Assessing the performances of some recently proposed density functionals for the description of organometallic structures

Brémond, Éric; Kalhor, Mahboubeh Poor; Bousquet, Diane; Mignon, Pierre; Ciofini, Ilaria; Adamo, Carlo; Cortona, Pietro; Chermette, Henry

doi:10.1007/s00214-013-1401-5

Cited by 12 publications

(7 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Considering the complexity of the system and the expected accuracy of the calculations, this value compares well to the computational value of 20.6 kcal mol –1 for a mechanism that involves the heterotrimer NdMg 2 a as a dormant species and (C 5 Me 5 ) 2 LnR as the active complex. In addition, the difference of 3 kcal mol –1 between measured and calculated activation energies corresponds to the best match among the set of functionals tested and fits with the expected precision of this methodology. − In addition, the mechanism is in line with a previously postulated mechanism. , In this mechanism, the active species is ca. 10 kcal mol –1 less stable than the dormant heterobimetallic trimer species.…”

Section: Discussionsupporting

confidence: 70%

Deciphering the Mechanism of Coordinative Chain Transfer Polymerization of Ethylene Using Neodymocene Catalysts and Dialkylmagnesium

et al. 2016

View full text Add to dashboard Cite

Ethylene polymerizations were performed in toluene using the neodymocene complex (C5Me5)2NdCl2Li(OEt2)2 or {(Me2Si(C13H8)2)Nd(μ-BH4)[(μ-BH4)Li(THF)]}2 in combination with n-butyl-n-octylmagnesium used as both alkylating and chain transfer agent. The kinetics were followed for various [Mg]/[Nd] ratios, at different polymerization temperatures, with or without ether as a cosolvent. These systems allowed us to (i) efficiently obtain narrowly distributed and targeted molar masses, (ii) characterize three phases during the course of polymerization, (iii) estimate the propagation activation energy (17 kcal mol–1), (iv) identify the parameters that control chain transfer, and (v) demonstrate enhanced polymerization rates and molar mass distribution control in the presence of ether as cosolvent. This experimental set of data is supported by a computational investigation at the DFT level that rationalizes the chain transfer mechanism and the specific microsolvation effects in the presence of cosolvents at the molecular scale. This joint experimental/computational investigation offers the basis for further catalyst developments in the field of coordinative chain transfer polymerization (CCTP).

show abstract

Section: Discussionsupporting

confidence: 70%

Deciphering the Mechanism of Coordinative Chain Transfer Polymerization of Ethylene Using Neodymocene Catalysts and Dialkylmagnesium

et al. 2016

View full text Add to dashboard Cite

show abstract

“…Experimental determination of the relative spin-state energies is not always available, especially for large complexes, and for such cases, insights from theoretical calculations can be very helpful. Theoretical calculations using Kohn–Sham density functional theory (KS-DFT) are widely used due to the ability of KS-DFT to model large metal-containing systems at a reasonable computational cost and with reasonable accuracy. − KS-DFT has been widely validated for transition-metal thermochemistry, − especially for properties involving the lowest-energy spin state.…”

Section: Introductionmentioning

confidence: 99%

Hyper Open-Shell Excited Spin States of Transition-Metal Compounds: FeF₂, FeF₂···Ethane, and FeF₂···Ethylene

2018

View full text Add to dashboard Cite

Spin-state energetics are important for understanding properties that involve more than one spin state, for example, catalysis occurring on two or more potential energy surfaces corresponding to different electronic spins. Very often, multiple-spin processes involve transition-metal compounds, and therefore, it is important to understand the electronic structure and energetics of such compounds in different spin states. In this work, we benchmark relative spin-state energies of FeF with respect to the quintet ground spin state using both single-configurational and multiconfigurational methods, and we examine how they are affected by the binding of ethane and ethylene to the iron center. We also benchmark the binding energies of the complexes. The single-configurational methods used in this work are the Hartree-Fock method, 32 exchange-correlation functionals, and the CCSD(T) coupled-cluster method in both restricted and unrestricted formalisms. The multiconfigurational methods that have been used are CASSCF, CASPT2, CASPT3, MRCI, MRCI+Q, and MR-ACPF. The spin-state splitting energies depend on the functional chosen, and of the 32 exchange-correlation functionals investigated here, we find that for the septet and spin-projected triplet states of FeF the M06 functional is the best when compared to our best estimates from multireference calculations. If all nine excitation energies are considered, where there are three excited spin states (singlet, triplet, and septet) for each of the three systems (FeF, FeF···ethane, and FeF···ethylene), the three best-performing functionals are HLE16, SOGGA11-X, and M06-2X. We find that the binding of ethane perturbs the relative spin-state energy of FeF by only a small amount, but the stronger binding of ethylene has a larger effect. For the spin-state splitting energies of FeF using single-reference CCSD(T), we find that the predicted results depend very strongly on precisely how the calculations are done, in particular, on the spin-restricted or spin-unrestricted character of the SCF reference state, which can differ even by around 50 kcal/mol for the SCF reference state and the subsequent CCSD(T) calculations. Upon analyzing the wave functions of both the spin-restricted or spin-unrestricted formalisms, we find that the lowest-energy singlet and triplet states of the complexes, just like FeF in isolation, can have more unpaired electrons than they are usually assumed to have, i.e., they can be hyper open-shell electronic configurations, and this can significantly lower the energy.

