Ene-yne cross-metathesis for the preparation of 2,3-diaryl-1,3-dienes

: Ene-yne cross-metathesis from alkynes and ethylene is a useful method to produce substituted conjugated butadiene derivatives. If this method has been used with aliphatic alkynes, it has however never been used starting from diarylacetylenes as internal alkynes. We show that the ene-yne cross-metathesis catalyzed by the second generation Hoveyda ruthenium catalyst provides the 2,3-diarylbuta-1,3-dienes under 3 atm of ethylene at 100 ◦ C. The scope and limitations of the reaction have been evaluated starting from unsymmetrical functionalized diarylacetylene derivatives hence leading to unsymmetrical 2,3-diarylbuta-1,3-dienes in a straightforward and environmentally acceptable manner. H 4 (3 atm), temperature 100 °C, toluene (2 mL). b Conversion detemined by Gas Chromatography analysis with tetradecane as internal standard; c Isolated yield. by Gas Chromatography analysis with tetradecane as internal standard; c Isolated yield. (2 mol%), C 2 H 4 (3 atm), temperature 100 °C, toluene (2 mL). b Conversion detemined by Gas Chromatography analysis with tetradecane as internal standard; c Isolated yield.

Herein, we report on the application of ruthenium-catalyzed ene-yne cross-metathesis for the direct preparation of 2,3-diarylbuta-1,3-dienes of type A from ethylene and a variety of internal alkynes. We focused on a new preparation of unsymmetrical dienes performed in one step with atom economy from suitably designed internal alkynes. This process competes in terms of productivity and environmental impact with the methods based on palladium-catalyzed cross-coupling of functionalized alkenes that produce the desired products in moderate yields together with stoichiometric amount of wastes [39,41].

Results and Discussion
The feasibility of the ene-yne cross-metathesis between 1,2-diphenylacetylene with ethylene was first evaluated in the presence of the second generation Grubbs (I) and Hoveyda (II) ruthenium catalysts ( Figure 2, Scheme 1).
Catalysts 2017, 7, 365 3 of 9 literature. A few mono-substituted 2-arylbuta-1,3-dienes have been obtained from terminal arylacetylenes [25,26,[53][54][55][56], but to the best of our knowledge only one example of synthesis of 2,3-diphenylbuta-1,3-diene via ene-yne cross-metathesis starting from an internal alkyne has been reported [57]. Herein, we report on the application of ruthenium-catalyzed ene-yne cross-metathesis for the direct preparation of 2,3-diarylbuta-1,3-dienes of type A from ethylene and a variety of internal alkynes. We focused on a new preparation of unsymmetrical dienes performed in one step with atom economy from suitably designed internal alkynes. This process competes in terms of productivity and environmental impact with the methods based on palladium-catalyzed cross-coupling of functionalized alkenes that produce the desired products in moderate yields together with stoichiometric amount of wastes [39,41].

Results and Discussion
The feasibility of the ene-yne cross-metathesis between 1,2-diphenylacetylene with ethylene was first evaluated in the presence of the second generation Grubbs (I) and Hoveyda (II) ruthenium catalysts ( Figure 2, Scheme 1). The first attempts carried out with 1 atm of ethylene in the presence of 2 mol% of Grubbs catalyst I at room temperature in dimethyl carbonate (DMC) or dichloromethane (DCM) were not successful (Table 1, entries 1-3). Increasing the ethylene pressure to 5 atm and the temperature to 80 °C in DMC or 100 °C in toluene made the ene-yne cross-metathesis possible but with modest conversion (Table 1, entries 4 and 5). Further increase of reaction pressure and reaction time in DMC led to 90% conversion of the alkyne (Table 1, entry 6). A similar beneficial effect of increasing ethylene pressure from 1 to 6 atm had been observed during the ene-yne cross-metathesis of ethylene with terminal propargylic acetates [47]. These results indicated that the ene-yne metathesis of 1,2-diphenylacetylene required higher pressure than the ene-yne metathesis of the terminal phenylacetylene, which was carried out in short reaction time under 1 atm of C2H4 at 80 °C in toluene with catalyst I [26,[53][54][55], and even at room temperature with a bimetallic ruthenium metathesis catalyst precursor [56]. The Hoveyda catalyst II was then evaluated under various experimental conditions. In dimethyl carbonate, the conversion of 1a at 80 °C under 5 atm of C2H4 was similar to that obtained with catalyst I under related conditions (Table 1, entries 4 and 7). It was  literature. A few mono-substituted 2-arylbuta-1,3-dienes have been obtained from terminal arylacetylenes [25,26,[53][54][55][56], but to the best of our knowledge only one example of synthesis of 2,3-diphenylbuta-1,3-diene via ene-yne cross-metathesis starting from an internal alkyne has been reported [57]. Herein, we report on the application of ruthenium-catalyzed ene-yne cross-metathesis for the direct preparation of 2,3-diarylbuta-1,3-dienes of type A from ethylene and a variety of internal alkynes. We focused on a new preparation of unsymmetrical dienes performed in one step with atom economy from suitably designed internal alkynes. This process competes in terms of productivity and environmental impact with the methods based on palladium-catalyzed cross-coupling of functionalized alkenes that produce the desired products in moderate yields together with stoichiometric amount of wastes [39,41].

