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Frustrated Lewis pair

January 01, 1970

A frustrated Lewis pair (FLP) is a compound or mixture containing a Lewis acid and a Lewis base that, because of steric hindrance, cannot combine to form a classical adduct.[1] Many kinds of FLPs have been devised, and many simple substrates exhibit activation.[2][3]

The discovery that some FLPs split H2[4] triggered a rapid growth of research into FLPs. Because of their "unquenched" reactivity, such systems are reactive toward substrates that can undergo heterolysis. For example, many FLPs split hydrogen molecules. Thus, a mixture of tricyclohexylphosphine (PCy3) and tris(pentafluorophenyl)borane reacts with hydrogen to give the respective phosphonium and borate ions:

This reactivity has been exploited to produce FLPs which catalyse hydrogenation reactions.[5]

Small molecule activation edit

Frustrated Lewis pairs have been shown to activate many small molecules, either by inducing heterolysis or by coordination.

Hydrogen edit

The discovery that some FLPs are able to split, and therefore activate, H2[4] triggered a rapid growth of research into this area. The activation and therefore use of H2 is important for many chemical and biological transformations. Using FLPs to liberate H2 is metal-free, this is beneficial due to the cost and limited supply of some transition metals commonly used to activate H2 (Ni, Pd, Pt).[6] FLP systems are reactive toward substrates that can undergo heterolysis (e.g. hydrogen) due to the "unquenched" reactivity of such systems. For example, it has been previously shown that a mixture of tricyclohexylphosphine (PCy3) and tris(pentafluorophenyl)borane reacts with H2 to give the respective phosphonium and borate ions:

 

In this reaction, PCy3 (the Lewis base) and B(C6F5)3 (the Lewis acid) cannot form an adduct due to the steric hindrance from the bulky cyclohexyl and pentafluorophenyl groups. The proton on the phosphorus and hydride from the borate are now ‘activated’ and can subsequently be ‘delivered’ to an organic substrate, resulting in hydrogenation.

Mechanism of dihydrogen activation by FLP edit

The mechanism for the activation of H2 by FLPs has been discussed for both the intermolecular and intramolecular cases. Intermolecular FLPs are where the Lewis base is a separate molecule to the Lewis acid, it is thought that these individual molecules interact through secondary London dispersion interactions to bring the Lewis base and acid together (a pre-organisational effect) where small molecules may then interact with the FLPs. The experimental evidence for this type of interaction at the molecular level is unclear. However, there is supporting evidence for this type of interaction based on computational density functional theory studies. Intramolecular FLPs are where the Lewis acid and Lewis base are combined in one molecule by a covalent linker. Despite the improved ‘pre-organisational effects’, rigid intramolecular FLP frameworks are thought to have a reduced reactivity to small molecules due to a reduction in flexibility.

Other small molecule substrates edit

FLPs are also reactive toward many unsaturated substrates beyond H2. Some FLPs react with CO2, specifically in the deoxygenative reduction of CO2 to methane.[7]

Ethene also reacts with FLPs:[8]

 

For acid-base pairs to behave both nucleophilically and electrophilically at the same time offers a method for the ring-opening of cyclic ethers such as THF, 2,5-dihydrofuran, coumaran, and dioxane.[9]

Use in catalysis edit

Imine, nitrile and aziridine hydrogenation edit

 
Catalytic cycle for reduction of imine to an amine using an FLP

Reduction of imines, nitriles, and aziridines to primary and secondary amines traditionally is effected by metal hydride reagents, e.g. lithium aluminium hydride and sodium cyanoborohydride. Hydrogenations of these unsaturated substrates can be effected by metal-catalyzed reactions. Metal-free catalytic hydrogenation was carried out using the phosphonium borate catalyst (R2PH)(C6F4)BH(C6F5)2 (R = 2,4,6-Me3C6H2) 1. This type of metal-free hydrogenation has the potential to replace high cost metal catalyst.

The mechanism of imine reduction is proposed to involve protonation at nitrogen giving the iminium salt. The basicity of the nitrogen centre determines the rate of reaction. More electron rich imines reduce at faster rates than electron poor imines. The resulting iminium center undergoes nucleophilic attack by the borohydride anion to form the amine. Small amines bind to the borane, quenching further reactions. This problem can be overcome using various methods: 1) Application of elevated temperatures 2) Using sterically bulky imine substituents 3) Protecting the imine with the B(C6F5)3group, which also serves as a Lewis acid promoter.[10]

Enantioselective imine hydrogenation edit

A chiral boronate Lewis acid derived from (1R)-(+)-camphor forms a frustrated Lewis pair with tBu3P, which is isolable as a salt. This FLP catalyses the enantioselective hydrogenation of some aryl imines in high yield but modest ee (up to 83%).

