Computational and synthetic studies with tetravinylethylenes

Unlocking Diverse π-Bond Enrichment Frameworks by the Synthesis and Conversion of Boronated Phenyldiethynylethylenes

The π-bond enrichment frameworks not only serve as a crucial building block in organic synthesis but also assume a pivotal role in the fields of materials science, biomedicine, photochemistry, and other related disciplines owing to their distinctive structural characteristics. The incorporation of various substituents into the C═C double bonds of tetrasubstituted alkenes is currently a highly significant research area. However, the synthesis of tetrasubstituted alkenes with diverse substituents on double bonds poses a significant challenge in achieving stereoselectivity. Here, we reported an efficient and convergent route of Cu-catalyzed borylalkynylation of both symmetrical and unsymmetrical 1,3-diynes, B2pin2, and acetylene bromide to the construction of boronated phenyldiethynylethylene (BPDEE) derivatives with excellent chemo-, stereo-, and regioselectivities. BPDEE derivatives could transform into novel tetrasubstituted organic π-conjugated gem-diphenyldiethynylethylene (DPDEE), vinylphenyldiethynylethylene (VPDEE), and phenyltriethynylethylene (PTEE) derivatives by a stepwise process, which provides a flexible platform for the synthesis of complex π-bond enrichment frameworks that were difficult to synthesize by previous methods. The initial optical characterization revealed that the synthesized molecules exhibited aggregation-induced emission (AIE) properties, which further establishes the groundwork for future applications and enriches and advances the field of functional π-conjugated frameworks research.

A General Stereoselective Synthesis of [4]Dendralenes

The first general synthesis of branched tetraenes ([4]dendralenes) involves two or three steps from inexpensive, commodity chemicals. It involves an unprecedented variation on Suzuki-Miyaura cross-coupling, generating two new C-C bonds in a one-flask operation with control of diastereoselectivity. The broad scope of the method is established through the synthesis of more than 60 diversely substituted [4]dendralene molecules, along with substituted buta-1,3-dienes and other [n]dendralenes. [4]Dendralenes are demonstrated to be significantly more kinetically stable than their well-known [3]dendralene counterparts. The first stereoselective synthesis of these compounds is also reported, through the catalyst-controlled generation of both E- and Z-diastereomeric products from the same precursor. Novel, through-conjugated/cross-conjugated hybrid molecules are introduced. The first selective dienophile cycloadditions to substituted [4]dendralenes are reported, thus paving the way for applications in target-oriented synthesis.

Unlocking Acyclic π-Bond Rich Structure Space with Tetraethynylethylene-Tetravinylethylene Hybrids

Literature reports describe tetraethynylethylene (TEE) as unstable but tetravinylethylene (TVE) as stable. The stabilities of these two known compounds are reinvestigated, along with those of five unprecedented TEE-TVE hybrid compounds. The five new C₁₀ hydrocarbons possess a core, tetrasubstituted C═C bond carrying all possible combinations of vinyl and ethynyl groups. A unified strategy is described for their synthesis, whereupon cross-conjugated ketones are dibromo-olefinated then cross-coupled. Due to an incorrect but nonetheless widely held belief that acyclic π-bond rich hydrocarbons are inherently unstable, a standardized set of robustness tests is introduced. Whereas only TVE survives storage in neat form, all seven hydrocarbons are remarkably robust in dilute solution, generally surviving exposure to moderate heat, light, air, and acid. The first X-ray crystal structure of TEE is reported. Subgroups of hybrids based upon conformational preferences are identified through electronic absorption spectra and associated computational studies. These new acyclic π-bond rich systems have extensive, untapped potential for the production of stable, conjugated carbon-rich materials.

