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Chem.Rev.2008,108,3795–3892 3795 Hydroamination: Direct Addition of Amines to Alkenes and Alkynes Thomas E. Mu¨ller,*,† Kai C. Hultzsch,*,‡,§ Miguel Yus,|,§ Francisco Foubelo,|,§ and Mizuki Tada⊥,§ CATCatalyticCenter,ITMC,RWTHAachen,Worringerweg1,52074Aachen,Germany,DepartmentofChemistryandChemicalBiology,Rutgers University,610TaylorRoad,Piscataway,NJ08854-8087,DepartamentodeQu´ımicaOrga´nica,UniversidaddeAlicante,E-03080Alicante,Spain, andDepartmentofChemistry,GraduateSchoolofScience,TheUniversityofTokyo,Hongo,Bunkyo-ku,Tokyo113-0033,Japan Received January 22, 2008 Contents 4.2.4. Dienes and Trienes 3853 4.3. Nonactivated Alkynes 3855 1. Introduction 3796 4.3.1. Synthesis of N-Heterocycles 3855 2. Hydroamination Reactions Involving Rare-Earth 3798 4.3.2. Synthesis of Complex Molecules in 3856 Metals, Actinides and Alkaline Earth Metals Sequential Reactions 2.1. Mechanistic Aspects 3798 4.4. Hydroamination of Alkenes with Weaker 3857 2.2. Catalysts and Scope of Reaction 3801 Nucleophiles 2.3. Intermolecular Hydroamination Using 3807 4.5. Catalysis in Aqueous Phase and Ionic Liquids 3857 Rare-Earth Metal Catalysts 4.6. Hydroamination Using Homogeneous Zinc 3858 2.4. Post-Metallocene Rare-Earth Metal Based 3811 Catalysts Hydroamination Catalysts 5. Heterogeneous Hydroamination Catalysts and 3859 2.5. Alkaline-Earth Metal Based Hydroamination 3814 Immobilized Early and Late Transition Metal Catalysts Complexes 2.6. Asymmetric Synthesis of Amines Using 3815 5.1. Inorganic Solid Catalysts 3859 Rare-Earth Metal Catalysts 5.2. Metal-Ion Exchanged Zeolites and Clays 3859 2.7. Chiral Rare-Earth Metal Catalysts Based on 3818 5.3. Supported Complexes on Oxide Surfaces 3860 Non-Cyclopentadienyl Ligands 5.4. Polymer-Supported Organolanthanide 3862 2.8. Kinetic Resolution of Chiral Aminoalkenes 3824 Catalysts 3. Group 4/5 Metal Based Catalysts 3824 6. Brønsted Acid Catalyzed Hydroamination of 3862 3.1. Mechanistic Aspects 3824 Alkenes and Alkynes 3.2. Catalysts and Scope of Reaction 3826 6.1. Intermolecular Brønsted Acid Catalyzed 3862 3.3. Applications of Hydroamination Reactions in 3834 Hydroamination of Alkenes and Alkynes Multistep Reaction Sequences 6.2. Intramolecular Brønsted Acid Catalyzed 3864 3.4. Hydroamination of Alkenes 3837 Hydroamination of Alkenes 3.5. Asymmetric Hydroamination Using Group 4 3840 7. Base-Catalyzed Hydroamination of Alkenes and 3865 Metal Catalysts Alkynes 3.6. One-Pot Reaction Sequences Involving 3841 7.1. Base-Catalyzed Hydroamination of Alkenes 3865 Hydroamination Products 7.1.1. Intermolecular Reactions 3865 4. Late Transition Metal Complexes as 3843 7.1.2. Intramolecular Reactions 3869 Homogeneous Hydroamination Catalysts 7.2. Base-Catalyzed Hydroamination of Alkynes 3871 4.1. Mechanistic Aspects 3844 8. Amino- and Amidomercuration-Demercuration of 3871 4.1.1. Nucleophilic Attack on Coordinated 3844 Alkenes and Alkynes Alkene/Alkyne 8.1. Aminomercuration-Demercuration of Alkenes 3872 4.1.2. Nucleophilic Attack on Allylic Complexes 3846 8.1.1. Intramolecular Reactions 3872 4.1.3. Insertion into the M-H Bond of Metal 3850 8.1.2. Intermolecular Reactions 3873 Hydrides 8.2. Aminomercuration-Demercuration of Alkynes 3875 4.1.4. Oxidative Addition 3850 8.3. Amidomercuration-Demercuration of Alkenes 3875 4.2. Catalysts and Scope of Reaction 3852 8.3.1. Intramolecular Reactions 3875 4.2.1. Hydroamination of Ethene 3852 8.3.2. Intermolecular Reactions 3877 4.2.2. Higher Alkenes 3853 8.4. OtherAminomercuration-Demercuration 3877 4.2.3. Enantioselective Hydroamination with Late 3853 Reactions Transition Metals 8.4.1. Sulfonamidomercuration Reactions 3878 *To whom correspondence should be addressed. Phone: +49 241 80 28594. Fax: +49 241 80 22593. E-mail: Thomas.Mueller@ 8.4.2. Phosphoramidomercuration Reactions 3878 catalyticcenter.rwth-aachen.de. 8.4.3. Azidomercuration Reactions 3878 †RWTHAachen. 8.4.4. Acetamidomercuration Reactions Using 3878 ‡RutgersUniversity. |UniversidaddeAlicante. Acetonitrile ⊥TheUniversityofTokyo. 8.4.5. Nitromercuration Reactions 3878 §E-mailaddresses:[email protected];[email protected];[email protected]; [email protected]. 9. Hydroamination of Alkenes and Alkynes under 3878 Microwave Irradiation 10.1021/cr0306788CCC:$71.00 2008AmericanChemicalSociety PublishedonWeb08/26/2008 3796 ChemicalReviews,2008,Vol.108,No.9 Mülleretal. 