 
Asymmetric imine hydrogenation by an FLP

Although conceptually interesting, the protocol suffers from lack of generality. It was found that increasing steric bulk of the imine substituents lead to decreased yield and ee of the amine product. methoxy-substituted imines exhibit superior yield and ee's.[10]

Asymmetric hydrosilylations edit

Frustrated Lewis pairs of chiral alkenylboranes and phosphines are beneficial for asymmetric Piers-type hydrosilylations of 1,2-dicarbonyl compounds and alpha-keto esters, giving high yield and enantioselectivity. However, in comparison to conventional Piers-type hydrosilyations, asymmetric Piers-type hydrosilylations are not as well developed.

In the following example, the chiral alkenylborane is formed in situ from a chiral diyne and the HB(C6F5)2. Heterolytic cleavage of the Si-H bond from PhMe2SiH by the FLP catalyst forms a silylium and hydridoborate ionic complex.[11]

 
Asymmetric hydrosilylation of a diketone by an FLP

Alkyne hydrogenation edit

Metal free hydrogenation of unactivated internal alkynes to cis-alkenes is readily achieved using FLP-based catalysts.[12] The condition for this reaction were relatively mild utilising 2 bar of H2. In terms of mechanism, the alkyne material is first hydroborated and then the resulting vinylborane-based FLP can then activate dihydrogen. A protodeborylation step releases the cis-alkene product, which is obtained due to the syn-hydroborylation process, and regenerating the catalyst. While active for alkyne hydrogenation the FLP-based catalysts do not however facilitate the hydrogenation of alkenes to alkanes.

The reaction is a syn-hydroboration, and as a result a high cis selectivity is observed. At the final stage of the catalytic cycle the C6F5 group is cleaved more easily than an alkyl group, causing catalyst degradation rather than alkane release. The catalytic cycle has three steps:

  • Substrate binding (the hydroboration of alkyne)
  • H2 cleavage with vinylborane, followed by intramolecular protodeborylation of vinyl substituent, recovering N,N-Dimethyl-2-[(pentafluorophenyl)boryl]aniline
  • Release of the cis-alkene
 
Binding of terminal alkyne to the FLP catalyst

With internal alkynes, a competitive reaction occurs where the proton bound to the nitrogen can be added to the fluorobenzenes. Therefore, this addition does not proceed that much, the formation of the alkene seems favoured.

But terminal alkynes do not bind to the boron through hydroboration but rather through C-H activation. Thus, the addition of the proton to the alkyne will result in the initial terminal alkyne. Hence this hydrogenation process is not suitable to terminal alkynes and will only give pentafluorobenzene.

The metal free hydrogenation of terminal alkynes to the respective alkenes was recently achieved using a pyridone borane based system.[13] This system activates hydrogen readily at room temperature yielding a pyridone borane complex.[14] Dissociation of this complex allows hydroboration of an alkyne by the free borane. Upon protodeborylation by the free pyridone the cis alkene is generated. Hydrogenation of terminal alkynes is possible with this system, because the C-H activation is reversible and competes with hydrogen activation.

Borylation edit

Amine-borane FLPs catalyse the borylation of electron-rich aromatic heterocycles (Scheme 1).[15] The reaction is driven by release of hydrogen via C-H activation by the FLP. Aromatic borylations are often used in pharmaceutical development, particularly due to the abundance, low cost and low toxicity of boron compounds compared to noble metals.,

 
Scheme 1: Mechanism for borylation catalysed by FLP

The substrate for the reaction has two main requirements, strongly linked to the mechanism of borylation. First, the substrate must be electron rich, exemplified by the absence of a reaction with thiophene, whereas its more electron rich derivatives - methoxythiophene and 3,4-ethylenedioxythiophene - can undergo a reaction with the amino-borane. Furthermore, substitution of 1-methylpyrrole (which can react) with the strongly electron withdrawing tertbutyloxycarbonyl (Boc) group at the 2-position completely inhibits the reaction. The second requirement is for the absence of basic amine groups in the substrate, which would otherwise form an unwanted adduct. This can be illustrated by the lack of a reaction with pyrrole, whereas both 1-methyl and N-benzylpyrrole derivatives are able to react.

