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Buchwald–Hartwig amination

April 11, 2024

In organic chemistry, the Buchwald–Hartwig amination is a chemical reaction for the synthesis of carbon–nitrogen bonds via the palladium-catalyzed coupling reactions of amines with aryl halides.[1] Although Pd-catalyzed C–N couplings were reported as early as 1983, Stephen L. Buchwald and John F. Hartwig have been credited, whose publications between 1994 and the late 2000s established the scope of the transformation. The reaction's synthetic utility stems primarily from the shortcomings of typical methods (nucleophilic substitution, reductive amination, etc.) for the synthesis of aromatic C−N bonds, with most methods suffering from limited substrate scope and functional group tolerance.[2] The development of the Buchwald–Hartwig reaction allowed for the facile synthesis of aryl amines, replacing to an extent harsher methods (the Goldberg reaction, nucleophilic aromatic substitution, etc.) while significantly expanding the repertoire of possible C−N bond formations.[citation needed]

Buchwald-Hartwig amination
Named after Stephen L. Buchwald
John F. Hartwig
Reaction type Coupling reaction
Identifiers
Organic Chemistry Portal buchwald-hartwig-reaction
RSC ontology ID RXNO:0000192

Over the course of its development, several 'generations' of catalyst systems have been developed, with each system allowing greater scope in terms of coupling partners and milder conditions, allowing virtually any amine to be coupled with a wide variety of aryl coupling partners.[citation needed] Because of the ubiquity of aryl C–N bonds in pharmaceuticals and natural products, the reaction has gained wide use in synthetic organic chemistry, with application in many total syntheses and the industrial preparation of numerous pharmaceuticals.

History edit

The first example of a palladium catalyzed C–N cross-coupling reaction was published in 1983 by Migita and coworkers and described a reaction between several aryl bromides and N,N-diethylamino-tributyltin using 1 mol% PdCl2[P(o-tolyl)3]2. Though several aryl bromides were tested, only electronically neutral, sterically unencumbered substrates gave good to excellent yields.[3]

 
Original precedent for Pd-catalyzed C–N coupling

 

 

 

 

(Eq.2)

In 1984, Dale L. Boger and James S. Panek reported an example of Pd(0)-mediated C–N bond formation in the context of their work on the synthesis of lavendamycin which utilized stoichiometric Pd(PPh3)4. Attempts to render the reaction catalytic were unsuccessful.[4]

 
C–N coupling reaction in the total synthesis of lavendamycin

 

 

 

 

(Eq.3)

These reports were virtually uncited for a decade. In February 1994, Hartwig reported a systematic study of the palladium compounds involved in the original Migita paper, concluding that the d10 complex Pd[P(o-Tolyl)3]2 was the active catalyst. Proposed was a catalytic cycle involving oxidative addition of the aryl bromide.[5]

 
hartwig 1994

 

 

 

 

(Eq.4)

In May 1994, Buchwald published an extension of the Migita paper offering two major improvements over the original paper. First, transamination of Bu3SnNEt2 followed by argon purge to remove the volatile diethylamine allowed extension of the methodology to a variety of secondary amines (both cyclic and acyclic) and primary anilines. Secondly, the yield for electron rich and electron poor arenes was improved via minor modifications to the reaction procedure (higher catalyst loading, higher temperature, longer reaction time), although no ortho-substituted aryl groups were included in this publication.[6]

 
Buchwald 1994 publication

 

 

 

 

(Eq.5)

In 1995, back to back studies from each lab showed that the couplings could be conducted with free amines in the presence of a bulky base (NaOtBu in the Buchwald publication, LiHMDS in the Hartwig publication), allowing for organotin-free coupling. Though these improved conditions proceeded at a faster rate, the substrate scope was limited almost entirely to secondary amines due to competitive hydrodehalogenation of the bromoarenes.[7][8] (See Mechanism below)

 
1995 Tin-free coupling conditions

 

 

 

 

(Eq.6)

These results established the so-called "first generation" of Buchwald–Hartwig catalyst systems. The following years saw development of more sophisticated phosphine ligands that allowed extension to a larger variety of amines and aryl groups. Aryl iodides, chlorides, and triflates eventually became suitable substrates, and reactions run with weaker bases at room temperature were developed. These advances are detailed in the Scope section below, and the extension to more complex systems remains an active area of research.

