Electronic and Ligand Properties of Skeletally Substituted Cyclic (Alkyl)(Amino)Carbenes (CAACs) and Their Reactivity towards Small Molecule Activation: A Theoretical Study

Bharadwaz, Priyam; Chetia, Pubali; Phukan, Ashwini K.

doi:10.1002/chem.201701645

Cited by 17 publications

(8 citation statements)

References 102 publications

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“…Studies have also included comparison of carbenes with silylenes, germylenes, and abnormal carbenes, 179,183 analysis of ring size and heterocycles on carbene properties, 180 the introduction of boron substituents to (NHC and PHC) backbones, 157 the effect of additional rings and carbonyl substituents on normal and abnormal NHCs, 158 analysis of remote carbenes, 182,184 consideration of adduct formation for normal and abnormal NHCs, 181 and small molecule activation by cyclic (alkyl)(amino) carbenes (CAACs). 185 Overlap with our core set of carbenes (Table 1c) is quite poor as these studies have been focused on novel/unusual structures, so data have not been compiled in this case. These studies also reported a number of additional descriptor and energy calculations, allowing orbital analysis, predicting redox potentials, metal and fragment binding energies, nucleophilicity, electrophilicity, proton affinity, assessing aromaticity through nucleus independent chemical shifts (NICS 186 ) etc., as well as a range of calculated NMR data to assess different ligand structures.…”

Section: Ligand Knowledge Base (Lkb-c)mentioning

confidence: 99%

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Computational Ligand Descriptors for Catalyst Design

2019

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Ligands, especially phosphines and carbenes, can play a key role in modifying and controlling homogeneous organometallic catalysts, and they often provide a convenient approach to fine-tuning the performance of known catalysts. The measurable outcomes of such catalyst modifications (yields, rates, selectivity) can be set into context by establishing their relationship to steric and electronic descriptors of ligand properties, and such models can guide the discovery, optimisation and design of catalysts.In this review we present a survey of calculated ligand descriptors, with a particular focus on homogeneous organometallic catalysis. A range of different approaches to calculating steric and electronic parameters are set out and compared, and we have collected descriptors for a range of representative ligand sets, including 30 monodentate phosphorus(III) donor ligands, 23 bidentate P,Pdonor ligands and 30 carbenes, with a view to providing a useful resource for analysis to practitioners. In addition, several case studies of applications of such descriptors, covering both maps and models, have been reviewed, illustrating how descriptor-led studies of catalysis can inform experiments and highlighting good practice for model comparison and evaluation.

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Section: Ligand Knowledge Base (Lkb-c)mentioning

confidence: 99%

“…Phukan and collaborators − ,− have again used a range of descriptors to assess carbenes. While the exact selection varied with application and no single coherent database has been presented, capturing carbene properties across a wide range of structural modifications.…”

Section: Ligand Descriptorsmentioning

confidence: 99%

Computational Ligand Descriptors for Catalyst Design

2019

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“…Besides the typical NHCs, stable cyclic alkyl-amino carbenes (cAACs) with stronger nucleophilic (σ-donors) and electrophilic (π-acceptors) character were first isolated and characterized by Bertrand and co-workers in 2005 . This unique electronic feature of cAAC has resulted in on ongoing “renaissance” in the stabilization of various unstable chemical species, radicals, and elements in their different unusual oxidation states. − In recent years, the wider application of carbenes has emboldened many research groups worldwide in the exploration of new classes of carbenes with interesting electronic properties and novel catalytic activities. − Few research studies have focused on both computational design and experimental isolation of novel carbenes, with the aim of achieving superior σ-donation and π-backdonation abilities compared to the reported analogues. − On the other hand, the stabilization of main-group elements and transition metals in their unusual oxidation states employing these carbenes has become the primary focus in many research laboratories. − In 2008, Robinson and co-workers isolated the silicon(0) compound featuring a SiSi double bond, revealing that NHCs could stabilize main group elements in their zero oxidation state . In subsequent years, the analogous Ge(0) and Sn(0) complexes were synthesized and isolated by Jones and co-workers utilizing NHC Ar (Ar = 2,6-diisopropylphenyl or 2,4,6-trimethylphenyl).…”

Section: Introductionmentioning

confidence: 99%

Donor Stabilized Diatomic Gr.14 E₂(E = C–Pb) Molecule D–E₂–D (D = NHC,aNHC,^NNHC, NHSi, NHGe, cAAC, cAASi, cAAGe): A Theoretical Insight

