Gas-phase formation of Grignard-type organolanthanide (III) ions RLnCl3 - : The influences of lanthanide center and hydrocarbyl group

Abstract

Rationale: Compared with organomagnesium compounds (Grignard reagents), the Grignard-type organolanthanides (III) exhibit several utilizable differences in reactivity. However, the fundamental understanding of Grignard-type organolanthanides (III) is still in its infancy. Decarboxylation of metal carboxylate ions is an effective method to obtain organometallic ions that are well suited for gas-phase investigation using electrospray ionization (ESI) mass spectrometry in combination with density functional theory (DFT) calculations.

Methods: The (RCO₂ )LnCl₃ ^- (R = CH₃ , Ln = La-Lu except Pm; Ln = La, R = CH₃ CH₂ , CH₂ CH, HCC, C₆ H₅ , and C₆ H₁₁ ) precursor ions were produced in the gas phase via ESI of LnCl₃ and RCO₂ H or RCO₂ Na mixtures in methanol. Collision-induced dissociation (CID) was employed to examine whether the Grignard-type organolanthanide (III) ions RLnCl₃ ^- can be obtained via decarboxylation of lanthanide chloride carboxylate ions (RCO₂ )LnCl₃ ^- . DFT calculations can be used to determine the influences of lanthanide center and hydrocarbyl group on the formation of RLnCl₃ ^- .

Results: When R = CH₃ , CID of (CH₃ CO₂ )LnCl₃ ^- (Ln = La-Lu except Pm) yielded decarboxylation products (CH₃ )LnCl₃ ^- and reduction products LnCl₃ ·^- with a variation in the relative intensity ratio of (CH₃ )LnCl₃ ^- /LnCl₃ ·^- . The trend is as follows: (CH₃ )EuCl₃ ^- /EuCl₃ ·^- < (CH₃ )YbCl₃ ^- /YbCl₃ ·^- ≈ (CH₃ )SmCl₃ ^- /SmCl₃ ·^- < other (CH₃ )LnCl₃ ^- /LnCl₃ ·^- , which complies with the trend of Ln (III)/Ln (II) reduction potentials in general. When Ln = La and hydrocarbyl groups were varied as CH₃ CH₂ , CH₂ CH, HCC, C₆ H₅ , and C₆ H₁₁ , the fragmentation behaviors of these (RCO₂ )LaCl₃ ^- precursor ions were diverse. Except for (C₆ H₁₁ CO₂ )LaCl₃ ^- , the four remaining (RCO₂ )LaCl₃ ^- (R = CH₃ CH₂ , CH₂ CH, HCC, and C₆ H₅ ) ions all underwent decarboxylation to yield RLaCl₃ ^- . (CH₂ CH)LaCl₃ ^- and especially (CH₃ CH₂ )LaCl₃ ^- are prone to undergo β-hydride transfer to form LaHCl₃ ^- , whereas (HCC)LaCl₃ ^- and (C₆ H₅ )LaCl₃ ^- are not. A minor reduction product, LaCl₃ ·^- , was formed via C₆ H₅ radical loss of (C₆ H₅ )LaCl₃ ^- . The relative intensities of RLaCl₃ ^- compared to (RCO₂ )LaCl₃ ^- decrease as follows: HCC > CH₂ CH > C₆ H₅ > CH₃ > CH₃ CH₂ >> C₆ H₁₁ (not visible).

Conclusion: A series of Grignard-type organolanthanide (III) ions RLnCl₃ ^- (R = CH₃ , Ln = La-Lu except Pm; Ln = La, R = CH₃ CH₂ , CH₂ CH, HCC, and C₆ H₅ ) were produced from (RCO₂ )LnCl₃ ^- via CO₂ loss, whereas (C₆ H₁₁ )LaCl₃ ^- did not. The experimental and theoretical results suggest that the reduction potentials of Ln (III)/Ln (II) couples as well as the bulkiness and hybridization of hydrocarbyl groups play important roles in promoting or limiting the formation of RLnCl₃ ^- via decarboxylation of (RCO₂ )LnCl₃ ^- .