Treatment of Terminal Alkynes R–C≡C–H with Dialkylaluminum Hydrides: Hydroalumination versus Deprotonation

Uhl, Werner; Er, Elif; Hepp, Alexander; Kösters, Jutta; Layh, Marcus; Rohling, Martina; Виноградов, А. Н.; Würthwein, Ernst‐Ulrich; Ghavtadze, Nugzar

doi:10.1002/ejic.200900264

Cited by 36 publications

(32 citation statements)

References 55 publications

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“…Yang, Parameswaran, and Roesky have reported the catalytic hydroboration of alkynes by a N,N'-bis-2,6-diisopropylphenyl diketiminate (NacNac)-supported aluminum dihydride. Treatment of the isolated alkenyl aluminum species 5 [22] with HBpin formed the borylated alkene 2c (Scheme 4a). Ther ate-determining step in this mechanism was predicted computationally to be protonation of the borylated alkenyl group at the aluminum center by the incoming terminal alkyne,w ith an activation barrier of 45.3 kcal mol À1 .…”

Section: Angewandte Chemiesupporting

confidence: 93%

Aluminum Hydride Catalyzed Hydroboration of Alkynes

2016

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An aluminum-catalyzed hydroboration of alkynes using either the commercially available aluminum hydride DIBAL-H or bench-stable Et Al⋅DABCO as the catalyst and H-Bpin as both the boron reagent and stoichiometric hydride source has been developed. Mechanistic studies revealed a unique mode of reactivity in which the reaction is proposed to proceed through hydroalumination and σ-bond metathesis between the resultant alkenyl aluminum species and HBpin, which acts to drive turnover of the catalytic cycle.

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Section: Angewandte Chemiesupporting

confidence: 93%

Aluminum Hydride Catalyzed Hydroboration of Alkynes

2016

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“…The formation of the products was evident from the disappearance of the Ge–H signal at about δ = 4.5 in the 1 H NMR spectra and the appearance of characteristic downfield signals for Ph 2 C( H )O at δ = 6.09 and C( H )=O, C( H )=N and CH=C H at δ > 7. The trans ‐configuration of the alkene in 10 is confirmed by the large 3 J HH coupling constant of 19.8 Hz , . Further characteristic signals are found in the 13 C NMR spectra with δ = 83.2 [Ph 2 C (H)O] (upfield to Ph 2 CO) and δ = 173.7, 156.1 and 134.2/148.9 [N‐ C (H)=O, N= C (H) and C H= C H] (downfield relative to the starting materials).…”

Section: Resultsmentioning

confidence: 80%

Aluminium Functionalized Germanes: Intramolecular Activation of Ge–H Bonds, Formation of a Dihydrogen Bond and Facile Hydrogermylation of Unsaturated Substrates

et al. 2019

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A series of alkenylhydrogermanes, RR′(H)Ge‐C(AlR′′2)=C(H)‐tBu [4a, R = R′ = Mes, R′′ = tBu; 4b, R = R′ = Mes, R′′ = CH(SiMe3)2; 5a, R = R′′ = tBu, R′ = CH2CH2tBu; 5b, R = tBu, R′ = CH2CH2tBu, R′′ = CH(SiMe3)2], was synthesized by hydroalumination of the respective alkynylgermanes, RR′(H)Ge‐C≡C‐tBu 3, with R′′2Al–H [R′′ = tBu, CH(SiMe3)2]. In the solid state compound 5b showed a contact between Al and the Ge bound H atom (293 pm) which according to quantum chemical calculations results in Ge–H bond activation. In case of less bulky substituents on Al (5a, R′′ = tBu) a mixture of isomers was observed that reacted with Et2NH to yield the simple Lewis acid‐base adduct [(tBu)(tBuCH2CH2)(H)Ge‐C(AltBu2)=C(H)‐tBu](HNEt2) (6). 6 features a dihydrogen bond (Ge–H···H–N) as evident from typical downfield (N–H) and high‐field (Ge–H) shifts in the NMR spectrum, red shifts of νGe‐H and νN‐H in the IR spectrum, a short H···H contact (210 pm) in the solid state and a bond critical point between both H atoms. The presence of a hard Lewis‐acidic Al atom in geminal position to the Ge–H bond in 5a facilitates reactions with Ph2CO, OC4H8N‐C≡N and Ph–NCO under surprisingly mild conditions by hydrogermylation of the heteronuclear π‐bonds and formation of four‐membered Ge–O/N–Al–C (7, 9) or six‐membered Ge–N–C–O–Al–C (8) heterocycles. Reaction with Ph–C≡C–H afforded the cis‐addition product 10, in which the α‐C atom of the new alkenyl group showed a close contact [258.3(2) pm] to the Al atom.

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“…Im ersten Fall verhindert die sterische Abschirmung den Substituentenaustausch, im zweiten Fall bilden sich bevorzugt eindimensional unendliche Koordinationspolymere mit ausschließlich vinylischen Kohlenstoffatomen in den verbrückenden Positionen. Die Produkte der einfachen Addition mit intakten AlR 2 ‐Gruppen gebunden an die Alkenyleinheiten entstehen auch mit terminalen Alkinen (H–C≡C–R) 6 und mit Trimethylsilylethinylbenzol‐Derivaten [7, 8]. In Abhängigkeit von der sterischen Abschirmung treten mit den Trimethylsilylverbindungen spontane cis / trans ‐Umlagerungen ein, die im Einklang mit quanten‐chemischen Rechnungen einer intermolekularen Aktivierung bedürfen 8.…”

Section: Introductionunclassified

Hydroaluminierung von Silicium‐zentrierten Dialkinen – Synthese gemischt‐substituierter Alkenyl‐alkinylsilane

Uhl

Heller

2010

Zeitschrift anorg allge chemie

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Bis(phenylethynyl)silanes reacted with equimolar quantities of various dialkylaluminium hydrides, R2Al–H [R = CH2tBu, tBu, iBu, CH(SiMe3)2], by hydroalumination and addition of a Al–H bond to a C≡C triple bond. Alkenyl‐alkynylsilanes were formed, which had the aluminium atoms in geminal positions with the silicon atoms and adopt a cis arrangement of aluminium and hydrogen at the resulting C=C double bonds in most cases. cis/trans‐Rearrangement with the formation the trans‐addition products was observed only for the two sterically least shielded compounds. Intramolecular interactions of the coordinatively unsaturated aluminium atoms with the α‐carbon atoms of the intact alkynyl groups were detected by crystal structure determinations for the tert‐butyl and neopentyl derivatives, whereas they did not occur with bulky bis(trimethylsilyl)methyl substituents.

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Treatment of Terminal Alkynes R–C≡C–H with Dialkylaluminum Hydrides: Hydroalumination versus Deprotonation

Cited by 36 publications

References 55 publications

Aluminum Hydride Catalyzed Hydroboration of Alkynes

Aluminum Hydride Catalyzed Hydroboration of Alkynes

Aluminium Functionalized Germanes: Intramolecular Activation of Ge–H Bonds, Formation of a Dihydrogen Bond and Facile Hydrogermylation of Unsaturated Substrates

Hydroaluminierung von Silicium‐zentrierten Dialkinen – Synthese gemischt‐substituierter Alkenyl‐alkinylsilane

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