Synthèse de structures complexes par réactions en cascade et catalyse au rhodium / Synthesis of complex structures by means of cascade reactions and rhodium catalysis

Salacz, Laura

29 October 2018

Ces travaux de thèse ont permis, au cours de deux projets, de s’attacher à la synthèse de structures complexes au moyen de réaction en cascade et de catalyse au rhodium.Dans une première partie, une méthodologie robuste pour la synthèse de 2,4,6-cycloheptatriénones entièrement substituées et non-symétriques par réaction de cycloaddition carbonylative [2+2+2+1] catalysée par des complexes de rhodium a été développée. Des mécanismes expliquant la formation des différents composés ont été proposés. Dans une seconde partie, l’application de l’hydroformylation désymétrisante catalysée au rhodium à la synthèse totale d’alcaloïdes indoliques de la famille Aspidosperma a été étudiée. Un intermédiaire clé de la synthèse de composés de type eburnane a ainsi été obtenu et sa transformation par différente stratégies été explorée. La synthèse totale de composés de type aspidosperma a été étudié, et les voies de synthèse explorées pourront être appliquées à des aldéhydes issus d’hydroformylation désymétrisante. / Through the course of two projects, this thesis work was concerned with the synthesis of complex scaffolds by means of cascade reactions and rhodium catalysis.In a first part, a new methodology was developed for the synthesis of non-symmetrical and fully substituted 2,4,6-cycloheptatrienones by rhodium-catalysed [2+2+2+1] carbonylative cycloaddition. Mechanisms for the formations of the observed compounds were proposed.In a second part, the application of rhodium-catalysed desymmetrising hydroformylation to the total synthesis of Aspidosperma indole alkaloids was studied. A key intermediate in the synthesis of eburnan-type alkaloids was thus obtained, and its transformation into th desired compounds using various strategies was explored. The total synthesis of aspidosperma-type alkaloids was studied, and the explored syntheses will be applied to aldehydes obtained by desymmetrising hydroformylation.

Tropone

Cycloaddition carbonylative

Cyclohydrocarbonylation

Réaction en cascade

Rhodium

Hydroformylation désymétrisante

Aspidosperma

Tropone

Carbonylative cycloaddition

Cyclohydrocarbonylation

Cascade reactions

Rhodium

Dessymmetrising hydroformylation

Aspidosperma

541.3

The syntheses, photochromism and aromaticity of dimethyldihydropyrene derivatives containing organometallic fragments and [e]-fused C7 and C8 aromatic systems

Zhang, Pengrong

08 September 2011

A series of cis- and trans-bis(ethynyl)platinum complexes containing dimethyldihydropyrene (DHP) photochromic compounds were synthesized from RDHPCCH (R = H, CH3CO, PhCO, 1-naphthoyl and benzo[e]) and platinum chloride with appropriate ancillary ligands (PEt3, PPh3, dppe, bipy and phen). The complexes were studied using mass spectrometry, NMR spectroscopy (1H, 13C, 31P and 195Pt) and IR. The X-ray structural information for bis(DHP-ethynyl) platinum complexes 44, 45, 47, 49, and 52 revealed that the Pt complexes possessed a square planar geometry at the metal centers. These platinum complexes are T type photochromic compounds. The BDHP-derived platinum complexes 48, 49, and 52 open completely when irradiated by visible light (λ > 590 nm). The photoopening rates for the platinum complexes are about 4 times slower than the corresponding DHP-alkynes. All the alkynyl platinum complexes close thermally faster than the corresponding free alkynes, and the closing rate is not affected substantially by changing the ancillary phosphine ligands. The BDHP-ethynyl platinum complexes with PEt3, PPh3 and dppe ligands have similar thermal closing half lives at 25°C of τ1/2 = 42 h, 38 h and 33 h, respectively, in contrast to the half life τ1/2 = 62 h of the BDHP-ethyne 40. The first cyclobutadienyl cobalt substituted dihydropyrenes were prepared by CpCo(CO)2 cyclization of a series of dihydropyrenyl ethynes. When the other alkyne substituent was small (methyl or carboxyethyl) only cis (head-to-head) isomers were obtained, but with larger sized groups, mixed head-to-head and head-to-tail isomers were obtained. The crystal structure of complex 21 indicated some unusually short bond distances were present. By comparison of the NMR and bond length data for complexes 21 or 69 with those for phenyl-DHP 60, the aromaticity of the cyclobutadienyl cobalt fragment was estimated quantitatively to be at least as large as that of benzene. The organometallic fragment [Cbd-Co-Cp] substantially slowed the DHP photoopening reaction of complex 72 relative to precursors 67 or 35. DHP[e]tropone, 17, DHP[e]tropylium cation, 18 and DHP[e]cyclooctatetraene dianion, 20 were synthesized to study the relative bond localizing abilities of COT dianion 80 (105 % relative to benzene), tropylium cation 15 (55 % relative to benzene), tropone 79 (13 % relative to benzene) using DHP as the NMR probe. The internal methyl protons of DHP resonated at δ -3.56 for 17, δ -2.61 for 18 and δ -1.38 for 20. Cycloheptatrienyl anions 111, 112 and 19 were made from cyclohepta-2,4,6-triene (CHT) isomers 107 and 108 (for two anions, 112 and 19). The internal methyl protons of their DHP resonated at δ -2.52, 2.67 for 111, δ -0.80, -0.84 for 112 and δ +2.10 for 19. The anion 19 was best taken as a 20π electron paratropic system. The homo-aromaticity of the CHT isomers 107, 108 and 117 was estimated based on the NMR data and X-ray structural data. Obvious anisotropic effects existed and the bond localization ability of the CHT (24% based on NMR data for 108) may have a large error. The ring inversion barriers of the COT 82 and CHT 77 were measured using variable temperature NMR spectroscopy as 13.9 and 8.7 kcal/mol, respectively. Five X-ray crystallography structures were obtained for 99B, 17, 108, 117 and 125 and the information was used in estimating the bond localization abilities and in establishing absolute stereochemistry / Graduate

dimethyldihydropyrene

photochromic

bis(DHP-ethynyl) platinum complexes

cyclobutadienyl cobalt

tropone

tropylium cation

Cycloheptatrienyl anions

cyclooctatetraene dianion