Microwave-ultrasound simultaneous irradiation: a hybrid technology applied to ring closing metathesis

Sacco, M.; Charnay, Clarence; Angelis, Francesco De; Radoiu, Marilena; Lamaty, Frédéric; Martinez, Jean; Colacino, Evelina

doi:10.1039/c4ra14938f

Cited by 15 publications

(7 citation statements)

References 68 publications

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“…However, the use of microwave or ultrasound irradiation promoted the undesired isomerisation of the C=C bond, thus lowering the yields of the desired product 9 (Table 1, entries 3 and 4). This result is in agreement with the known fact that in protic solvents ruthenium hydrides are formed leading to isomerisation byproducts [66]. Finally, we were pleased to see that the use of ultrasound or microwave irradiation were beneficial for the CM of alcohol 8 with methyl acrylate ( 10 , Table 1, entries 5 and 6) resulting not only in increased conversion but also reducing the amount of the unwanted product of self-metathesis of 8 .…”

Section: Resultssupporting

confidence: 86%

“…Both methods were shown in the past to be responsible for shortening the reaction time, increasing the reaction yield or even favour the formation of the desired product when compared to traditional protocols [56–57]. In the case of olefin metathesis, examples of application of those techniques are well documented for organic solvents [58–66], surprisingly, examples describing reactions in aqueous media are scarce and thus merit further investigation [67–68].…”

Section: Introductionmentioning

confidence: 99%

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Ammonium-tagged ruthenium-based catalysts for olefin metathesis in aqueous media under ultrasound and microwave irradiation

Gułajski¹,

Tracz²,

Urbaniak³

et al. 2019

Beilstein J. Org. Chem.

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The influence of microwave and ultrasonic irradiation on the performance of ammonium-tagged Ru-based catalysts in olefin metathesis transformations in aqueous media was studied. Differences in the catalytic activity in correlation with the nature of the present counter ion and the size of the N-heterocyclic carbene (NHC) ligand were revealed. The presented methodology allows for preparation of a variety of polar and non-polar metathesis products under environmentally friendly conditions.

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Section: Resultssupporting

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Ammonium-tagged ruthenium-based catalysts for olefin metathesis in aqueous media under ultrasound and microwave irradiation

Gułajski¹,

Tracz²,

Urbaniak³

et al. 2019

Beilstein J. Org. Chem.

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“…We assumed that this was due to molecular interactions between the ruthenium-based carbene complex and oleic acid, and concluded that some catalyst may have stuck to the wall of the reaction vial, thus limiting reaction yields. An ultrasound probe was used to ensure effective mixing (Gulajski et al, 2008;Jakobs and Sijbesma, 2012;Piermattei et al, 2009;Sacco et al, 2015;Sari et al, 2013). With sonication and in the absence of solvent, higher rates of oleic acid conversion were observed after only 5 h of reaction (Tab.…”

Section: Schemamentioning

confidence: 99%

Ultrasound-assisted self-metathesis reactions of monounsaturated fatty acids

Elmkaddem

Thiébaud‐Roux

et al. 2016

OCL

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-An efficient protocol for the self-metathesis of oleic acid, using ruthenium catalysts is described. The self-metathesis reaction under ultrasonic activation allows the conversion of monoenic fatty acids such as oleic acid, elaidic acid and erucic acid into diacids and olefins with very short reaction times in the presence of Grubbs ruthenium catalysts. These yields and selectivity towards the desired products are influenced by the nature of solvents. This study demonstrated that metathesis reaction carried out in DCM or 1-butanol showed promising results, since it produced a variety of products, like n-alkenes and diacids with good yields (45-75%) and high selectivities (75-95%).Keywords: Self-metathesis / long-chain diacids / oleic acid / 1,18-octadec-9-enedioic acid / 1,26-hexacos-13-enedioic acid Résumé -Métathèse activée par les ultrasons : homocouplage d'acides gras monoinsaturés. Un nouveau protocole efficace pour l'homocouplage de l'acide oléique par réaction métathèse utilisant des catalyseurs de ruthénium est décrit dans cet article. La réaction d'homocouplage activée par ultrasons permet d'obtenir avec des temps de réac-tion très faibles, la conversion d'acides gras insaturés tels que l'acide oléique, l'acide élaïdique et l'acide érucique en diacides et oléfines en présence de catalyseurs au ruthénium de Grubbs. Les rendements et la sélectivité des produits obtenus sont influencés par la nature du solvant utilisé. Cette étude a démontré que la réaction de métathèse réalisée dans du dichlorométhane ou du 1-butanol donne des résultats prometteurs : elle permet d'obtenir une grande variété d'alcènes et des diacides à longues chaînes avec de bons rendements (45-75 %) et des sélectivités élevées (75-95 %). Mots clés :Homocouplage / métathèse / diacides à longue chaîne / acide oléique / acide 1,18-octadéc-9-ènedioïque / acide 1,26-hexacos-13-ènedioïque