9.1. Hydroamination of Alkenes under Microwave 3878 Irradiation 9.2. Hydroamination of Alkynes under Microwave 3879 Irradiation 10. Radical Hydroamination of Alkenes 3880 11. Conclusions 3883 12. Abbreviations 3884 13. Acknowledgments 3884 14. References 3884 1. Introduction Nitrogen-containing compounds, such as amines, enam- ines, and imines, are valuable and commercially important bulk chemicals, specialty chemicals, and pharmaceuticals.1 Amongvarioussynthesisroutes,hydroamination,thedirect ThomasE.MüllerwasborninLandshut,SouthernGermany,in1967.He formation of a new C-N bond by addition of an amine to received his undergraduate education at LMU München and ETH Zürich. HisDiplomarbeitledhimforthefirsttimetotheUnitedKingdom,wherehe an unsaturated CC bond, is of particular significance. The workedwithD.M.L.Goodgame,ICLondon,oncoordinationpolymers.After reaction offers an atom-efficient pathway starting from returning to Switzerland, he received his Diploma in 1991. He joined the readily accessible alkenes and alkynes. While the reaction research group of D. M. P. Mingos at IC London the following year and is thermodynamically feasible under normal conditions receivedhisPh.D.degreein1995forstudiesonpolyaromaticphosphines (slightly exothermic but nearly ergoneutral, because hy- andtheircoordinationtonoblemetals.In1995,hemovedtotheUniversity ofSussextopursuepostdoctoralresearchonfullerenesandnanotubeswith droaminationreactionsareentropicallynegative,inparticular D. M. Walton and Sir H. K. Kroto. After working for two years as Liebig- in the intermolecular variant),2,3 there is a high reaction StipendiatinclosecollaborationwithM.BellerandW.A.HerrmannatTU barrier. The 2 + 2 cycloaddition of N-H across the CC München,hestartedhishabilitationin1998inthegroupofJ.A.Lercher.In bond, which is orbital-forbidden under thermal conditions 2003,hecontinuedatTUMünchenasPrivatdozent.Aftervisitingprofessor butcanbepromotedwithlight,4canbeavoidedbytheuse positions at NUS Singapore (2005) and University of Tokyo (2005), he of a catalyst opening other reaction pathways. However, acceptedthepositionasheadofCATCatalyticCenter,RWTHAachen,in relatively low reaction temperatures (generally e200-300 2007.Hehaspublishedmorethan50papers,mainlyinthefieldofamine °C) are required, because the conversion is limited by the synthesis, mechanistic studies on hydroamination, reductive amination, hydrogenation of nitriles, and catalyst immobilization. His current research reaction equilibrium at higher temperatures.5 interestisfocusedonhomogeneouscatalysiswithtransitionmetalcomplexes, Thehydroaminationofalkenesismoredifficultcompared immobilizationofhomogeneouscatalysts,supportedionicliquidsandmetal with that of alkynes because of the lower reactivity and nanoparticles,multiphasereactions,andbuildingblocksystemsforhetero- electron density of CdC bonds.6 A particular challenge is geneouscatalysis. the reversal of the regiochemistry to obtain the anti- Markovnikov product.7 For good reason, the catalytic anti- Markovnikov addition of H-NR to olefins was listed as 2 oneoftheso-called“TenChallengesforCatalysis”.6During recent years, hydroamination became a widely explored operation in the synthesis of nitrogen heterocycles and complexmolecules.TheMarkovnikovadditionofprotected amines to alkynes is now an established synthesis strategy. Withthedevelopment ofa newgeneration ofcatalysts,the additionofprotectedaminestoalkeneswillquicklybecome a routine reaction. More challenging and, thus, demanding furtherdevelopmenttimeistheconversionofstronglybasic amines, such as ammonia, as well as achieving adequate controloftheregioselectivityinanti-Markovnikovfashion. During the last decade, the interest of the scientific KaiCarstenHultzschstudiedchemistryattheUniversityofMainz,Germany, communityinhydroaminationhasincreasedsharply(Figure andToronto,Canada,from1991to1996.HefinishedisPh.D.in1999under 1).Whilemostlyalkaliandlanthanidemetalcatalystswere the guidance of Jun Okuda in Mainz. After two years as a Feodor Lynen used in early studies, the focus has shifted recently to the postdoctoralfellowinthegroupofRichardR.SchrockatMIT,hebeganhis useofzirconium,titanium,andlatetransitionmetalcatalysts. independentresearchcareerin2001asaDFGEmmyNoetherfellowatthe Mostcatalystsareemployedashomogenouscatalysts,while UniversityofErlangen-Nu¨rnberg,Germany.Afterfinishinghishabilitationin the development of heterogeneous catalysts lags behind. In 2006andvisitingprofessorpositionsinErlangen(2005/2006)andMu¨nster this respect, new strategies for the immobilization of (2007), he accepted his assistant professor position at Rutgers University, Piscataway,NJ,in2007.HeistherecipientoftheWo¨hlerYoungInvestigator homogeneouscatalystswillgainincreasedimportance.Some Award, the ADUC Award for Habilitands, the Lieseberg Award from the examples are described below. UniversityofHeidelberg,andtheEmmy-Noether-Habilitation-Awardfromthe SincethelastcomprehensivereviewbyMu¨llerandBeller