Aspects of Phosphaallene Chemistry: Heat-Induced Formation of 1,2-Dihydrophosphetes by Intramolecular Nucleophilic Aromatic Substitution and Photochemical Generation of Tricyclic Phosphiranes

Abstract: 3H-Phosphaallenes are accessible on a new and facile route and show a fascinating chemical behavior. The thermally induced rearrangement of Mes*PCC­(H)­R′ (R′ = tBu, Ad) afforded by C–H activation, isobutene elimination, and C–C and P–H bond formation bicyclic 1-benzo-dihydrophosphetes (2) with PC3 heterocycles. DFT calculations suggest a mechanism with intramolecular nucleophilic aromatic substitution and replacement of an alkyl group by the nucleophilic α-C atom of the phosphaallene. These bicycles formed … Show more

“…The tricyclic phosphirane 5 is an isomer of ap hosphaallene and was obtained by rearrangement, CÀHb ond activation and PÀCb ond formation. [14] Compound 4 represents an unusual, asymmetricd imer with aP ÀP bond. [2] One Pa tom bears an alkynyl group, while the second one is boundt oa na lkenylg roup.…”

“…One of these crystallized from the reaction mixture and wasi dentified as compound 13 (Scheme 6) which contains af ive-membered AlP 2 C 2 heterocycle and resultsf rom the reactiono fa ni ntermediately formed FLP (2,S cheme 1) with the transient phosphaallene 3b. [15] Another secondary product (14)s howed resonances of three different Pa toms with three coupling con- 8, average valueso ftwo independent molecules : P1ÀP2 2.245, P1ÀC1 1.755, C1ÀC2 1.202, P1ÀC41 1.865 3 J PP coupling and indicates the presence of aP ÀPb ond. The concentration of 14 increased continuously, while the resonances of the phosphaallene 3b disappeared after two days.…”

“…Compound K,a st he analogue of the experimentally obtained trimer 14,i sf inally formed after proton shift and release of AlMe 3 .A si mpressively shown, the formationo fthe trimericphosphaallene requires acomplicated multistep process and proceedsv ia relativelyl ow activation barriers (maximum 12.4 kcal mol À1 )w hich are in accordance with the mild reaction conditions. Overall, the trimeric formula unit (14)i st hermodynamically highly favoured over the starting material (3b), but its selectiveformation requires activation by aLewis acid.…”

“…[7e, 12] The central Ca tom of the P=C=Cm oiety bears ap artial negative charge and is attacked by protons. [1,13,14] Recently,w ef ound facile accesst ov arious 3H-phosphaallenes( 3)i namultigram scale and excellenty ields by treatment of dialkynylphosphines (1) with commerciallya vailable dialkylaluminium hydrides (e.g. iBu 2 AlH;S cheme 1).…”

“…The phosphorus-bound Ha tom of 6 allowed catalyst-free hydrophosphination reactions and the generation of bulky phosphinel igands. [14] In this paper we focus on reactions at the vinylidene part of the phosphaallenes and report on the isolation of an ovel trimericproduct of an unstable derivative.…”

New Reactivity Patterns in 3H‐Phosphaallene Chemistry [Aryl‐P=C=C(H)‐tBu]: Hydroboration of the C=C Bond, Deprotonation and Trimerisation

“…The tricyclic phosphirane 5 is an isomer of ap hosphaallene and was obtained by rearrangement, CÀHb ond activation and PÀCb ond formation. [14] Compound 4 represents an unusual, asymmetricd imer with aP ÀP bond. [2] One Pa tom bears an alkynyl group, while the second one is boundt oa na lkenylg roup.…”

“…One of these crystallized from the reaction mixture and wasi dentified as compound 13 (Scheme 6) which contains af ive-membered AlP 2 C 2 heterocycle and resultsf rom the reactiono fa ni ntermediately formed FLP (2,S cheme 1) with the transient phosphaallene 3b. [15] Another secondary product (14)s howed resonances of three different Pa toms with three coupling con- 8, average valueso ftwo independent molecules : P1ÀP2 2.245, P1ÀC1 1.755, C1ÀC2 1.202, P1ÀC41 1.865 3 J PP coupling and indicates the presence of aP ÀPb ond. The concentration of 14 increased continuously, while the resonances of the phosphaallene 3b disappeared after two days.…”

“…Compound K,a st he analogue of the experimentally obtained trimer 14,i sf inally formed after proton shift and release of AlMe 3 .A si mpressively shown, the formationo fthe trimericphosphaallene requires acomplicated multistep process and proceedsv ia relativelyl ow activation barriers (maximum 12.4 kcal mol À1 )w hich are in accordance with the mild reaction conditions. Overall, the trimeric formula unit (14)i st hermodynamically highly favoured over the starting material (3b), but its selectiveformation requires activation by aLewis acid.…”

“…[7e, 12] The central Ca tom of the P=C=Cm oiety bears ap artial negative charge and is attacked by protons. [1,13,14] Recently,w ef ound facile accesst ov arious 3H-phosphaallenes( 3)i namultigram scale and excellenty ields by treatment of dialkynylphosphines (1) with commerciallya vailable dialkylaluminium hydrides (e.g. iBu 2 AlH;S cheme 1).…”

“…The phosphorus-bound Ha tom of 6 allowed catalyst-free hydrophosphination reactions and the generation of bulky phosphinel igands. [14] In this paper we focus on reactions at the vinylidene part of the phosphaallenes and report on the isolation of an ovel trimericproduct of an unstable derivative.…”

New Reactivity Patterns in 3H‐Phosphaallene Chemistry [Aryl‐P=C=C(H)‐tBu]: Hydroboration of the C=C Bond, Deprotonation and Trimerisation

Stereochemical Behavior of Pairs of P‐stereogenic Phosphanyl Groups at the Dimethylxanthene Backbone

Molybdenum‐Mediated Insertion of Ketones into the P−P bond of cyclo‐(P₅Ph₅) and Formation of Trinuclear Molybdenum Complexes