Beyond Continuum Solvent Models in Computational Homogeneous Catalysis

Norjmaa, Gantulga; Ujaque, Gregori; Lledós, Agustı́

doi:10.1007/s11244-021-01520-2

Cited by 29 publications

(22 citation statements)

References 86 publications

(101 reference statements)

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“…In order to achieve a more accurate value of this barrier, the solvation energy of the different involved species should be considered by using an explicit solvent model. [48,49] In that case, the expected free-energy barrier associated with 21 TS should be higher than the calculated one and more in line with the employed experimental conditions. However, the high number of atoms to be modelled renders calculations very time-consuming and the correction was not introduced.…”

Section: C) Combined Activation Of Co 2 and N-butyl-2-phenylaziridinesupporting

confidence: 62%

Protonated Porphyrins: Bifunctional Catalysts for the Metal‐Free Synthesis of N‐Alkyl‐Oxazolidinones

Cavalleri

Damiano

Manca

et al. 2022

Chemistry A European J

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The protonation of commercially available porphyrin ligands yields a class of bifunctional catalysts able to promote the synthesis of N-alkyl oxazolidinones by CO 2 cycloaddition to corresponding aziridines. The catalytic system does not require the presence of any Lewis base or additive, and shows interesting features both in terms of cost effectiveness and eco-compatibility. The metal-free method-ology is active even with a low catalytic loading of 1 % mol, and the chemical stability of the protonated porphyrin allowed it to be recycled three times without any decrease in performance. In addition, a DFT study was performed in order to suggest how a simple protonated porphyrin can mediate CO 2 cycloaddition to aziridines to yield oxazolidinones.

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Section: C) Combined Activation Of Co 2 and N-butyl-2-phenylaziridinesupporting

confidence: 62%

Protonated Porphyrins: Bifunctional Catalysts for the Metal‐Free Synthesis of N‐Alkyl‐Oxazolidinones

Cavalleri

Damiano

Manca

et al. 2022

Chemistry A European J

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“…Hereafter, energies refer to Gibbs energies (∆ G , kcal mol −1 ) estimated at 298 K and 1 atm upon full geometry optimization. Solvation by methanol has been modeled by means of a micro-solvation approach [ 39 ] that combines an explicit description of the first solvation sphere and an implicit representation of the bulk solvation effects by a polarization continuum model [ 40 ]. The fully detailed computational approach is available in Section 4 , Materials and Methods.…”

Section: Resultsmentioning

confidence: 99%

“…Figure 5 depicts the most relevant Gibbs energy profile in the case of the di-solvated [Cu II (PhB(OH) 3 )(MeOH) 2 ] + ( 3 +,n = 2 ) heterobimetallic adduct. The influence of solvation on the stabilities of 3 +,n (n = 0, 1 or 2) and on the B-to-Cu transmetalation energy barriers is discussed in the SI ( Figure S15 ) [ 39 ].…”

Section: Resultsmentioning

confidence: 99%

Copper-Catalyzed Homocoupling of Boronic Acids: A Focus on B-to-Cu and Cu-to-Cu Transmetalations

et al. 2022

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Controlling and understanding the Cu-catalyzed homocoupling reaction is crucial to prompt the development of efficient Cu-catalyzed cross-coupling reactions. The presence of a coordinating base (hydroxide and methoxide) enables the B-to-Cu(II) transmetalation from aryl boronic acid to CuIICl2 in methanol, through the formation of mixed Cu-(μ-OH)-B intermediates. A second B-to-Cu transmetalation to form bis-aryl Cu(II) complexes is disfavored. Instead, organocopper(II) dimers undergo a coupled transmetalation-electron transfer (TET) allowing the formation of bis-organocopper(III) complexes readily promoting reductive elimination. Based on this mechanism some guidelines are suggested to control the undesired formation of homocoupling product in Cu-catalyzed cross-coupling reactions.

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“…[35][36][37][38] Hereafter, energies refer to Gibbs energies (∆G, kcal mol -1 ) estimated at 298 K and 1 atm upon full geometry optimization. Solvation by methanol has been modeled by means of a micro-solvation approach [39] that combines an explicit description of the first solvation sphere and an implicit representation of the bulk solvation effects by a polarization continuum model. [40] The fully detailed computational approach is available in section 4, Materials and Methods.…”

Section: Computational Mechanistic Investigation: B-to-cu(ii) Transme...mentioning

confidence: 99%

“…The influence of solvation on the stabilities of 3 +,n (n= 0, 1 or 2) and on the B-to-Cu transmetalation energy barriers is discussed in the SI (Figure S15). [39] Complex 3 +,n=2 features two bridging μ-OH groups between Cu(II) and B atoms and the 4-membered ring atoms are nearly co-planar (ΦCu-O-B-O = 1.5°, Figure 6.A.). The formation of such a mixed Cu-(μ-OH)-B dimer as a key pre-transmetalation species mirrors previous reports on Pd [41][42][43] or Ni complexes.…”

Section: Computational Mechanistic Investigation: B-to-cu(ii) Transme...mentioning

confidence: 99%

Copper-Catalyzed Homocoupling of Boronic Acids: A focus on B-to-Cu and Cu-to-Cu Transmetalations

Salamé¹,

Rio²,

Ciofini³

et al. 2022

Preprint

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Controlling and understanding Cu-catalyzed homocoupling reaction is crucial to prompt the development of efficient Cu-catalyzed cross-coupling reactions. The presence of a coordinating base (hydroxide, methoxide) enables the B-to-Cu(II) transmetalation from aryl boronic acid to CuIICl2 in methanol, through formation of a mixed Cu-(μ-OH)-B intermediates. A second B-to-Cu transmetalation to form bis-aryl Cu(II) complexes is disfavored. Instead, organocopper(II) dimers undergo a coupled transmetalation-electron-transfer (TET) allowing the formation of a bis-organocopper(III) complexes readily promoting reductive elimination. Based on this mechanism some guidelines are suggested to control the undesired formation of homocoupling product in Cu-catalyzed cross-coupling reactions.

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Beyond Continuum Solvent Models in Computational Homogeneous Catalysis

Cited by 29 publications

References 86 publications

Protonated Porphyrins: Bifunctional Catalysts for the Metal‐Free Synthesis of N‐Alkyl‐Oxazolidinones

Protonated Porphyrins: Bifunctional Catalysts for the Metal‐Free Synthesis of N‐Alkyl‐Oxazolidinones

Copper-Catalyzed Homocoupling of Boronic Acids: A Focus on B-to-Cu and Cu-to-Cu Transmetalations

Copper-Catalyzed Homocoupling of Boronic Acids: A focus on B-to-Cu and Cu-to-Cu Transmetalations

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