UniversityofErlangen-Nu¨rnberg.Hismainareasofinterestsaretransition in 1998,8 review articles covering many aspects of hy- metalcatalyzedstereoselectiveolefinheterofunctionalizationsand(co)polym- erizationofnonpolarandpolarmonomers. droaminationhavebeenpublished(seeTable1).Thearticle ofAlonsoetal.deservesparticularattentionforitsthorough 1998untilJune2007isdiscussed.Thefirstpartofthisreport coverage of the hydroamination of alkynes.9 In the review coversmechanisticaspectsofhydroaminationwithearlyand article presented here, the development of the subject from late transition metal catalysts. The use of heterogeneous Hydroamination ChemicalReviews,2008,Vol.108,No.9 3797 MiguelYuswasborninZaragoza(Spain)in1947andreceivedhisB.Sc. FranciscoFoubelowasborninCarren˜a-Cabrelas(Asturias)in1961.He (1969), M.Sc. (1971), and Ph.D. (1973) degrees from the University of studied chemistry at the University of Oviedo from which he received Zaragoza.AfterspendingtwoyearsasapostdoctoralfellowattheMax B.S.(1984),M.S.(1986),andPh.D.(1989)degrees.Afterapostdoctoral PlanckInstitutfu¨rKohlenforschunginMu¨lheima.d.Ruhr,hereturnedto stay(1989-1991)asaFulbrightfellowatPrincetonUniversity,hemoved SpaintotheUniversityofOviedowherehebecameassociateprofessor totheUniversityofAlicanteandjoinedtheresearchgroupofProfessor in1977,beingpromotedtofullprofessorin1987atthesameuniversity. M.YuswherehebecameAssociateProfessorin1995andFullProfessor In 1988, he moved to a chair in Organic Chemistry at the University of in 2002. Now he is a member of the Department of Organic Chemistry AlicantewhereheiscurrentlytheheadoftheOrganicSynthesisInstitute andtheOrganicSynthesisInstitute(ISO)atthesameuniversity.Hehas (ISO).ProfessorYushasbeenvisitingprofessoratdifferentinstitutions published more than 80 papers and is cofounder of the new chemical anduniversitiessuchasETH-Zentrum,Oxford,Harvard,Uppsala,Tucson, companyMEDALCHEMY,S.L.,asaspin-offoftheUniversityofAlicante. Okayama, Paris, Strasbourg, and Kyoto. He is coauthor of more than Hisresearchinterestsarefocusedonthedevelopmentofnewsynthetic 400papers,mainlyinthefieldofthedevelopmentofnewmethodologies methodologies for the preparation of functionalized organolithium com- involvingorganometallicintermediates,andthreepatents.ProfessorYus poundsfromdifferentprecursorsandtheapplicationoftheseorganome- hasbeenamemberoftheAdvisoryBoardofthejournals,amongothers, tallicintermediatesinorganicsynthesis.Heterofunctionalizationofalkenes Tetrahedron, Tetrahedron Letters, Chemistry Letters, European Journal andthedevelopmentofnewsyntheticmethodsforasymmetricsynthesis ofOrganicChemistry,TrendsinOrganicChemistry,andCurrentChemical relatedtochiralsulfiniminesarerecentinterests. Biology,beingRegionalEditorofLettersinOrganicChemistryalso.He has given more than 100 lectures, most of them abroad, and already supervised43Ph.D.students.Amongothers,hehasreceivedtwicethe JapanSocietyforthePromotionofSciencePrize(Okayama,1999;Kyoto, 2007),theFrench-SpanishPrizeoftheSociete´Franc¸aisedeChimie(Paris, 1999),theC.A.StiefvaterMemorialLectureAward(Nebraska,2001),the Nagase Science and Technology Foundation fellowship (Kyoto, 2003), the Cellchem Lectureship (Sheffield, 2005), the Singenta Lectureship (Basel,2007),andtheFundeun-IberdrolaPrize(Alicante,2007).Hiscurrent researchinterestisfocusedonthepreparationofveryreactivefunction- alized organometallic compounds and their use in synthetic organic chemistry, arene-catalyzed activation of different metals, preparation of newmetal-basedcatalysts,includingmetallicnanoparticles,forhomoge- neousandheterogeneousselectivereactions,andasymmetriccatalysis. In 2002, he and other members of the ISO founded the new chemical companyMEDALCHEMY,S.L.,tocommercializefinechemicals. catalysts,baseandacidcatalyzedhydroamination,andsome MizukiTadawasbornin1979inTokyo(Japan).Shestudiedandreceived stoichiometric reactions, such as the mercuration/demercu- her B.Sc. (2001) and M.Sc. (2003) from the Department of Chemistry, ration protocol are described next. Recently, non-conven- Graduate School of Science at The University of Tokyo. She obtained tionalreactionconditions,inparticulartheuseofmicrowaves herPh.D.in2005fromTheUniversityofTokyounderthesupervisionof and radical chemistry in solution, have been introduced in Prof.YasuhiroIwasawa.Shebecametheassistantprofessorofchemistry hydroamination.Inthefinalpartofthisreport,thescopeof in2004-2007andwaspromotedtoassociateprofessorintheDepartment hydroaminationreactionsasnewandhighlyexcitingaccess ofChemistry,GraduateSchoolofScience,atTheUniversityofTokyoin 2008. Her current research focuses on the catalyst surface, advanced to complex nitrogen-containing molecules is discussed. surfacedesignofsupportedmetal-complexcatalysts,surfacemolecular- Hydroamination in the context of this review article is imprintedcatalystsandinsitutime-resolvedcharacterizationofcatalyst defined as the addition of H-NR across a nonactivated surfaces. 