Mechanism edit

The reaction mechanism for this reaction has been demonstrated to proceed through steps similar to those known for palladium catalyzed CC coupling reactions. Steps include oxidative addition of the aryl halide to a Pd(0) species, addition of the amine to the oxidative addition complex, deprotonation followed by reductive elimination. An unproductive side reaction can compete with reductive elimination wherein the amide undergoes beta hydride elimination to yield the hydrodehalogenated arene and an imine product.[9]

Throughout the development of the reaction the group sought to identify reaction intermediates through fundamental mechanistic studies. These studies have revealed a divergent reaction pathways depending on whether monodentate or chelating phosphine ligands are employed in the reaction, and a number of nuanced influences have been revealed (especially concerning the dialkylbiaryl phosphine ligands developed by Buchwald).

The catalytic cycle proceeds as follows:[10][11][12][13]

 
Catalytic cycle for monodentate phosphine ligand systems

 

 

 

 

(Eq.7)

For monodentate ligand systems the monophosphine palladium (0) species is believed to form the palladium (II) species which is in equilibrium with the μ-halogen dimer. The stability of this dimer decreases in the order of X = I > Br > Cl, and is thought to be responsible for the slow reaction of aryl iodides with the first-generation catalyst system. Amine ligation followed by deprotonation by base produces the palladium amide. (Chelating systems have been shown to undergo these two steps in reverse order, with base complexation preceding amide formation.) This key intermediate reductively eliminates to produce the product and regenerate the catalyst. However, a side reaction can occur wherein β-hydride elimination followed by reductive elimination produces the hydrodehalogenated arene and the corresponding imine. Not shown are additional equilibria wherein various intermediates coordinate to additional phosphine ligands at various stages in the catalytic cycle.

For chelating ligands, the monophosphine palladium species is not formed; oxidative addition, amide formation and reductive elimination occur from L2Pd complexes. The Hartwig group found that "reductive elimination can occur from either a four-coordinate bisphosphine or three-coordinate monophosphine arylpalladium amido complex. Eliminations from the three-coordinate compounds are faster. Second, β-hydrogen elimination occurs from a three-coordinate intermediate. Therefore, β-hydrogen elimination occurs slowly from arylpalladium complexes containing chelating phosphines while reductive elimination can still occur from these four-coordinate species."[14]

Application edit

Because of the ubiquity of aryl C–N bonds in pharmaceuticals and natural products, the reaction has gained wide use in synthetic organic chemistry, with application in many total syntheses and the industrial preparation of numerous pharmaceuticals.[22] Industrial applications include α-arylation of carbonyl compounds (such as ketones, esters, amides, aldehydes) and nitriles.[23]

Scope edit

Although the scope of the Buchwald–Hartwig amination has been expanded to include a wide variety of aryl and amine coupling partners, the conditions required for any particular reactants are still largely substrate dependent. Various ligand systems have been developed, each with varying capabilities and limitations, and the choice of conditions requires consideration of the steric and electronic properties of both partners. Detailed below are the substrates and conditions for the major generations of ligand systems. (Not included herein are N-heterocyclic carbene ligands and ligands with wide bite angles such as Xantphos and Spanphos which also have been developed considerably.)[9]

First-generation catalyst system edit

The first generation (Pd[P(o-Tolyl)3]2) catalyst system was found to be effective for the coupling of both cyclic and acyclic secondary amines bearing both alkyl and aryl functionality (though not diarylamines) with a variety of aryl bromides. In general, these conditions were not able to couple primary amines due to competitive hydrodehalogenation of the arene.[7][8]

Aryl iodides were found to be suitable substrates for the intramolecular variant of this reaction,[8] and importantly, could be coupled intermolecularly only if dioxane was used in place of toluene as a solvent, albeit with modest yields.[24]