Mondal

Dutta

et al. 2018

J. Phys. Chem. A

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Quantum chemical calculations have been carried out to explore the detailed electronic structure and bonding scenario in various bis-donor stabilized E2 compounds (E = C–Pb). Our computational findings reveal that the thermodynamic stabilities of the E2 core gradually decrease as we move down the group. A linear D–E–E′–D framework is observed for C2 systems, while the heavier group 14 analogues possess trans-bent geometries. Consideration of few compounds as viable targets for synthesis is suggested by their corresponding calculated formation energies. In addition, the thermodynamic stabilities of C2 systems notably increase with the saturation of the donor ring framework and are even more pronounced for boron-substituted saturated NHD ligand. QTAIM calculations affirmed that the covalent nature of E–E′ bonds shifts toward the donor–acceptor region as one traverses from top to bottom along group 14. The E–D and E′–D bonds in the C2 systems have covalent nature, whereas those in Si2–Pb2 systems are characterized by donor–acceptor bonds. In addition, we have computed proton affinities and vertical ionization potentials (VIPs) of these compounds. An excellent correlation was obtained between calculated VIPs and orbital energies of HOMOs. Furthermore, in the present study, we also explored the effect of bis-donors in the stabilization of heterodiatomic SiC compounds. Our calculations indicate that a typical bonding description of the SiC(D)2 compounds should be represented by a combination of a classical double bond between C–D with significant donor–acceptor interaction in Si–D, i.e., D → SiCD. The SiC(D)2 systems are found to be less stable than the corresponding dicarbon compounds C2(D)2, but they show significant stabilization compared to the corresponding disilicon systems Si2(D)2.

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“…Here, one of the nitrogen substituents of an NHC was replaced by an ylide group. Due to the lower electronegativity of carbon compared to nitrogen, such an ylide-substitution should result in increased HOMO and LUMO levels, thus making CAYCs particularly strong donors with interesting electronic properties [20][21][22][23][24]. Eigenvalues of the frontier orbitals were taken from Reference [21].…”

Section: Introductionmentioning

confidence: 99%

Towards the Preparation of Stable Cyclic Amino(ylide)Carbenes

et al. 2020

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Cyclic amino(ylide)carbenes (CAYCs) are the ylide-substituted analogues of N-heterocyclic Carbenes (NHCs). Due to the stronger π donation of the ylide compared to an amino moiety they are stronger donors and thus are desirable ligands for catalysis. However, no stable CAYC has been reported until today. Here, we describe experimental and computational studies on the synthesis and stability of CAYCs based on pyrroles with trialkyl onium groups. Attempts to isolate two CAYCs with trialkyl phosphonium and sulfonium ylides resulted in the deprotonation of the alkyl groups instead of the formation of the desired CAYCs. In case of the PCy3-substituted system, the corresponding ylide was isolated, while deprotonation of the SMe2-functionalized compound led to the formation of ethene and the thioether. Detailed computational studies on various trialkyl onium groups showed that both the α- and β-deprotonated compounds were energetically favored over the free carbene. The most stable candidates were revealed to be α-hydrogen-free adamantyl-substituted onium groups, for which β-deprotonation is less favorable at the bridgehead position. Overall, the calculations showed that the isolation of CAYCs should be possible, but careful design is required to exclude decomposition pathways such as deprotonations at the onium group.

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Electronic and Ligand Properties of Skeletally Substituted Cyclic (Alkyl)(Amino)Carbenes (CAACs) and Their Reactivity towards Small Molecule Activation: A Theoretical Study

Cited by 17 publications

References 102 publications

Computational Ligand Descriptors for Catalyst Design

Computational Ligand Descriptors for Catalyst Design

Donor Stabilized Diatomic Gr.14 E₂(E = C–Pb) Molecule D–E₂–D (D = NHC,aNHC,^NNHC, NHSi, NHGe, cAAC, cAASi, cAAGe): A Theoretical Insight

Towards the Preparation of Stable Cyclic Amino(ylide)Carbenes

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Electronic and Ligand Properties of Skeletally Substituted Cyclic (Alkyl)(Amino)Carbenes (CAACs) and Their Reactivity towards Small Molecule Activation: A Theoretical Study

Cited by 17 publications

References 102 publications

Computational Ligand Descriptors for Catalyst Design

Computational Ligand Descriptors for Catalyst Design

Donor Stabilized Diatomic Gr.14 E2(E = C–Pb) Molecule D–E2–D (D = NHC,aNHC,NNHC, NHSi, NHGe, cAAC, cAASi, cAAGe): A Theoretical Insight

Towards the Preparation of Stable Cyclic Amino(ylide)Carbenes

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Donor Stabilized Diatomic Gr.14 E₂(E = C–Pb) Molecule D–E₂–D (D = NHC,aNHC,^NNHC, NHSi, NHGe, cAAC, cAASi, cAAGe): A Theoretical Insight