Results and Discussion
The feasibility of the ene-yne cross-metathesis between 1,2-diphenylacetylene with ethylene was first evaluated in the presence of the second generation Grubbs (I) and Hoveyda (II) ruthenium catalysts ( Figure 2, Scheme 1). The first attempts carried out with 1 atm of ethylene in the presence of 2 mol% of Grubbs catalyst I at room temperature in dimethyl carbonate (DMC) or dichloromethane (DCM) were not successful (Table 1, entries 1-3). Increasing the ethylene pressure to 5 atm and the temperature to 80 °C in DMC or 100 °C in toluene made the ene-yne cross-metathesis possible but with modest conversion (Table 1, entries 4 and 5). Further increase of reaction pressure and reaction time in DMC led to 90% conversion of the alkyne (Table 1, entry 6). A similar beneficial effect of increasing ethylene pressure from 1 to 6 atm had been observed during the ene-yne cross-metathesis of ethylene with terminal propargylic acetates [47]. These results indicated that the ene-yne metathesis of 1,2-diphenylacetylene required higher pressure than the ene-yne metathesis of the terminal phenylacetylene, which was carried out in short reaction time under 1 atm of C2H4 at 80 °C in toluene with catalyst I [26,[53][54][55], and even at room temperature with a bimetallic ruthenium metathesis catalyst precursor [56]. The Hoveyda catalyst II was then evaluated under various experimental conditions. In dimethyl carbonate, the conversion of 1a at 80 °C under 5 atm of C2H4 was similar to that obtained with catalyst I under related conditions (Table 1, entries 4 and 7). It was Scheme 1. Ene-yne cross-metathesis of 1,2-diphenylacetylene with ethylene.
The first attempts carried out with 1 atm of ethylene in the presence of 2 mol% of Grubbs catalyst I at room temperature in dimethyl carbonate (DMC) or dichloromethane (DCM) were not successful (Table 1, entries 1-3). Increasing the ethylene pressure to 5 atm and the temperature to 80 • C in DMC or 100 • C in toluene made the ene-yne cross-metathesis possible but with modest conversion (Table 1, entries 4 and 5). Further increase of reaction pressure and reaction time in DMC led to 90% conversion of the alkyne (Table 1, entry 6). A similar beneficial effect of increasing ethylene pressure from 1 to 6 atm had been observed during the ene-yne cross-metathesis of ethylene with terminal propargylic acetates [47]. These results indicated that the ene-yne metathesis of 1,2-diphenylacetylene required higher pressure than the ene-yne metathesis of the terminal phenylacetylene, which was carried out in short reaction time under 1 atm of C 2 H 4 at 80 • C in toluene with catalyst I [26,[53][54][55], and even at room temperature with a bimetallic ruthenium metathesis catalyst precursor [56]. The Hoveyda catalyst II was then evaluated under various experimental conditions. In dimethyl carbonate, the conversion of 1a at 80 • C under 5 atm of C 2 H 4 was similar to that obtained with catalyst I under related conditions (Table 1, entries 4 and 7). It was possible to improve the conversion of the alkyne by increasing the initial concentration of the substrate from 0.06 M to 0.3 M (Table 1, entries 8-10). It must be noted that in all the experiments performed in DMC solvent, the formation of 1,2-diphenylbuta-1,3-diene 2a' resulting from hydrovinylation of the alkyne by ethylene was observed as a byproduct in variable amounts. This side reaction might be attributed to the formation of Ru-H species resulting from the reaction of ruthenium species with MeOH arising from DMC decomposition. It is interesting to note that the formation of 2a' has been reported only once by reaction of alkynes with ethylene and that a ruthenium hydride was assumed to be essential for this catalytic reaction [58]. Such Ru-H species were also previously proposed to be responsible of carbon-carbon double bonds migration during olefin metathesis reactions performed in boiling DMC [59]. Toluene appeared to be a better solvent as the reaction carried out under 3 atm of ethylene at 100 • C for 17 h gave full conversion of the alkyne (Table 1, entry 11). Not only the conversion of the alkyne was better, but the selectivity in favor of the 2,3-diphenylbuta-1,3-diene was excellent since 2a' could not be detected. Optimization of the reaction in toluene revealed that 100 • C, 17 h were the optimum experimental conditions whereas a higher pressure of ethylene had a negative effect inhibiting the catalytic reaction, and lower catalyst loading led to decreased activity (Table 1, entries 12-15). The first generation catalyst III utilized