 

Bidentate phosphine ligands edit

The development of diphenylphosphinobinapthyl (BINAP) and diphenylphosphinoferrocene (DPPF) as ligands for the Buchwald–Hartwig amination provided the first reliable extension to primary amines and allowed efficient coupling of aryl iodides and triflates. (It is believed that the bidentate ligands prevent formation of the palladium iodide dimer after oxidative addition, speeding up the reaction.) These ligands typically produce the coupled products at higher rates and better yields than the first generation of catalysts. The initial reports of these ligands as catalysts were somewhat unexpected given the mechanistic evidence for monoligated complexes serving as the active catalysts in the first-generation system. In fact, the first examples from both labs were published in the same issue of JACS.[25][26][27]

 
Bidentate ligand examples

 

 

 

 

(Eq.8)

The chelation from these ligands is thought to suppress β-hydride elimination by preventing an open coordination site. In fact, α-chiral amines were found not to racemize when chelating ligands were employed, in contrast to the first-generation catalyst system.[28]

 
Chiral retention by chelating phosphine ligands

 

 

 

 

(Eq.9)

Sterically hindered ligands edit

Bulky tri- and di-alkyl phosphine ligands have been shown to be remarkably active catalysts, allowing the coupling of a wide range of amines (primary, secondary, electron withdrawn, heterocyclic, etc.) with aryl chlorides, bromides, iodides, and triflates. Additionally, reactions employing hydroxide, carbonate, and phosphate bases in place of the traditional alkoxide and silylamide bases have been developed. The Buchwald group has developed a wide range of dialkylbiaryl phosphine ligands, while the Hartwig group has focused on ferrocene-derived and trialkyl phosphine ligands.[29][30][31][32][33][34]

 
Bulky ligands in the Buchwald–Hartwig amination

 

 

 

 

(Eq.10)

The dramatic increase in activity seen with these ligands is attributed to their propensity to sterically favor the monoligated palladium species at all stages of the catalytic cycle, dramatically increasing the rate of oxidative addition, amide formation, and reductive elimination. Several of these ligands also seem to enhance the rate of reductive elimination relative to β-hydride elimination via the electron donating arene-palladium interaction.[19][20]

Even electron withdrawn amines and heterocyclic substrates can be coupled under these conditions, despite their tendency to deactivate the palladium catalyst.[35][36]

 
Heteoaryl and amide substrates in the Buchwald–Hartwig amination

 

 

 

 

(Eq.11)

Ammonia equivalents edit

Ammonia remains one of the most challenging coupling partners for Buchwald–Hartwig amination reactions, a problem attributed to its tight binding with palladium complexes. Several strategies have been developed to overcome this based on reagents that serve as ammonia equivalents. The use of a benzophenone imine or silylamide can overcome this limitation, with subsequent hydrolysis furnishing the primary aniline.[37][38][39]

 
Ammonia equivalents in the Buchwald–Hartwig amination

 

 

 

 

(Eq.12)

A catalyst system that can directly couple ammonia using a Josiphos-type ligand.[40]

Variations on C–N couplings: C–O, C–S, and C–C couplings edit

Under conditions similar to those employed for amination, alcohols can be coupled with aryl halides to produce the corresponding aryl ethers. This serves as a convenient replacement for harsher analogues of this process such as the Ullmann condensation.[41][42]

 
Aryl ether synthesis

 

 

 

 

(Eq.13)

Thiols and thiophenols can be coupled with aryl halides under Buchwald-Hartwig-type conditions to produce the corresponding aryl thioethers. Furthermore, mercaptoesters have been employed as H2S-equivalents in order to generate the thiophenol from the corresponding aryl halide.[43]

Enolates and other similar carbon nucleophiles can also be coupled to produce α-aryl ketones, malonates, nitriles, etc. The scope of this transformation is similarly ligand-dependent and a number of systems have been developed.[44] Several enantioselective methods for this process have been developed.[45][46]

 
Enolate coupling as an extension of the Buchwald–Hartwig amination

 

