Stephen A. Decker scite author profile

Deoxygenations of (silox)(3)WNO (12) and R(3)PO (R = Me, Ph, (t)Bu) by M(silox)(3) (1-M; M = V, NbL (L = PMe(3), 4-picoline), Ta; silox = (t)Bu(3)SiO) reflect the consequences of electronic effects enforced by a limiting steric environment. 1-Ta rapidly deoxygenated R(3)PO (23 degrees C; R = Me (DeltaG degrees (rxn)(calcd) = -47 kcal/mol), Ph) but not (t)Bu(3)PO (85 degrees, >2 days), and cyclometalation competed with deoxygenation of 12 to (silox)(3)WN (11) and (silox)(3)TaO (3-Ta; DeltaG degrees (rxn)(calcd) = -100 kcal/mol). 1-V deoxygenated 12 slowly and formed stable adducts (silox)(3)V-OPR(3) (3-OPR(3)) with OPR(3). 1-Nb(4-picoline) (S = 0) and 1-NbPMe(3) (S = 1) deoxygenated R(3)PO (23 degrees C; R = Me (DeltaG degrees (rxn)(calcd from 1-Nb) = -47 kcal/mol), Ph) rapidly and 12 slowly (DeltaG degrees (rxn)(calcd) = -100 kcal/mol), and failed to deoxygenate (t)Bu(3)PO. Access to a triplet state is critical for substrate (EO) binding, and the S --> T barrier of approximately 17 kcal/mol (calcd) hinders deoxygenations by 1-Ta, while 1-V (S = 1) and 1-Nb (S --> T barrier approximately 2 kcal/mol) are competent. Once binding occurs, significant mixing with an (1)A(1) excited state derived from population of a sigma-orbital is needed to ensure a low-energy intersystem crossing of the (3)A(2) (reactant) and (1)A(1) (product) states. Correlation of a reactant sigma-orbital with a product sigma-orbital is required, and the greater the degree of bending in the (silox)(3)M-O-E angle, the more mixing energetically lowers the intersystem crossing point. The inability of substrates EO = 12 and (t)Bu(3)PO to attain a bent 90 degree angle M-O-E due to sterics explains their slow or negligible deoxygenations. Syntheses of relevant compounds and ramifications of the results are discussed. X-ray structural details are provided for 3-OPMe(3) (90 degree angle V-O-P = 157.61(9) degrees), 3-OP(t)Bu(3) ( 90 degree angle V-O-P = 180 degrees ), 1-NbPMe(3), and (silox)(3)ClWO (9).

show abstract

η¹ versus η⁵ Bonding Modes in Cp*Al(I) Adducts of 9-Borafluorenes

Romero

Piers

Decker

et al. 2003

Organometallics

View full text Add to dashboard Cite

The reactivity of highly Lewis acidic perfluorinated borafluorenes C 12 F 8 BR (R ) C 6 F 5 , 1a; CH 3 , 1b) and the nonfluorinated 9-phenyl-9-borafluorene (2) toward [Cp*Al] 4 was investigated. The reaction of 1 with [Cp*Al] 4 leads to the formation of thermally robust η 1 Lewis acid-base adducts 3a,b as the thermodynamically favored products. Use of the less Lewis acidic 2 does not alter the mode of reactivity, with the η 1 Lewis acid-base 4 formed preferentially. Reduction of 2 to the 9-boratafluorene 2‚Li 2 (THF) n is readily accomplished in THF solution. However, reaction of 2‚Li 2 (THF) n with [Cp*AlCl 2 ] 2 or Cp*AlCl 2 (THF), 5, affords aluminum metal, 2‚THF, and Cp*H as the main identifiable products. Compounds 3a, 3b, 4, and 5 were fully characterized including their X-ray structures. A DFT computational study was conducted to probe the reason for the strong preference for η 1 bonding, which essentially stems from the localization of aromaticity in the flanking phenyl rings in the 9-borafluorene ring system.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Stephen A. Decker

Symmetry and Geometry Considerations of Atom Transfer: Deoxygenation of (silox)₃WNO and R₃PO (R = Me, Ph,^tBu) by (silox)₃M (M = V, NbL (L = PMe₃, 4-Picoline), Ta; silox =^tBu₃SiO)

η¹ versus η⁵ Bonding Modes in Cp*Al(I) Adducts of 9-Borafluorenes

Contact Info

Product

Resources

About

Stephen A. Decker

Symmetry and Geometry Considerations of Atom Transfer: Deoxygenation of (silox)3WNO and R3PO (R = Me, Ph,tBu) by (silox)3M (M = V, NbL (L = PMe3, 4-Picoline), Ta; silox =tBu3SiO)

η1 versus η5 Bonding Modes in Cp*Al(I) Adducts of 9-Borafluorenes

Contact Info

Product

Resources

About

Symmetry and Geometry Considerations of Atom Transfer: Deoxygenation of (silox)₃WNO and R₃PO (R = Me, Ph,^tBu) by (silox)₃M (M = V, NbL (L = PMe₃, 4-Picoline), Ta; silox =^tBu₃SiO)

η¹ versus η⁵ Bonding Modes in Cp*Al(I) Adducts of 9-Borafluorenes