Further work by the same authors revealed that simply piperidine as the amine R group (as opposed to tetramethylpiperidine, pictured above) accelerated the rate of reaction. Through kinetic and DFT studies the authors proposed that the C-H activation step was more facile than with larger substituents.[16]

Dearomatisation can also be achieved under similar conditions but using N-tosyl indoles. Syn-hyrdoborylated indolines are obtained.[17]

 
Deromatisation of N-tosyl indole by HBpin

Borylation of S-H bonds in thiols by a dehydrogenative process has also been observed. Alcohols and amines such as tert-Butanol and tert-Butylamine form stable products that prevent catalysis due to a strong π-bond between the N/O atom's lone pair and boron, whereas the same is not true for thiols, thus allowing for successful catalysis. In addition, successful borylation of Se-H bonds has been achieved. In all cases, the formation of H2 gas is a strong driving force for the reactions.[18]

Carbon capture edit

FLP chemistry is conceptually relevant to carbon capture.[19] Both an intermolecular (Scheme 1) and intramolecular (Scheme 2) FLP consisting of a phosphine and a borane were used to selectively capture and release carbon dioxide. When a solution of the FLP was covered by an atmosphere of CO2 at room temperature, the FLP-CO2 compound immediately precipitated as a white solid.[19][20]

 
Scheme 1: Intermolecular FLP CO2 capture and release

Heating the intermolecular FLP-CO2 compound in bromobenzene at 80 °C under vacuum for 5 hours caused the release of around half of the CO2 and regenerating the two constituent components of the FLP. After several more hours of sitting at room temperature under vacuum, total release of CO2 and FLP regeneration had occurred.[19]

 
Scheme 2: Intramolecular FLP CO2 capture and release

The intramolecular FLP-CO2 compound by contrast was stable as a solid at room temperature but fully decomposed at temperatures above -20 °C as a solution in dichloromethane releasing CO2 and regenerating the FLP molecule.[19]

This method of FLP carbon capture can be adapted to work in flow chemistry systems.[21]