show abstract

“…The calculated values are in excellent agreement with experiment, with our modeling strategy affording relative kinetics parameters within 1 kcal mol –1 of experimental values. This precision is comparable to that attained in state-of-the-art molecular modeling of transition metal reactivity. ,− …”

Section: Resultsmentioning

confidence: 59%

Ethylene–Butadiene Copolymerization by Neodymocene Complexes: A Ligand Structure/Activity/Polymer Microstructure Relationship Based on DFT Calculations

et al. 2016

View full text Add to dashboard Cite

Ethylene/butadiene copolymerization can be performed by neodymocene catalysts in the presence of an alkylating/chain transfer agent. A variety of polymerization activities and copolymer microstructures can be obtained depending on the neodymocene ligands. For a set of four catalysts, namely (C5Me5)2NdR, [Me2Si(3-Me3SiC5H3)2]NdR, [Me2Si(C5H4)(C13H8)]NdR and [Me2Si(C13H8)2]NdR, we report a DFT mechanistic study of this copolymerization reaction performed in the presence of dialkylmagnesium. Based on the modeling strategy developed for the ethylene homopolymerization catalyzed by (C5Me5)2NdR in the presence of MgR2, our model is able to account for the following: (i) the formation of Nd/Mg heterobimetallic complexes as intermediates, (ii) the overall differential activity of the catalysts, (iii) the copolymerization reactivity indexes, and (iv) the specific microstructure of the resulting copolymers, including branching and cyclization. The analysis of the reaction mechanisms and the energy profiles thus relates ligand structure, catalyst activity, and polymer microstructure and sets the basis for further catalyst developments.

show abstract

Assessing the performances of some recently proposed density functionals for the description of organometallic structures

Cited by 12 publications

References 41 publications

Deciphering the Mechanism of Coordinative Chain Transfer Polymerization of Ethylene Using Neodymocene Catalysts and Dialkylmagnesium

Deciphering the Mechanism of Coordinative Chain Transfer Polymerization of Ethylene Using Neodymocene Catalysts and Dialkylmagnesium

Hyper Open-Shell Excited Spin States of Transition-Metal Compounds: FeF₂, FeF₂···Ethane, and FeF₂···Ethylene

Ethylene–Butadiene Copolymerization by Neodymocene Complexes: A Ligand Structure/Activity/Polymer Microstructure Relationship Based on DFT Calculations

Contact Info

Product

Resources

About

Assessing the performances of some recently proposed density functionals for the description of organometallic structures

Cited by 12 publications

References 41 publications

Deciphering the Mechanism of Coordinative Chain Transfer Polymerization of Ethylene Using Neodymocene Catalysts and Dialkylmagnesium

Deciphering the Mechanism of Coordinative Chain Transfer Polymerization of Ethylene Using Neodymocene Catalysts and Dialkylmagnesium

Hyper Open-Shell Excited Spin States of Transition-Metal Compounds: FeF2, FeF2···Ethane, and FeF2···Ethylene

Ethylene–Butadiene Copolymerization by Neodymocene Complexes: A Ligand Structure/Activity/Polymer Microstructure Relationship Based on DFT Calculations

Contact Info

Product

Resources

About

Hyper Open-Shell Excited Spin States of Transition-Metal Compounds: FeF₂, FeF₂···Ethane, and FeF₂···Ethylene