2 alkene or alkyne providing a higher substituted amine or enamine, respectively. When ammonia or a primary amine example, see Scheme 2), telomerization of amines with is reacted with an alkyne, the enamine formed isomerizes butadiene,69–74additionstoalkenesactivatedbyaneighbor- subsequently to the corresponding imine. The addition of amines to allenes and dienes is closely related and will be ing electron-accepting substituent, such as the aza-Michael covered. For the latter reactions, regioselectivity is an reaction20,75–79andtheadditiontoacrylicacidoracrylonitrile important issue, even when symmetric substrates are used, derivatives,80–84 oxidative amination using molecular oxy- as1,2and2,1addition,andfordienes,1,4additionprovides gen85 or styrene86 as oxidant, and allylic amination of different products (Scheme 1). 3-alkenyl-carbonates87 are generally not considered in this Relatedreactions,suchasthereactionofnitrogennucleo- review except for cases where it seems appropriate. The philes with cyclopropanes62–67 or cyclopropenes68 (for an hydroamination of slightly activated substrates, such as 3798 ChemicalReviews,2008,Vol.108,No.9 Mülleretal. Scheme1 Scheme2 Scheme3. SimplifiedMechanismforRare-EarthMetal CatalyzedHydroamination/CyclizationofAminoalkenes norbornene, vinylethers, and, in particular, vinylarenes is, however, included. 2. Hydroamination Reactions Involving Rare-Earth Metals, Actinides and Alkaline Earth Metals Rare-earth metal complexes are highly efficient catalysts for intramolecular hydroamination of various C-C unsat- urations such as alkenes, alkynes, allenes, and dienes, but reducedratesareobservedinintermolecularhydroamination processes. Attractive features of rare-earth metal catalysts beensynthesizedforenantioselectivehydroamination.While includeveryhighturnoverfrequenciesandexcellentstereo- therare-earthmetalcatalystsareveryefficientcatalystsfor selectivities,renderingthismethodologyapplicabletoconcise hydroamination,theirsensitivitytooxygenandmoisturehave synthesisofnaturallyoccurringalkaloidsandotherpolycyclic limited their use in many applications. azacycles.Thegeneralhydroaminationmechanisminvolves Aswillbediscussedinchapter3,recentdevelopmentsin rate-limiting C-C multiple bond insertion into the Ln-N catalytically active group 4 metal complexes have resulted bond, followed by rapid protonolysis by other amine in significant improvements in their reactivity towards substrates.ThegroundbreakingstudiesinthegroupsofT.J. aminoalkenes,andthefirsthighlyenantioselectiveexamples Marks,30 some of which were summarized in the 1998 using chiral catalysts have been reported. Similar to rare- review,8 and later G. A. Molander have utilized predomi- earth metals, group 4 metal complexes are very oxophilic, nantly lanthanocene complexes. Since then, sterically less whichreducestheirfunctionalgrouptolerance.Nevertheless, encumberedliganddesigns(e.g.,constrained-geometrycom- group 4 metal catalysts have been applied to the synthesis plexes,post-metallocenes)havebeendevelopedtoimprove of a range of biologically active molecules of relevance to reaction rates and alter catalyst stereoselectivities. Metal- pharmaceutical industry. loceneandnon-metallocenechirallanthanidecomplexeshave 2.1. Mechanistic Aspects The mechanism of the hydroamination/cyclization30,88,89 proceedsthrougharare-earthmetalamidospecies,whichis formeduponprotonolysisofarare-earthmetalamidooralkyl bond in the precatalyst (Scheme 3). The first step of the catalyticcycleinvolvesinsertionoftheolefinintotherare- earth metal amido bond with a seven-membered chair-like transition state (for n ) 1). The roughly thermoneutral insertion step88 is usually rate-determining, giving rise to a zero-order rate dependence on substrate concentration and first-orderratedependenceoncatalystconcentration(eq1). d[subst] rate)- )k[subst]0[catalyst]1 (1) dt The resting state of lanthanocene catalysts is an amido Figure1. Numberofarticlespublishedonhydroamination. amine species of the general form Cp* Ln(NHR)(NH R) 2 2 Hydroamination ChemicalReviews,2008,Vol.108,No.9 3799 Table1. ReviewArticlesonHydroaminationReactionsa substrates no.of covering ref authors citedrefs until topicsinorderofimportance alkenes alkynes dienes allenes 10 Andrea,Eisen 118 09/2007 thoriumanduraniumcatalysts X X 11 Aillaud,Collin,Hannedouche,Schulz 61 07/2007 asymmetrichydroamination