 

 

 

(Eq.14)

Several versions of the reaction employing complexes of copper and nickel rather than palladium have also been developed.[18]

References edit

  1. ^ Forero-Cortés, Paola A.; Haydl, Alexander M. (2 July 2019). "The 25th Anniversary of the Buchwald–Hartwig Amination: Development, Applications, and Outlook". Organic Process Research & Development. 23 (8): 1478–1483. doi:10.1021/acs.oprd.9b00161. S2CID 198366762.
  2. ^ Weygand, Conrad (1972). Hilgetag, G.; Martini, A. (eds.). Weygand/Hilgetag Preparative Organic Chemistry (4th ed.). New York: John Wiley & Sons, Inc. p. 461. ISBN 0471937495.
  3. ^ Kosugi, M.; Kameyama, M.; Migita, T. (1983), "Palladium-Catalyzed Aromatic Amination of Aryl Bromides With n,n-Di-Ethylamino-Tributyltin", Chemistry Letters, 12 (6): 927–928, doi:10.1246/cl.1983.927
  4. ^ Boger, D.L.; Panek, J.S. (1984), "Palladium(0)- mediated [beta]-carboline synthesis: Preparation of the CDE ring system of lavendamycin", Tetrahedron Letters, 25 (30): 3175–3178, doi:10.1016/S0040-4039(01)91001-9
  5. ^ Paul,F.; Patt, J.; Hartwig, J.F. (1994), "Palladium-catalyzed formation of carbon-nitrogen bonds. Reaction intermediates and catalyst improvements in the hetero cross-coupling of aryl halides and tin amides", J. Am. Chem. Soc., 116 (13): 5969–5970, doi:10.1021/ja00092a058
  6. ^ Guram, A.S.; Buchwald, S.L. (1994), "Palladium-Catalyzed Aromatic Aminations with in situ Generated Aminostannanes", J. Am. Chem. Soc., 116 (17): 7901–7902, doi:10.1021/ja00096a059
  7. ^ a b Louie,J.; Hartwig, J.F. (1995), "Palladium-catalyzed synthesis of arylamines from aryl halides. Mechanistic studies lead to coupling in the absence of tin reagents", Tetrahedron Letters, 36 (21): 3609–3612, doi:10.1016/0040-4039(95)00605-C
  8. ^ a b c Guram, A.S.; Rennels, R.A.; Buchwald, S.L. (1995), "A Simple Catalytic Method for the Conversion of Aryl Bromides to Arylamines", Angewandte Chemie International Edition, 34 (12): 1348–1350, doi:10.1002/anie.199513481
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  18. ^ a b Hartwig, J.F. (1998), "Transition Metal Catalyzed Synthesis of Arylamines and Aryl Ethers from Aryl Halides and Triflates: Scope and Mechanism", Angew. Chem. Int. Ed., 37 (15): 2046–2067, doi:10.1002/(sici)1521-3773(19980817)37:15<2046::aid-anie2046>3.0.co;2-l, PMID 29711045
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  22. ^ [15][16][14][9][17][18][19][20][21]
  23. ^ Thomas J. Colacot. The 2010 Nobel Prize in Chemistry: Palladium-Catalysed Cross-Coupling. 2020-06-02 at the Wayback Machine Platinum Metals Rev., 2011, 55, (2) doi:10.1595/147106711X558301
  24. ^ Wolfe, J. P.; Buchwald, S. L. (1996), "Palladium-Catalyzed Amination of Aryl Iodides", J. Org. Chem., 61 (3): 1133–1135, doi:10.1021/jo951844h
  25. ^ Driver, M.S.; Hartwig, J.F. (1996), "A Second-Generation Catalyst for Aryl Halide Amination: Mixed Secondary Amines from Aryl Halides and Primary Amines Catalyzed by (DPPF)PdCl2", J. Am. Chem. Soc., 118 (30): 7217–7218, doi:10.1021/ja960937t
  26. ^ Wolfe, J.P.; Wagaw, S.; Buchwald, S.L. (1996), "An Improved Catalyst System for Aromatic Carbon-Nitrogen Bond Formation: The Possible Involvement of Bis(Phosphine) Palladium Complexes as Key Intermediates", J. Am. Chem. Soc., 118: 7215–7216, doi:10.1021/ja9608306
  27. ^ Louie, J.; Driver, M.S.; Hamann, B.C.; Hartwig, J.F. (1997), "Palladium-Catalyzed Amination of Aryl Triflates and Importance of Triflate Addition Rate", J. Org. Chem., 62 (5): 1268–1273, doi:10.1021/jo961930x
  28. ^ Wagaw, S.; Rennels, R.A.; Buchwald, S.L. (1997), "Palladium-Catalyzed Coupling of Optically Active Amines with Aryl Bromides", J. Am. Chem. Soc., 119 (36): 8451–8458, doi:10.1021/ja971583o