References edit

  1. ^ Stephan, Douglas W (2008). "Frustrated Lewis pairs: a concept for new reactivity and catalysis". Org. Biomol. Chem. 6 (9): 1535–1539. doi:10.1039/b802575b. PMID 18421382.  
  2. ^ Stephan, Douglas W.; Erker, Gerhard (2010). "Frustrated Lewis Pairs: Metal-free Hydrogen Activation and More". Angewandte Chemie International Edition. 49 (1): 46–76. doi:10.1002/anie.200903708. ISSN 1433-7851. PMID 20025001.  
  3. ^ Stephan, Douglas W.; Erker, Gerhard (2017). "Frustrated Lewis pair chemistry". Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences. 375 (2101): 20170239. Bibcode:2017RSPTA.37570239S. doi:10.1098/rsta.2017.0239. ISSN 1364-503X. PMC 5540845. PMID 28739971.  
  4. ^ a b Welch, Gregory C.; Juan, Ronan R. San; Masuda, Jason D.; Stephan, Douglas W. (2006). "Reversible, Metal-Free Hydrogen Activation". Science. 314 (5802): 1124–1126. Bibcode:2006Sci...314.1124W. doi:10.1126/science.1134230. ISSN 0036-8075. PMID 17110572. S2CID 20333088.  
  5. ^ Lam, Jolie; Szkop, Kevin M.; Mosaferi, Eliar; Stephan, Douglas W. (2018). "FLP catalysis: main group hydrogenations of organic unsaturated substrates". Chemical Society Reviews. 41 (13): 3592–3612. doi:10.1039/C8CS00277K. PMID 30178796. S2CID 206130644.
  6. ^ Welch, Gregory C.; Juan, Ronan R. San; Masuda, Jason D.; Stephan, Douglas W. (2006-11-17). "Reversible, Metal-Free Hydrogen Activation". Science. 314 (5802): 1124–1126. Bibcode:2006Sci...314.1124W. doi:10.1126/science.1134230. ISSN 0036-8075. PMID 17110572. S2CID 20333088.
  7. ^ Berkefeld, Andreas; Piers, Warren E.; Parvez, Masood (2010-08-11). "Tandem Frustrated Lewis Pair/Tris(pentafluorophenyl)borane-Catalyzed Deoxygenative Hydrosilylation of Carbon Dioxide". Journal of the American Chemical Society. 132 (31): 10660–10661. doi:10.1021/ja105320c. ISSN 0002-7863. PMID 20681691.
  8. ^ Stephan, D. W. (2009). ""Frustrated Lewis Pairs": A New Strategy to Small Molecule Activation and Hydrogenation Catalysis". Dalton Trans (17): 3129–3136. doi:10.1039/b819621d. PMID 19421613.  
  9. ^ Tochertermam, W (1966). "Structures and Reactions of Organic ate-Complexes". Angew. Chem. Int. Ed. 5 (4): 351–171. doi:10.1002/anie.196603511.
  10. ^ a b Chen, Dianjun; Wang, Yutian; Klankermayer, Jürgen (2010-12-03). "Enantioselective Hydrogenation with Chiral Frustrated Lewis Pairs". Angewandte Chemie International Edition. 49 (49): 9475–9478. doi:10.1002/anie.201004525. ISSN 1521-3773. PMID 21031385.
  11. ^ Ren, Xiaoyu; Du, Haifeng (2016-01-15). "Chiral Frustrated Lewis Pairs Catalyzed Highly Enantioselective Hydrosilylations of 1,2-Dicarbonyl Compounds". Journal of the American Chemical Society. 138 (3): 810–813. doi:10.1021/jacs.5b13104. ISSN 0002-7863. PMID 26750998.
  12. ^ Chernichenko, Konstantin; Madarász, Ádám; Pápai, Imre; Nieger, Martin; Leskelä, Markku; Repo, Timo (2013). "A frustrated-Lewis-pair approach to catalytic reduction of alkynes to cis-alkenes" (PDF). Nature Chemistry. 5 (8): 718–723. Bibcode:2013NatCh...5..718C. doi:10.1038/nchem.1693. PMID 23881505. S2CID 22474399. 
  13. ^ Wech, Felix; Hasenbeck, Max; Gellrich, Urs (2020-09-18). "Semihydrogenation of Alkynes Catalyzed by a Pyridone Borane Complex: Frustrated Lewis Pair Reactivity and Boron–Ligand Cooperation in Concert". Chemistry – A European Journal. 26 (59): 13445–13450. doi:10.1002/chem.202001276. ISSN 0947-6539. PMC 7693047. PMID 32242988.
  14. ^ Gellrich, Urs (2018). "Reversible Hydrogen Activation by a Pyridonate Borane Complex: Combining Frustrated Lewis Pair Reactivity with Boron-Ligand Cooperation". Angewandte Chemie International Edition. 57 (17): 4779–4782. doi:10.1002/anie.201713119. ISSN 1521-3773. PMID 29436754.
  15. ^ Légaré, Marc A.; Courtmanche, Marc A.; Rochette, Étienne; Fontaine, Frédéric G. (2015-07-30). "Metal-free catalytic C-H bond activation and borylation of heteroarenes". Science. 349 (6247): 513–516. Bibcode:2015Sci...349..513L. doi:10.1126/science.aab3591. hdl:20.500.11794/30087. ISSN 0036-8075. PMID 26228143. S2CID 206638394. 
  16. ^ Légaré Lavergne, Julien; Jayaraman, Arumugam; Misal Castro, Luis C.; Rochette, Étienne; Fontaine, Frédéric-Georges (2017-10-06). "Metal-Free Borylation of Heteroarenes Using Ambiphilic Aminoboranes: On the Importance of Sterics in Frustrated Lewis Pair C–H Bond Activation". Journal of the American Chemical Society. 139 (41): 14714–14723. doi:10.1021/jacs.7b08143. hdl:20.500.11794/30144. ISSN 0002-7863. PMID 28901757.
  17. ^ Jayaraman, Arumugam; Misal Castro, Luis C.; Desrosiers, Vincent; Fontaine, Frédéric-Georges (2018). "Metal-free borylative dearomatization of indoles: exploring the divergent reactivity of aminoborane C–H borylation catalysts". Chemical Science. 9 (22): 5057–5063. doi:10.1039/c8sc01093e. ISSN 2041-6520. PMC 5994747. PMID 29938036.
  18. ^ Rochette, Étienne; Boutin, Hugo; Fontaine, Frédéric-Georges (2017-06-30). "Frustrated Lewis Pair Catalyzed S–H Bond Borylation". Organometallics. 36 (15): 2870–2876. doi:10.1021/acs.organomet.7b00346. hdl:20.500.11794/30088. ISSN 0276-7333.
  19. ^ a b c d Mömming, Cornelia M.; Otten, Edwin; Kehr, Gerald; Fröhlich, Roland; Grimme, Stefan; Stephan, Douglas W.; Erker, Gerhard (2009-08-24). "Reversible Metal-Free Carbon Dioxide Binding by Frustrated Lewis Pairs" (PDF). Angewandte Chemie International Edition. 48 (36): 6643–6646. doi:10.1002/anie.200901636. ISSN 1433-7851. PMID 19569151. S2CID 28050646.
  20. ^ Stephan, Douglas W.; Erker, Gerhard (2015-05-14). "Frustrated Lewis Pair Chemistry: Development and Perspectives". Angewandte Chemie International Edition. 54 (22): 6400–6441. doi:10.1002/anie.201409800. ISSN 1433-7851. PMID 25974714.
  21. ^ Abolhasani, Milad; Günther, Axel; Kumacheva, Eugenia (2014-06-24). "Microfluidic Studies of Carbon Dioxide". Angewandte Chemie International Edition. 53 (31): 7992–8002. doi:10.1002/anie.201403719. ISSN 1433-7851. PMID 24961230.

