, ainsi que des complexes Cu- et Ag-NHC. L’ammoniaque est utilisé ici à la fois comme milieu solubilisant des espèces métalliques et comme base pour la déprotonation des sels d’imidazoli(ni)ums fournissant une métallation douce, rapide et simple. La fonctionnalisation des NHC, dans des positions définies, permet une modulation de certaines de leurs caractéristiques sans impacter les propriétés remarquables de leurs complexes. De nouvelles méthodes de fonctionnalisation, par cycloaddition azoture-alcyne en périphérie des noyaux aromatiques, ont été mises au point. Ceci mène à l’introduction de trois stratégies synthétique : pré-, post- et auto-fonctionnalisation. La stratégie de pré-fonctionnalisation de précurseurs permet l’accès à des métallo-NHC du groupe 11, dont les propriétés de solubilité peuvent être facilement modifiées. Des réactions thermiques d’Huisgen et de SPAAC sont réalisables directement sur les complexes Au-NHC modifiés par des azotures, et sont désignés comme post-fonctionnalisation. Des réactions dites d’auto-fonctionnalisations entre un complexe Cu-NHC possédant un azoture et des alcynes divers, permettent l’introduction, par exemple, de biomolécules sensibles sans étapes de protection/déprotection. Enfin, les complexes Cu-NHC fonctionnalisés avec des groupements hydrosolubilisants ont été étudiés en tant que catalyseurs de cycloaddition de CuAAC dans des milieux biocompatibles, tandis que les Ag-NHC fonctionnalisés avec des groupements lipophiles présentent une activité antibactérienne. / N-heterocyclic carbenes (NHCs) have been used very frequently as ligands for the preparation of transition metal-based catalysts as well as drug candidates. This work will present a simplification of imidazoliniums synthesis and a new preparation of Ag-, Cu-NHC complexes. Aqueous ammonia will be used for the solubilisation of metallic species and as a base for the deprotonation of imidazoli(ni)um salts providing a mild, quick and easy metallation procedure. The functionalisation of NHC ligands, in definite positions, allows the modulation of some of their characteristics without interfering with the remarkable properties of their complexes. New functionalisation strategies by azide-alkyne cycloaddition reaction at the periphery of aromatics cores, were developped. This can be described by the following three synthetics strategies: pre-, post- and auto-functionalisation. Pre-functionnalisations strategy of precursors allows the synthesis of coinage metal-NHC complexes, for which variation of solubility is easily obtained. Thermal Huisgen reactions and SPAAC are achievable on the Au-NHC azide modified complexes directly, in a post-functionalisation pathway. Furthermore, the post-functionnalisation strategy was extended to Cu-NHC complexes resulting in an auto-functionalisation process. This allowed subsequently the introduction of sensitive biomolecules without protection/deprotection steps. Finally, water soluble Cu-NHCs complexes were used as CuAAC catalyst in bio-compatible media. Lipophilic Ag-NHCs complexes were tested as antibacterials (antibiofilm and growth inhibition activities).

Carbènes N-Hétérocycliques (NHC)

Chimie click

Métaux du groupe 11

Fonctionnalisation

Catalyse

Antibactériens

N-Heterocylic carbenes (NHCs)

Catalysis

Antibacterials

Click chemistry

Coinage metals

Functionalisation