X X X X 12 Brunet,Chu,Rodriguez-Zubiri 122 04/2007 platinumcatalyzedhydroamination X promotedwithhalideanions 13 Lee,Schafer 135 04/2007 groupIVamidatecomplexes X X X 14 Severin,Doye 40 10/2006 recentdevelopmentsin X hydroaminationofalkynes 15 Hunt 169 01/2007 computationalaspectsofhydroamination X X X X withorganolanthanides 16 Liu,Bender,Han,Widenhoefer 78 10/2006 platinumcatalysts X 17 Widenhoefer,Han 116 05/2006 goldcatalysts X X X X 18 Mitsudo,Ura,Kondo 94 02/2006 zerovalentrucomplexes X 19 Rowlands 55 2006 freeradicalreactions X 20 Hii 30 2006 palladiumcatalysts,enantioselective 21,22 Gottfriedsen,Edelmann 308,285 05/2005 chemistryoforganolanthanidesandactinides X X 23 Hultzsch 53 12/2004 rare-earthandgroupIVmetalcatalysts X 24 Doye 93 12/2004 titaniummetallocenecatalysts X 25 Hultzsch,Gribkov,Hampel 87 11/2004 non-metallocenesrare-earthcatalysts, X enantioselective 26 Odom 92 10/2004 titaniumdiamidecomplexes X 27 Rosenthal,Burlakov,Arndt,Baumann, 76 09/2004 zirconiumandtitanium X Spannenberg,Shur metallocenecomplexes 28 Arndt,Okuda 94 08/2004 cationicalkylcomplexesofrare-earthmetals X 29 Hultzsch 120 08/2004 asymmetrichydroamination X X X X 30 Hong,Marks 24 02/2004 organolanthanidecatalysts X X X X 31 Brunet,Poli 16 2004 selectedaspectsofRu,Pdcatalysis X 32 Beller,Tillack,Seayad 118 2004 greenaspects X X 33 Barbaro,Bianchini,Giambastiani, 148 11/2003 enantioselectivehydroaminationwith X Parisel iridiumandnickelcomplexes 9 Alonso,Beletskaya,Yus 456 10/2003 comprehensivereviewonalkynes X 34 Buffat 148 08/2003 synthesisofpiperidines X X 35 Hartwig 40 07/2003 palladium,nickel,andrhodiumcatalysts X X 36 Leung 57 07/2003 vinyl-andalkynylphosphines X X 37 Beller,Seayad,Tillack,Jiao 34 06/2003 regioselectivity X X 38 Roesky,Mu¨ller 24 04/2003 enantioselectivehydroamination X X 39 Salzer 55 11/2002 arene(tricarbonyl)chromiumcomplexes X 40 Bytschkov,Doye 44 08/2002 groupIVmetalcomplexes X X 41 Pohlki,Doye 38 07/2002 recentresultsin2002 X 42 Gibson,Ibrahim 67 02/2002 asymmetriccatalysisusing[(arene)Cr(CO)] X 3 complexesasligands 43 Duncan,Bergman 55 2002 imidozirconocenecomplexes 44 Seayad,Tillack,Hartung,Beller 142 2002 basecatalyzedhydroaminationreactions X X X 45 Taube 22 2002 microreview 46 Molander,Romero 130 09/2001 lanthanocenecatalysts X X X 47 Nobis,Drie(cid:1)en-Ho¨lscher 26 05/2001 recentresultsin2002 X X X 48,49 Mu¨ller 55,56 02/2001 homogeneousandheterogeneous X X X catalysts,respectively 50 Siebeneicher,Doye 37 11/2000 chemistryof[CpTiMe] X 2 2 51 Togni,Bieler,Burckhardt,Kollner, 21 07/1999 iridiumcatalysts,protectedamines X Pioda,Schneider,Schnyder 52 Haak,Doye 37 1999 microreview X X 53 Yamamoto,Radhakrishnan 36 08/1998 PdIIcatalyzedadditionofpronucleophiles X 54 Eisen,Straub,Haskel 46 1998 organoactinidecatalyzedtelomerisation X 55 Johannsen,Jørgensen 165 1998 synthesisofallylicamines X 56 Merola 93 1997 iridiumcatalysts 8 Mu¨ller,Beller 239 07/1997 comprehensivereview,mechanisticaspects X X X X 57 Brunet 56 1997 rhodiumcatalyst,hydroamination X withlithiumphenylamide 58 Simpson,Cole-Hamilton 200 01/1996 reactionscatalyzedwithrhodium X trialkylphosphinecomplexes 59 Anwander 115 1996 homogeneouslanthanidecatalysts 60 Taube 21 1996 microreview 61 Marks,Gagne,Nolan,Schock, 49 1989 thermodynamicaspects X Seyam,Stern aImportantarticleswithparticularfocusonhydroaminationaremarkedinbold. based on spectroscopic and crystallographic evidence.88 inhibition.Forexample,stericallyopenansa-lanthanocenes However, lanthanocene catalysts are only slightly inhibited and constrained-geometry catalysts have displayed product bythepresenceofexternalbases,suchasn-propylamineor inhibition (apparent first-order kinetics),88,90–92 while self- THF,butdependingonthestericcongestionaroundthemetal accelerationhasbeenobservedinthecyclizationofamino- center and substrate structure, significant deviations from hexene derivatives using sterically more encumbered cata- zero-orderratekineticshavebeenobserved,andthesehave lysts.91 Metal centers in non-metallocene-type catalysts are been attributed to substrate self-inhibition and product often more accessible to amine bases, as evidenced by 3800 ChemicalReviews,2008,Vol.108,No.9 Mülleretal. Scheme4. ProposedAmineParticipationintheOlefin andreleasingtheheterocyclicproduct.Surprisingly,kinetic InsertionTransitionStateoftheHydroamination/ studiesusingN-deuteratedaminoalkenes88b,95haverevealed Cyclizationa alargeprimarykineticisotopeeffectwithk /k intherange H D of2.3-5.2,althoughnoN-Hbondbreakingisinvolvedin the rate-determining olefin insertion step. A plausible explanation involves partial proton transfer from a coordi- natedaminetotheR-carboninthefour-memberedinsertion