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“…After 2010 a number of papers were published having as topic either two steps processes, like metal organic framework IRMOF-1 synthesis [12], (in a separate reactors as stated by Lionelli and Mason), synthesis of polysubstituted pyridines under combined microwave and ultrasound irradiation [13], porous manganese dioxide (MnO2) synthesized via an ultrasound-microwave-intensified precipitation [14] (perhaps in a single reactorthe papers do not offers details of equipment), or even for biodiesel preparation emphasizing the synergetic effects of combining both source of energy in one device [15]. Several papers shown how to build or review the simultaneous ultrasound and microwave new reactor [16][17][18][19], others how to use this combination for adding value to some byproducts (like glycerol from biodiesel synthesis) [20]. Clearly there are efforts in developing such a combined device in which MW and US could be used together in a controllable mode.…”

Section: Introductionmentioning

confidence: 99%

“…This device is produced by SAIREM and is described in a paper published few years ago by Sacco et. al., [17] as a hybrid technology applicable for a specific process (ring closing metathesis) and is in use in our laboratory from a couple of years. This device is having as ultrasonic source a modified ultrasonic cleaning bath to be attachable to the MW unit (see figure 5).…”

Section: Introductionmentioning

confidence: 99%

Microwave and Ultrasounds Together – A Challenge

Vînătoru

2019

Proceedings 17th International Conference on Microwave and High Frequency Heating

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The literature related to microwave and ultrasound working simultaneously is rather infrequent. The reason is obvious: microwave irradiation is of electromagnetic origin while ultrasound is a mechanical vibration energy. Moreover, the optimal settings for ultrasound propagation throughout a reaction media do not coincide with the conditions required for application of microwaves. Therefore, the challenge is to find a way to best combination of these sources of energy into one apparatus to allow researchers to take advantage of the features of each technology. The oldest paper describing such a combination – microwave and ultrasound is having just 20 years [1] and describe an apparatus which uses a probe system delivering ultrasound through decalin to a vessel holding the reagents dipped in the MW cavity (fig. 1a). Another possibility using a normal MW oven is described by Peng [2] (fig.1b), but this setup is having radiation leakage problems and needs a proper protection. Ragaini et all proposed another type of setup [3] (fig. 1c), not easy to reproduce, but describing calibration and parameters which show an additive increase of thermal energy delivered when MW and US works simultaneous. Insert here uploaded pictures Figure 1. Some MW-US simultaneous setups Few years ago, Cravotto and Cintas [4], disccussed for the first time the potential of using MW and US in sequential or tandem setups. Their paper discuss all possible setups for using mostly glass probe for devlivery of ultrasonic energy or classical setup (fig. 1a). Slowly the concept gain popularity and the paper of Lionelly and Mason [5] prompts to the potential industrial applications, naming the combination of microwave with ultrasound a hybrid technology. The challenge in using this “hybrid technology” is to find a vesatile and reproducible apparatus able to deliver both microwave and ultrasound at a full controlable parameters. In our laboratory we have and use the setup like in the fig. 1a, but the ultrasonic energy is delivered by an ultrasonic cleaning device attached to microwave device (SAIREM Miniflow 200SS). To achieve the above mentioned outcome launched a project to build a device which could work with MW and US in tandem (as Cravotto mentioned [4]) using an US device able to deliver more than a single ultrasonic frequency at a full controlled power. It is our believe that such a device could significantly contribute to MW-US tandem equipment development. Based on our expertise and potential proposed interaction of US with reagents [6] we will investigate the influence (if any) of ultrasound upon MW field. In this paper we will present the earlier results of “Tandem Microwave Ultrasound” energy influence on chemical reagents. References 1. Lagha, A., et al., Analusis, 1999. 27(5): p. 452-457. 2. Peng, Y. and G. Song, Green Chemistry, 2001. 3(6): p. 302-304. 3. Ragaini, V., et al., Ultrasonics Sonochemistry, 2012. 19(4): p. 872-876. 4. Cravotto, G. and P. Cintas, Chemistry - A European Journal, 2007. 13(7): p. 1902-1909. 5. Leonelli, C. and T.J. Mason, Chemical Engineering and Processing: Process Intensification, 2010. 49(9): p. 885-900. 6. Vinatoru, M. and T.J. Mason, Ultrasonics Sonochemistry, 2018.

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Microwave-ultrasound simultaneous irradiation: a hybrid technology applied to ring closing metathesis

Cited by 15 publications

References 68 publications

Ammonium-tagged ruthenium-based catalysts for olefin metathesis in aqueous media under ultrasound and microwave irradiation

Ammonium-tagged ruthenium-based catalysts for olefin metathesis in aqueous media under ultrasound and microwave irradiation

Ultrasound-assisted self-metathesis reactions of monounsaturated fatty acids

Microwave and Ultrasounds Together – A Challenge

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