  29. ^ Old, D.W.; Wolfe, J.P.; Buchwald, S.L. (1998), "A Highly Active Catalyst for Palladium-Catalyzed Cross-Coupling Reactions: Room-Temperature Suzuki Couplings and Amination of Unactivated Aryl Chlorides", J. Am. Chem. Soc., 120 (37): 9722–9723, doi:10.1021/ja982250+
  30. ^ Wolfe, J.P.; Buchwald, S.L. (1999), "A Highly Active Catalyst for the Room-Temperature Amination and Suzuki Coupling of Aryl Chlorides", Angew. Chem. Int. Ed., 38 (16): 2413–2416, doi:10.1002/(sici)1521-3773(19990816)38:16<2413::aid-anie2413>3.0.co;2-h, PMID 10458806
  31. ^ Hamann, B.C.; Hartwig, J.F. (1998), "Sterically Hindered Chelating Alkyl Phosphines Provide Large Rate Accelerations in Palladium-Catalyzed Amination of Aryl Iodides, Bromides, and Chlorides, and the First Amination of Aryl Tosylates", J. Am. Chem. Soc., 120 (29): 7369–7370, doi:10.1021/ja981318i
  32. ^ Wolfe, J.P.; Tomori, H.; Sadighi, J.P.; Yin, J.; Buchwald, S.L. (2000), "Simple, Efficient Catalyst System for the Palladium-Catalyzed Amination of Aryl Chlorides, Bromides, and Triflates" (PDF), J. Org. Chem., 65 (4): 1158–1174, doi:10.1021/jo991699y, PMID 10814067
  33. ^ Stambuli, J.P.; Kuwano, R.; Hartwig, J.F. (2002), "Unparalleled Rates for the Activation of Aryl Chlorides and Bromides: Coupling with Amines and Boronic Acids in Minutes at Room Temperature", Angew. Chem. Int. Ed., 41 (24): 4746–4748, doi:10.1002/anie.200290036, PMID 12481346
  34. ^ Huang, X.; Anderson, K.W.; Zim, D.; Jiang, L.; Klapars, A.; Buchwald, S.L. (2003), "Expanding Pd-Catalyzed C–N Bond-Forming Processes: The First Amidation of Aryl Sulfonates, Aqueous Amination, and Complementarity with Cu-Catalyzed Reactions", J. Am. Chem. Soc., 125 (22): 6653–6655, doi:10.1021/ja035483w, PMID 12769573
  35. ^ Anderson, K.W.; Tundel, R.E.; Ikawa, T.; Altman, R.A.; Buchwald, S.L. (2006), "Monodentate Phosphines Provide Highly Active Catalysts for Pd-Catalyzed C–N Bond-Forming Reactions of Heteroaromatic Halides/Amines and (H)N-Heterocycles", Angew. Chem. Int. Ed., 45 (39): 6523–6527, doi:10.1002/anie.200601612, PMID 16955526
  36. ^ Ikawa, T.; Barder, T.E.; Biscoe, M.R.; Buchwald, S.L. (2007), "Pd-Catalyzed Amidations of Aryl Chlorides Using Monodentate Biaryl Phosphine Ligands: A Kinetic, Computational, and Synthetic Investigation", J. Am. Chem. Soc., 129 (43): 13001–13007, doi:10.1021/ja0717414, PMID 17918833
  37. ^ Wolfe, J.P.; Ahman, J.; Sadighi, J.P.; Singer, R.A.; Buchwald, S.L. (1997), "An Ammonia Equivalent for the Palladium-Catalyzed Amination of Aryl Halides and Triflates", Tetrahedron Lett., 38 (36): 6367–6370, doi:10.1016/S0040-4039(97)01465-2
  38. ^ Lee, S.; Jorgensen, M.; Hartwig, J.F. (2001), "Palladium-Catalyzed Synthesis of Arylamines from Aryl Halides and Lithium Bis(trimethylsilyl)amide as an Ammonia Equivalent", Org. Lett., 3 (17): 2729–2732, doi:10.1021/ol016333y, PMID 11506620
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  40. ^ Vo, G.D.; Hartwig, J.F. (2009), "Palladium-Catalyzed Coupling of Ammonia with Aryl Chlorides, Bromides, Iodides, and Sulfonates: A General Method for the Preparation of Primary Arylamines", J. Am. Chem. Soc., 131 (31): 11049–11061, doi:10.1021/ja903049z, PMC 2823124, PMID 19591470
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  42. ^ Torraca, K.E.; Huang, X.; Parrish, C.A.; Buchwald, S.L. (2001), "An Efficient Intermolecular Palladium-Catalyzed Synthesis of Aryl Ethers", J. Am. Chem. Soc., 123 (43): 10770–10771, doi:10.1021/ja016863p, PMID 11674023
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External links edit