step (Scheme 4). However, some experimental data, in aRR′NH)substrateorhydroaminationproduct. particular the observation of sequential hydroamination/ bicyclizationsequences(Videinfra),isinconflictwiththese coordinating solvents (e.g., THF) found in the precatalysts, findings, because the latter requires a finite lifetime for the andkineticdeviationshavebeenobservedmorefrequently.93–95 rare-earth metal alkyl intermediate. Coordinativesaturationofthemetalcenterthroughstrong From a thermodynamic point of view, rare-earth metal aminebindingresultsinreducedelectrophilicityandtherefore catalyzedhydroamination/cyclizationofaminoalkenesdiffers reducedcatalyticactivity.Therefore,ifbindingofeitherthe significantly from reactions involving aminoalkynes, ami- substrate (Ksubst) or the product azacycle (Kprod) to the noallenes, and conjugated aminodienes. For terminal ami- catalyst is substantial, the rate of the reaction is reduced to noalkenes, the olefin insertion step of the Ln-amide into the same extent as the reservoir of the more reactive, the carbon-carbon double bond is approximately thermo- coordinatively unsaturated species is diminished with in- neutral, and it is only slightly exothermic for an internal creasing amine (substrate/product) concentration (eq 2). aminoalkenewithan1,2-disubstitutedalkene(Scheme5,step d[subst] k[catalyst] A).88,92Thefollowingprotonolysisoftheprimaryrare-earth rate)- ) dt 1+Ksubst[subst]+Kprod[prod] metal alkyl species is quite exothermic, to a lesser extent also for the secondary rare-earth metal alkyl species. In (2) markedcontrast,insertionofanalkyne,allene,or1,3-diene Inmanyinstancesthebindingconstantsofthesubstrate(e.g., intotheLn-amidebondisveryexothermic(Scheme5,steps primary aminoalkene) and product azacycle are similar or B-D).91,96,97Protonolysisoftheresultingvinyl(incaseof virtuallyidentically(Ksubst≈Kprod≡K ),resultinginapparent alkynesandallenes)orη3-allyl(incaseofconjugateddienes) eq zero-orderratedependenceonsubstrateconcentration,because rare-earth metal species is about thermoneutral (for the the overall amine concentration remains constant throughout vinylic species) to slightly endothermic (for the allylic thereaction(eq3;[L])[subst]+[prod]). species)duetothesignificantstabilizationofthesespecies. Despite these significant differences, it was proposed that d[subst] k[catalyst] rate)- ) (3) in all these cyclization reactions the insertion step is dt 1+K [L] eq rate-determining,89a,bfollowedbyarapidprotonolysisstep. The rare-earth metal alkyl species formed in the insertion However, recent DFT analyses of the catalytic cycle of the process is prone to rapid protonolysis with a second amine rare-earth metal catalyzed hydroamination of dienes and molecule, regenerating the rare-earth metal amido species allenessuggestthatprotonolysisoftherare-earthmetalη3- Scheme5. ThermodynamicsoftheElementaryStepsinRare-EarthMetalCatalyzedHydroamination/Cyclization88,91,92,96,97 Hydroamination ChemicalReviews,2008,Vol.108,No.9 3801 Table2. ComparisonofActivationParametersforHydroamination/CylizationReactions. Scheme6. 5-endo-dig-Hydroamination/Cyclizationofa Scheme7. Lanthanocene-CatalyzedHydroamination/ Homopropargylamine.100 CyclizationofAminoalkenes88 allylspecies(inhydroaminationofdienes)orvinylicspecies (inhydroaminationofallenes)istherate-limitingstep.89c–e Theactivationparametersassociatedwiththerate-determin- ingstepofthecatalyticcycleindicatethatthehydroamination/ Scheme8. Lanthanocene-CatalyzedHydroamination/ cyclizationinvolvesahighlyorderedtransitionstate(Table2). CyclizationofAminoalkynes96 Thehighestenthalpicbarrierisobservedforthecyclizationof theinternalaminoalkenes,originatingfromstericandelectro- staticrepulsionofthe1,2-disubstitutedolefin. Quitegenerally,rare-earthmetalcatalyzedcyclizationsof aminoalkenes, aminoalkynes, and aminodienes produce exclusivelytheexocyclichydroaminationproducts.However, cyclizationofhomopropargylaminesleadstotheformation of the endocyclic enamine product via a 5-endo-dig- hydroamination/cyclization (Scheme 6),100 most likely due to steric strain in the four-membered ring exocyclic hy- increasingionicradiusoftherare-earthmetalion(Table3, droaminationproduct.Interestingly,the5-endo-digcycliza- entries 1-3 and 7-9).88 Better accessibility of the metal tionisevenpreferredinthepresenceofanolefingroupthat center also results in increased rates of cyclization, as would lead to a 6-exo hydroamination product. observable in the tied-back ansa-lanthanocene precatalysts Initialstudiesonintermolecularhydroaminationofalkynes Me Si(C Me ) LnE(SiMe ) (2a,b-Ln; E ) CH (a), N (b)) withprimaryamines101suggestedfororganoactinidecatalysts 