January 01, 1970
frustrated, lewis, pair, frustrated, lewis, pair, compound, mixture, containing, lewis, acid, lewis, base, that, because, steric, hindrance, cannot, combine, form, classical, adduct, many, kinds, flps, have, been, devised, many, simple, substrates, exhibit, ac. A frustrated Lewis pair FLP is a compound or mixture containing a Lewis acid and a Lewis base that because of steric hindrance cannot combine to form a classical adduct 1 Many kinds of FLPs have been devised and many simple substrates exhibit activation 2 3 The discovery that some FLPs split H2 4 triggered a rapid growth of research into FLPs Because of their unquenched reactivity such systems are reactive toward substrates that can undergo heterolysis For example many FLPs split hydrogen molecules Thus a mixture of tricyclohexylphosphine PCy3 and tris pentafluorophenyl borane reacts with hydrogen to give the respective phosphonium and borate ions PCy 3 B C 6 F 5 3 H 2 HPCy 3 HB C 6 F 5 3 displaystyle ce PCy3 B C6F5 3 H2 gt HPCy3 HB C6F5 3 This reactivity has been exploited to produce FLPs which catalyse hydrogenation reactions 5 Contents 1 Small molecule activation 1 1 Hydrogen 1 2 Mechanism of dihydrogen activation by FLP 1 3 Other small molecule substrates 2 Use in catalysis 2 1 Imine nitrile and aziridine hydrogenation 2 2 Enantioselective imine hydrogenation 2 3 Asymmetric hydrosilylations 2 4 Alkyne hydrogenation 2 5 Borylation 3 Carbon capture 4 ReferencesSmall molecule activation editFrustrated Lewis pairs have been shown to activate many small molecules either by inducing heterolysis or by coordination Hydrogen edit The discovery that some FLPs are able to split and therefore activate H2 4 triggered a rapid growth of research into this area The activation and therefore use of H2 is important for many chemical and biological transformations Using FLPs to liberate H2 is metal free this is beneficial due to the cost and limited supply of some transition metals commonly used to activate H2 Ni Pd Pt 6 FLP systems are reactive toward substrates that can undergo heterolysis e g hydrogen due to the unquenched reactivity of such systems For example it has been previously shown that a mixture of tricyclohexylphosphine PCy3 and tris pentafluorophenyl borane reacts with H2 to give the respective phosphonium and borate ions PCy 3 B C 6 F 5 3 H 2 HPCy 3 HB C 6 F 5 3 displaystyle ce PCy3 B C6F5 3 H2 gt HPCy3 HB C6F5 3 nbsp In this reaction PCy3 the Lewis base and B C6F5 3 the Lewis acid cannot form an adduct due to the steric hindrance from the bulky cyclohexyl and pentafluorophenyl groups The proton on the phosphorus and hydride from the borate are now activated and can subsequently be delivered to an organic substrate resulting in hydrogenation Mechanism of dihydrogen activation by FLP edit The mechanism for the activation of H2 by FLPs has been discussed for both the intermolecular and intramolecular cases Intermolecular FLPs are where the Lewis base is a separate molecule to the Lewis acid it is thought that these individual molecules interact through secondary London dispersion interactions to bring the Lewis base and acid together a pre organisational effect where small molecules may then interact with the FLPs The experimental evidence for this type of interaction at the molecular level is unclear However there is supporting evidence for this type of interaction based on computational density functional theory studies Intramolecular FLPs are where the Lewis acid and Lewis base are combined in one molecule by a covalent linker Despite the improved pre organisational effects rigid intramolecular FLP frameworks are thought to have a reduced reactivity to small molecules due to a reduction in flexibility Other small molecule substrates edit FLPs are also reactive toward many unsaturated substrates beyond H2 Some FLPs react with CO2 specifically in the deoxygenative reduction of CO2 to methane 7 Ethene also reacts with FLPs 8 PCy 3 B C 6 F 5 3 C 2 H 4 Cy 3 P CH 2 CH 2 B C 6 F 5 3 displaystyle ce PCy3 B C6F5 3 C2H4 gt Cy3P CH2CH2B C6F5 3 nbsp For acid base pairs to behave both nucleophilically and electrophilically at the same time offers a method for the ring opening of cyclic