A Broad-Spectrum Synthesis of Tetravinylethylenes

The first general synthesis of compounds of the tetravinylethylene (TVE) family is reported. Ramirez-type dibromo-olefination of readily accessible penta-1,4-dien-3-ones generates 3,3-dibromo[3]dendralenes, which undergo twofold Negishi, Suzuki-Miyaura or Mizoroki-Heck reactions with a wide variety of olefinic coupling partners. This route delivers a broad range of unsymmetrically substituted tetravinylethylenes with up to three different alkenyl substituents attached to the central C=C bond. The extensive scope of the approach is demonstrated by the preparation of the first higher order oligo-alkenic through-conjugated/cross-conjugated hybrid compounds. An unsymmetrically substituted TVE is shown to undergo a domino electrocyclization-cycloaddition with high site-selectivity and diastereoselectivity, thereby demonstrating the substantial synthetic potential of substituted TVEs for controlled, rapid structural complexity generation.

Synthesis and Diels-Alder Reactivity of Substituted [4]Dendralenes

The first synthesis of all five possible monomethylated [4]dendralenes has been achieved via two distinct synthetic strategies. The Diels-Alder chemistry of these new dendralenes (as multidienes) with an electron poor dienophile, N-methylmaleimide (NMM), has been studied. Thus, simply upon mixing the dendralene and an excess of dienophile at ambient temperature in a common solvent, sequences of cycloadditions result in the rapid generation of complex multicyclic products. Distinct product distributions are obtained with differently substituted dendralenes, demonstrating that dendralene substitution influences the pathway followed, when a matrix of mechanistic possibilities exists. Dendralene site selectivities are traced to electronic, steric and conformational effects, thereby allowing predictive tools for applications of substituted dendralenes in future synthetic endeavors.

Preparation and synthetic value of π-bond-rich branched hydrocarbons

The two simplest branched acyclic structures comprising only conjugated C═C units, namely, [3]dendralene (3-methylene-1,4-pentadiene) and [4]dendralene (3,4-dimethylene-1,5-hexadiene), were first reported in 1955 and 1962, respectively. No higher members of the series were described in the literature until 2000. This Account describes the modern phase of dendralene chemistry, driven to a large extent by research performed within the author's group. The first synthesis of the parent dendralene family allowed access to the hydrocarbons in batches of up to 5 mg. The synthetic approach took into account the prevailing dogma of the time, specifically that these compounds would be very reactive species and hence difficult to handle in the laboratory. As such, a route involving the cheleotropic elimination of SO2 from stable, and generally insoluble, 3-sulfolene-masked precursors was devised. Our second-generation approach was of significantly higher value in preparative terms, allowing the syntheses of the first six members of the unsubstituted [n]dendralenes (i.e., n = 3-8) directly, on scales of hundreds of milligrams to decagrams, using commercially available precursors and standard laboratory equipment and methods. This work demonstrated that the assumed high reactivity and instability this family of compounds was erroneous and ultimately led to the development of syntheses of structurally related cross-conjugated systems including substituted dendralenes, tetravinylethylene, 1,1-divinylallene, and furan-containing analogues of the dendralenes. Cross-coupling reactions feature strongly in the syntheses of these compounds, and methods involving single- to multifold Stille, Kumada, and Negishi couplings are mainstays of this work. The even parity [n]dendralenes were shown to exhibit enhanced stability over the odd parity congeners, a result that can be attributed to conformational effects. π-Bond-rich branched hydrocarbons are demonstrated to have significant value in the rapid generation of structural complexity. Pericyclic processes are particularly useful in this regard, with the dendralenes and their relatives serving as multidienes, participating in diene-transmissive cycloaddition sequences, sometimes in combination with electrocyclizations, to generate fused and bridged multicyclic systems containing many new covalent bonds. The outcomes of exploratory investigations into pericyclic sequences involving dendralenes are presented, along with methods developed to control chemoselectivity, regioselectivity, and stereoselectivity. Distinct from their use in diene-transmissive sequences, the dendralenes also serve as multialkenes, for the direct synthesis of polyols and oligo-cyclopropanes. Finally, the deployment of π-bond-rich branched hydrocarbons in the shortest total synthesis of a pseudopterosin natural product is summarized, as a prelude to future prospects in the areas of hydrocarbon chemistry and target synthesis.