in the conditions of entry 7 led to only 10% conversion [60] and a high proportion of hydrovinylation product 2a'. The conditions reported in entry 11 appeared to be the best to investigate the scope of the reaction focused on the synthesis of unsymmetrical 2,3-diarylbuta-1,3-dienes. The unsymmetrical phenylacetylene derivatives 1b-s were prepared according to the Sonogashira method from phenylacetylene and the desired substituted halogenated aryl derivatives in the presence of catalytic amounts of PdCl 2 (PPh 3 ) 2 and CuI (See Supplementary Materials). Several alkynes presenting different electronic and steric properties were prepared in order to evaluate the full potential of the synthetic method. The results of the ene-yne cross-metathesis reactions of these substrates with C 2 H 4 (Scheme 2) are gathered in Table 2. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l (Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l ( Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO 2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. Table 2. Ene-yne cross-metathesis of unsymmetrical diarylacetylenes with ethylene a .
The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l ( Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l ( Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l ( Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l ( Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l ( Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l ( Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l (Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l (Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l (Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l (Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l (Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57]. The presence of an electron-donating or -withdrawing groups in para-position of one of the aryl groups did not inhibit the cross-metathesis with ethylene and the corresponding dienes 2b-h were isolated in high yields after 17-24 h ( Table 2, entries 1-7). Total conversion of the para-halogenated derivatives 1i-k were obtained under similar conditions and the dienes 2i-k were isolated in 89-90% yield without noticeable dehalogenation. Compounds 2i and 2k are particularly interesting for further cross-coupling reactions. The mixed phenyl 2-thiophenyl butadiene 2l was isolated in 60% yield after complete conversion of the starting alkyne 1l (Table 2, entry 11). Substitution at the ortho-position of one phenyl group was more problematic. Indeed, with the o-cyano group in 1m a very low yield of 18% was obtained whereas no reaction took place with the o-OMe and o-NO2 substrates 1n,o ( Table 2, entries 13 and 14) even when extended reaction time or higher temperatures were used. Both the steric hindrance and the potential catalyst inhibition by coordination of these o-substituents to the metal center might be at the origin of the low reactivity. Limitations were also observed with 1q-s for which steric hindrance (1q) or substrate additional coordination site (1r,s) might be responsible from the lack of reactivity. On the contrary, the arylalkylacetylene hex-1-yn-1-ylbenzene 1p led to full conversion and an excellent 97% isolated yield of 2p, a class of 1,3-dienes scarcely reported employing olefin metathesis [57].

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 °C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.

Conclusions
We have shown that 2,3-diarybuta-1,3-dienes could be prepared from diarylacetylenes using ene-yne cross-metathesis with Hoveyda second generation catalyst. The reaction requires a low ethylene pressure of 3 atm and a temperature of 100 • C. Toluene was found to be the best solvent allowing the selective formation of the desired products whereas in a greener solvent such as dimethyl carbonate the formation of hydrovinylation byproducts was observed. However, this side reaction presents a synthetic interest and will be investigated in more details. From unsymmetrical diarylacetylenes bearing one non-functionalized phenyl group, the reaction took place efficiently with a variety of substituents on the other aryl group, except in the case of bulky aromatic substituents and substitution at the ortho-position.
Author Contributions: C.B. and C.F. conceived and designed the experiments and wrote the paper; M.K.A. performed the experimental work and analyzed the analytical data. Z.K. supervised the work at the Université Frères Mentouri Constantine (Algeria).

Conflicts of Interest:
The authors declare no conflict of interest.