ethers such as THF 2 5 dihydrofuran coumaran and dioxane 9 Use in catalysis editImine nitrile and aziridine hydrogenation edit nbsp Catalytic cycle for reduction of imine to an amine using an FLP Reduction of imines nitriles and aziridines to primary and secondary amines traditionally is effected by metal hydride reagents e g lithium aluminium hydride and sodium cyanoborohydride Hydrogenations of these unsaturated substrates can be effected by metal catalyzed reactions Metal free catalytic hydrogenation was carried out using the phosphonium borate catalyst R2PH C6F4 BH C6F5 2 R 2 4 6 Me3C6H2 1 This type of metal free hydrogenation has the potential to replace high cost metal catalyst The mechanism of imine reduction is proposed to involve protonation at nitrogen giving the iminium salt The basicity of the nitrogen centre determines the rate of reaction More electron rich imines reduce at faster rates than electron poor imines The resulting iminium center undergoes nucleophilic attack by the borohydride anion to form the amine Small amines bind to the borane quenching further reactions This problem can be overcome using various methods 1 Application of elevated temperatures 2 Using sterically bulky imine substituents 3 Protecting the imine with the B C6F5 3group which also serves as a Lewis acid promoter 10 Enantioselective imine hydrogenation edit A chiral boronate Lewis acid derived from 1R camphor forms a frustrated Lewis pair with tBu3P which is isolable as a salt This FLP catalyses the enantioselective hydrogenation of some aryl imines in high yield but modest ee up to 83 nbsp Asymmetric imine hydrogenation by an FLP Although conceptually interesting the protocol suffers from lack of generality It was found that increasing steric bulk of the imine substituents lead to decreased yield and ee of the amine product methoxy substituted imines exhibit superior yield and ee s 10 Asymmetric hydrosilylations edit Frustrated Lewis pairs of chiral alkenylboranes and phosphines are beneficial for asymmetric Piers type hydrosilylations of 1 2 dicarbonyl compounds and alpha keto esters giving high yield and enantioselectivity However in comparison to conventional Piers type hydrosilyations asymmetric Piers type hydrosilylations are not as well developed In the following example the chiral alkenylborane is formed in situ from a chiral diyne and the HB C6F5 2 Heterolytic cleavage of the Si H bond from PhMe2SiH by the FLP catalyst forms a silylium and hydridoborate ionic complex 11 nbsp Asymmetric hydrosilylation of a diketone by an FLP Alkyne hydrogenation edit Metal free hydrogenation of unactivated internal alkynes to cis alkenes is readily achieved using FLP based catalysts 12 The condition for this reaction were relatively mild utilising 2 bar of H2 In terms of mechanism the alkyne material is first hydroborated and then the resulting vinylborane based FLP can then activate dihydrogen A protodeborylation step releases the cis alkene product which is obtained due to the syn hydroborylation process and regenerating the catalyst While active for alkyne hydrogenation the FLP based catalysts do not however facilitate the hydrogenation of alkenes to alkanes The reaction is a syn hydroboration and as a result a high cis selectivity is observed At the final stage of the catalytic cycle the C6F5 group is cleaved more easily than an alkyl group causing catalyst degradation rather than alkane release The catalytic cycle has three steps Substrate binding the hydroboration of alkyne H2 cleavage with vinylborane followed by intramolecular protodeborylation of vinyl substituent recovering N N Dimethyl 2 pentafluorophenyl boryl aniline Release of the cis alkene nbsp Binding of terminal alkyne to the FLP catalyst With internal alkynes a competitive reaction occurs where the proton bound to the nitrogen can be added to the fluorobenzenes Therefore this addition does not proceed that much the formation of the alkene seems favoured But terminal alkynes do not bind to the boron through hydroboration but rather through C H activation Thus the addition of the proton to the alkyne will result in the initial terminal alkyne Hence this hydrogenation process is not suitable to