2 5 4 2 3 2 incomparisontothestericallymorehinderedpermethyllan- amechanismcloselyrelatedtothatfoundforneutralgroup thanocenesCp* LnE(SiMe ) (1a,b-Ln;E)CH(a),N(b)) 4 metal catalysts (Vide infra), involving a [2 + 2] cycload- (Figure 2 and T2able 3, ent3rie2s 3-6). A further increase in dition pathway proceeding via reactive L AndNR imido 2 catalystactivitywasobservedwhenstericallymoreopenand species. This proposal was put forth based on kinetic and less electron-donating constrained-geometry catalysts structuralevidence.101However,theobservationofactinide- catalyzed hydroamination of an alkyne with a secondary amine,102aswellashydroamination/cyclizationreactionsof primary and secondary aminoalkenes,103 provide strong evidencethatasecondmechanisticpathwaymustbeopera- tive.Thereactionproceedsviainsertionoftheolefinicdouble bond into an actinide-amide σ-bond in a polar and highly orderedfour-centeredinsertiontransitionstate,analogousto the lanthanide-mediated reaction. 2.2. Catalysts and Scope of Reaction As reviewed earlier,8,30 rare-earth metal catalysts are among the most active and most versatile catalysts for the intramolecular hydroamination of (terminal) aminoalkenes (Scheme7)88,104andaminoalkynes(Scheme8),96producing pyrrolidines, piperidines, indolines, and azepanes. The rate of cyclization generally decreases with increasing ring size (5 > 6 . 7).88,96 Figure 2. Dependence of catalytic activity in hydroamination/ Catalyticactivityinrare-earthmetalcatalyzedhydroami- cyclizationofaminoalkenesonstericdemandofthecatalystligand nation/cyclizationofaminoalkenesgenerallyincreaseswith frameworkforrare-earthmetalandactinidecatalysts. 3802 ChemicalReviews,2008,Vol.108,No.9 Mülleretal. Table3. RateDependenceonIonicRadiusandStericDemandoftheAncillaryLigandintheRare-EarthMetalCatalyzedCyclization ofAminoalkenes entry catalyst ionic radius,107 Å T,°C TOF,h-1 ref 1 Cp*LaCH(SiMe) (1a-La) 1.160 25 95 88 2 32 2 Cp*SmCH(SiMe) (1a-Sm) 1.079 60 48 88b 2 32 3 Cp*LuCH(SiMe) (1a-Lu) 0.977 80 <1 88b 2 32 4 MeSi(CMe)LuCH(SiMe) (2a-Lu) 0.977 80 75 88b 2 5 42 32 5 MeSi(CMe)(CH)LuCH(SiMe) 0.977 80 200 88b 2 5 4 5 4 32 6 meso-[(ebi)YbN(SiMe)]a 0.985 25 0.6b 108 32 7 MeSi(CMe)(tBuN)NdN(SiMe) (3b-Nd) 1.109 25 200 105 2 5 4 32 8 MeSi(CMe)(tBuN)SmN(SiMe) (3b-Sm) 1.079 25 181 105 2 5 4 32 9 MeSi(CMe)(tBuN)LuCH(SiMe) (3a-Lu) 0.977 25 90 105 2 5 4 32 10 MeSi(CMe)(tBuN)Th(NMe) (6-Th) 1.09 25 15 103a,b 2 5 4 22 11 MeSi(CMe)(tBuN)U(NMe) (6-U) 1.05 25 2.5 103a,b 2 5 4 22 aebi)ethylene-bis-(η5-indenyl).bEstimatedvalue(2mol%catalyst,70h,79%isolatedyield). Table4. RateDependenceonIonicRadiusandStericDemand oftheAncillaryLigandintheRare-EarthMetalandActinide CatalyzedHydroaminationCyclizationofAminoalkynes ionic TOF, Figure3. Proposedstabilizationoftheolefininsertiontransition entry catalyst radius,107 Å h-1 ref statethroughintramolecularchelation. 1 Cp*LaCH(SiMe) (1a-La) 1.160 135 96b 2 32 2 Cp*NdCH(SiMe) (1a-Nd) 1.109 207 96b Scheme10. LanthanoceneCatalyzedIntramolecular 2 32 3 Cp*2SmCH(SiMe3)2(1a-Nd) 1.079 580 96b Hydroamination/BicyclizationofAminodialkenes 4 Cp*LuCH(SiMe) (1a-Lu) 0.977 711 96b 2 32 5 MeSi(CMe)NdCH(SiMe) 1.109 78 96b 2 5 42 32 (2a-Nd) 6 Cp*UMe (4-U) 1.05 26 103a,b 2 2 7 MeSi(CMe)(tBuN)Th(NR) 1.09 7.8 103a,b 2 5 4 22 (6-Th) 8 MeSi(CMe)(tBuN)U(NR) 1.05 1210 103a,b 2 5 4 22 (6-U) significantly slower and under much more forcing reaction Scheme9 conditions (Vide infra). Interestingly, the reactivity pattern in rare-earth metal catalyzed hydroamination/cyclization reactions of aminoalkynes with respect to ionic radius size andstericdemandoftheancillaryligandfollowstheopposite trend to that observed for aminoalkenes, for example, generally decreasing rates of cyclization with increasing ionicradiusoftherare-earthmetalandmoreopencoordina- tion sphere around the metal (Table 4).96 Me Si(C Me )(tBuN)LnE(SiMe ) (3a,b-Ln; E ) CH (a), 2 5 4 3 2 N(b))wereutilized.105Electroniceffectsalsoplayapivotal Thehydroaminationreactionsusingoxophiliclanthanide role for catalytic activity. Thus, decreased reactivity of a catalystsarebestperformedinnon-polaraliphaticoraromatic constrained-geometry indenyl lutetium complex containing solvents, whereas slight rate depressions are noticeable in an electron-donating pyrrolidinyl substituent was observed polar solvents, such as THF (ktoluene/kTHF ≈ 5).88b Interest- in comparison to 3a-Lu.106 ingly, the ansa-yttrocene 9, Thestereoelectroniccharacteristicsoftheancillaryligand are significantly more pronounced for organoactinide cata- lysts. The constrained-geometry complexes Me Si(C Me )- 2 5 4 (tBuN)An(NR ) (6-An;An)Th,U;NR )NMe ,NMeEt, 2 2 2 2 NEt )103 are highly active hydroamination catalysts for 2 essentiallythesamesetofsubstratesasappliedtolanthanide catalysts. In contrast, the sterically more encumbered and electronically more saturated ansa-actinocenes Me Si(C Me ) AnR (5-An; An ) Th, U; R ) CH SiMe , withanetherfunctionalitytetheredtothesiliconbridge,was 2 5 4 2 2 2 3 CH Ph)orthepermethylactinoceneCp* AnR (4-An)react shown to display increased reactivity (up to 5-fold) in the 2 2 2 rather sluggishly with aminoalkene substrates. cyclizationofaminoalkenesrelativetothenonfunctionalized Cyclizationofaminoalkynescommonlyproceedssignifi- ansa-yttroceneMe Si(C Me ) YCH(SiMe ) (2a-Y),though 2 5 4 2 3 2 cantlyfasterthancyclizationofaminoalkenes.96Furthermore, the effect on diastereoselectivity was minimal to negligible terminal as well as internal alkynes react with comparable (Scheme9).109Itwassuggestedthatthiseffectresultsfrom rates, while internal double bonds in aminoalkenes react a stabilization of the polar olefin insertion transition state Hydroamination ChemicalReviews,2008,Vol.108,No.9 3803 Table5. StereoselectiveRare-EarthMetalCatalyzedHydroamination/BicyclizationofAminodialkenesUsingCp*LnCH(SiMe) (Ln) 2 32 Nd(1a-Nd),Sm(1a-Sm)111 aGeneral conditions: 10 mol % catalyst in CD, 4 d. Substrates were generated in situ from their corresponding hydrochloride salts. bThe 6 6 stereochemistryoftheseproductshasnotbeenreported. Table6. PreparationofTricyclicAromaticAzacyclesthrough through an intramolecular chelation of the tethered donor Rare-EarthMetalMediatedHydroamination/Bicyclization112 group (Figure 3). Hydroamination/bicyclizationofaminodialkenes,amino- dialkynes, and aminoalkeneynes allows facile access to pyrrolizidinesandindolizidinesinatandemC-NandC-C bond-forming process (Scheme 10).110 This process has entry R n m Ln T,°C dr yield,% significant synthetic potential in the synthesis of complex 1 H 1 1 Sm rt <5.5:1b 79 naturally occurring alkaloidal skeletons. An important pre- 2 OMe 1 1 Sm 45-50 4.7:1b 84 requisite for the success of this reaction sequence is a 3 OMe 1 2 Sm 45-50 >50:1b 59a sufficientlifetimeoftherare-earthmetalalkylintermediate 4 H 2 1 Nd 9-rt 1.7:1b 76 5 OMe 2 1 Nd 9-rt 1.4:1b 82 formed in the initial insertion process of the alkene/alkyne 6 H 2 2 Nd rt 26:1c >73 in the Ln-amide bond to permit the carbocyclization step. 7 OMe 2 2 Nd 45-50 16:1c 69 However,thissequenceisinconflictwiththelargeprimary aIsolatedasHClsaltinthepresenceofBHT,butreadilyoxidized kinetic isotope effect observed for primary aminoalkenes, insolution.bStereochemistrynotestablished.cThemajorisomerhas whichsuggestspartialN-Hbondbreakinginthecourseof a 1,3-cis relationship of the two stereocenters according to an X-ray the olefin insertion step (Vide supra). crystallographicanalysis. A more detailed study extended the hydroamination/ bicyclizationmethodologyalsotoquinolizidinesandprobed whentheinitialhydroaminationstepinvolvedformationof theinfluenceofalkylsubstituentsinvariouspositionsofthe a five-membered ring. substrate backbone on the sense and magnitude of diaste- A further extension of this methodology gave access to reoselection.111Whilemethylsubstitutioninthe(cid:1)-position tricyclic (Table 6) and tetracyclic (eq 4) alkaloidal skel- tothesecondaryaminenitrogeneffectedhighstereoselection (Table 5, entries 2, 5, and 6), more remote positions closer to the olefinic group (Table 5, entries 3, 4, 7, and 8) gave poor selectivities. Possibly because of stereoelectronic reasons, the larger neodymium catalyst performed better in the formation of quinolizidines and indolizidines involving six-membered ring formation in the initial hydroamination (4) step,whereasthesmallersamariumionwasmoreeffective 3804 ChemicalReviews,2008,Vol.108,No.9 Mülleretal. Scheme11. ProposedMechanismofLanthanocene-CatalyzedInter-andIntramolecularHydroamination/Tricyclization.110b Table7. Rare-EarthMetalCatalyzedHydroamination/CyclizationofHinderedGem-DisubstitutedAminoalkenesUsing [(CHSiMe)Ln(µ-Me)] (Ln)Nd,Sm) 5 4 32 2 aReactioninneatsolution. etons.112Particularlyhighdiastereoselectivitieswereachieved systems.Remarkably,electron-donatingmethoxysubstitution in the formation of the pyrido[2,1-a]isoindolizine (Table 6, of the aromatic ring did not sequester catalyst activity and entry 3) and benzo[a]quinolizine (Table 6, entry 6) ring selectivity to a significant extent.

Description:
Hydroamination: Direct Addition of Amines to Alkenes and Alkynes. Thomas E. Müller,*,† Kai C gen85 or styrene86 as oxidant, and allylic amination of counterparts and therefore expand the spectrum of available catalysts. The synthetic validity of this approach has been dem- onstrated in the
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