terminal alkynes and will only give pentafluorobenzene The metal free hydrogenation of terminal alkynes to the respective alkenes was recently achieved using a pyridone borane based system 13 This system activates hydrogen readily at room temperature yielding a pyridone borane complex 14 Dissociation of this complex allows hydroboration of an alkyne by the free borane Upon protodeborylation by the free pyridone the cis alkene is generated Hydrogenation of terminal alkynes is possible with this system because the C H activation is reversible and competes with hydrogen activation Borylation edit Amine borane FLPs catalyse the borylation of electron rich aromatic heterocycles Scheme 1 15 The reaction is driven by release of hydrogen via C H activation by the FLP Aromatic borylations are often used in pharmaceutical development particularly due to the abundance low cost and low toxicity of boron compounds compared to noble metals nbsp Scheme 1 Mechanism for borylation catalysed by FLPThe substrate for the reaction has two main requirements strongly linked to the mechanism of borylation First the substrate must be electron rich exemplified by the absence of a reaction with thiophene whereas its more electron rich derivatives methoxythiophene and 3 4 ethylenedioxythiophene can undergo a reaction with the amino borane Furthermore substitution of 1 methylpyrrole which can react with the strongly electron withdrawing tertbutyloxycarbonyl Boc group at the 2 position completely inhibits the reaction The second requirement is for the absence of basic amine groups in the substrate which would otherwise form an unwanted adduct This can be illustrated by the lack of a reaction with pyrrole whereas both 1 methyl and N benzylpyrrole derivatives are able to react Further work by the same authors revealed that simply piperidine as the amine R group as opposed to tetramethylpiperidine pictured above accelerated the rate of reaction Through kinetic and DFT studies the authors proposed that the C H activation step was more facile than with larger substituents 16 Dearomatisation can also be achieved under similar conditions but using N tosyl indoles Syn hyrdoborylated indolines are obtained 17 nbsp Deromatisation of N tosyl indole by HBpin Borylation of S H bonds in thiols by a dehydrogenative process has also been observed Alcohols and amines such as tert Butanol and tert Butylamine form stable products that prevent catalysis due to a strong p bond between the N O atom s lone pair and boron whereas the same is not true for thiols thus allowing for successful catalysis In addition successful borylation of Se H bonds has been achieved In all cases the formation of H2 gas is a strong driving force for the reactions 18 Carbon capture editFLP chemistry is conceptually relevant to carbon capture 19 Both an intermolecular Scheme 1 and intramolecular Scheme 2 FLP consisting of a phosphine and a borane were used to selectively capture and release carbon dioxide When a solution of the FLP was covered by an atmosphere of CO2 at room temperature the FLP CO2 compound immediately precipitated as a white solid 19 20 nbsp Scheme 1 Intermolecular FLP CO2 capture and release Heating the intermolecular FLP CO2 compound in bromobenzene at 80 C under vacuum for 5 hours caused the release of around half of the CO2 and regenerating the two constituent components of the FLP After several more hours of sitting at room temperature under vacuum total release of CO2 and FLP regeneration had occurred 19 nbsp Scheme 2 Intramolecular FLP CO2 capture and release The intramolecular FLP CO2 compound by contrast was stable as a solid at room temperature but fully decomposed at temperatures above 20 C as a solution in dichloromethane releasing CO2 and regenerating the FLP molecule 19 This method of FLP carbon capture can be adapted to work in flow chemistry systems 21 References edit Stephan Douglas W 2008 Frustrated Lewis pairs a concept for new reactivity and catalysis Org Biomol Chem 6 9 1535 1539 doi 10 1039 b802575b PMID 18421382 nbsp Stephan Douglas W Erker Gerhard 2010 Frustrated Lewis Pairs Metal free Hydrogen Activation and More Angewandte Chemie International Edition 49 1 46 76 doi 10 1002 anie 200903708 ISSN 1433 7851 PMID 20025001 nbsp Stephan Douglas W Erker Gerhard 2017 Frustrated Lewis pair chemistry Philosophical Transactions of the Royal Society A Mathematical Physical and Engineering Sciences 375 2101 20170239 Bibcode 2017RSPTA 37570239S doi 10 1098 rsta 2017 0239 ISSN 1364 503X PMC 5540845 PMID 28739971 nbsp a b Welch Gregory C Juan Ronan R San Masuda Jason D Stephan Douglas W 2006 Reversible Metal Free Hydrogen Activation Science 314 5802 1124 1126 Bibcode 2006Sci 314 1124W doi 10 1126 science 1134230 ISSN 0036 8075 PMID 17110572 S2CID 20333088 nbsp 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Complexes Angew Chem Int Ed 5 4 351 171 doi 10 1002 anie 196603511 a b Chen Dianjun Wang Yutian Klankermayer Jurgen 2010 12 03 Enantioselective Hydrogenation with Chiral Frustrated Lewis Pairs Angewandte Chemie International Edition 49 49 9475 9478 doi 10 1002 anie 201004525 ISSN 1521 3773 PMID 21031385 Ren Xiaoyu Du Haifeng 2016 01 15 Chiral Frustrated Lewis Pairs Catalyzed Highly Enantioselective Hydrosilylations of 1 2 Dicarbonyl Compounds Journal of the American Chemical Society 138 3 810 813 doi 10 1021 jacs 5b13104 ISSN 0002 7863 PMID 26750998 Chernichenko Konstantin Madarasz Adam Papai Imre Nieger Martin Leskela Markku Repo Timo 2013 A frustrated Lewis pair approach to catalytic reduction of alkynes to cis alkenes PDF Nature Chemistry 5 8 718 723 Bibcode 2013NatCh 5 718C doi 10 1038 nchem 1693 PMID 23881505 S2CID 22474399 nbsp Wech Felix Hasenbeck Max Gellrich Urs 2020 09 18 Semihydrogenation of Alkynes Catalyzed by a Pyridone Borane Complex Frustrated Lewis Pair Reactivity and Boron Ligand Cooperation in Concert Chemistry A European Journal 26 59 13445 13450 doi 10 1002 chem 202001276 ISSN 0947 6539 PMC 7693047 PMID 32242988 Gellrich Urs 2018 Reversible Hydrogen Activation by a Pyridonate Borane Complex Combining Frustrated Lewis Pair Reactivity with Boron Ligand Cooperation Angewandte Chemie International Edition 57 17 4779 4782 doi 10 1002 anie 201713119 ISSN 1521 3773 PMID 29436754 Legare Marc A Courtmanche Marc A Rochette Etienne Fontaine Frederic G 2015 07 30 Metal free catalytic C H bond activation and borylation of heteroarenes Science 349 6247 513 516 Bibcode 2015Sci 349 513L doi 10 1126 science aab3591 hdl 20 500 11794 30087 ISSN 0036 8075 PMID 26228143 S2CID 206638394 nbsp Legare Lavergne Julien Jayaraman Arumugam Misal Castro Luis C Rochette Etienne Fontaine Frederic Georges 2017 10 06 Metal Free Borylation of Heteroarenes Using Ambiphilic Aminoboranes On the Importance of Sterics in Frustrated Lewis Pair C H Bond Activation Journal of the American Chemical Society 139 41 14714 14723 doi 10 1021 jacs 7b08143 hdl 20 500 11794 30144 ISSN 0002 7863 PMID 28901757 Jayaraman Arumugam Misal Castro Luis C Desrosiers Vincent Fontaine Frederic Georges 2018 Metal free borylative dearomatization of indoles exploring the divergent reactivity of aminoborane C H borylation catalysts Chemical Science 9 22 5057 5063 doi 10 1039 c8sc01093e ISSN 2041 6520 PMC 5994747 PMID 29938036 Rochette Etienne Boutin Hugo Fontaine Frederic Georges 2017 06 30 Frustrated Lewis Pair Catalyzed S H Bond Borylation Organometallics 36 15 2870 2876 doi 10 1021 acs organomet 7b00346 hdl 20 500 11794 30088 ISSN 0276 7333 a b c d Momming Cornelia M Otten Edwin Kehr Gerald Frohlich Roland Grimme Stefan Stephan Douglas W Erker Gerhard 2009 08 24 Reversible Metal Free Carbon Dioxide Binding by Frustrated Lewis Pairs PDF Angewandte Chemie International Edition 48 36 6643 6646 doi 10 1002 anie 200901636 ISSN 1433 7851 PMID 19569151 S2CID 28050646 Stephan Douglas W Erker Gerhard 2015 05 14 Frustrated Lewis Pair Chemistry Development and Perspectives Angewandte Chemie International Edition 54 22 6400 6441 doi 10 1002 anie 201409800 ISSN 1433 7851 PMID 25974714 Abolhasani Milad Gunther Axel Kumacheva Eugenia 2014 06 24 Microfluidic Studies of Carbon Dioxide Angewandte Chemie International Edition 53 31 7992 8002 doi 10 1002 anie 201403719 ISSN 1433 7851 PMID 24961230 Retrieved from https en wikipedia org w index php title Frustrated Lewis pair amp oldid 1204272509, wikipedia, wiki, book, books, library,

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