  • Buchwald–Hartwig Coupling – Recent Literature
  • Buchwald–Hartwig Chemistry Ian Mangion MacMillan Group Meeting July 30, 2002
  • Buchwald–Hartwig reaction Precious-Metal catalysts from Acros Organics for coupling reactions in organic synthesis

April 11, 2024
buchwald, hartwig, amination, this, article, relies, excessively, references, primary, sources, please, improve, this, article, adding, secondary, tertiary, sources, find, sources, news, newspapers, books, scholar, jstor, august, 2016, learn, when, remove, thi. This article relies excessively on references to primary sources Please improve this article by adding secondary or tertiary sources Find sources Buchwald Hartwig amination news newspapers books scholar JSTOR August 2016 Learn how and when to remove this template message In organic chemistry the Buchwald Hartwig amination is a chemical reaction for the synthesis of carbon nitrogen bonds via the palladium catalyzed coupling reactions of amines with aryl halides 1 Although Pd catalyzed C N couplings were reported as early as 1983 Stephen L Buchwald and John F Hartwig have been credited whose publications between 1994 and the late 2000s established the scope of the transformation The reaction s synthetic utility stems primarily from the shortcomings of typical methods nucleophilic substitution reductive amination etc for the synthesis of aromatic C N bonds with most methods suffering from limited substrate scope and functional group tolerance 2 The development of the Buchwald Hartwig reaction allowed for the facile synthesis of aryl amines replacing to an extent harsher methods the Goldberg reaction nucleophilic aromatic substitution etc while significantly expanding the repertoire of possible C N bond formations citation needed Buchwald Hartwig aminationNamed after Stephen L Buchwald John F HartwigReaction type Coupling reactionIdentifiersOrganic Chemistry Portal buchwald hartwig reactionRSC ontology ID RXNO 0000192 Over the course of its development several generations of catalyst systems have been developed with each system allowing greater scope in terms of coupling partners and milder conditions allowing virtually any amine to be coupled with a wide variety of aryl coupling partners citation needed Because of the ubiquity of aryl C N bonds in pharmaceuticals and natural products the reaction has gained wide use in synthetic organic chemistry with application in many total syntheses and the industrial preparation of numerous pharmaceuticals Contents 1 History 2 Mechanism 3 Application 4 Scope 4 1 First generation catalyst system 4 2 Bidentate phosphine ligands 4 3 Sterically hindered ligands 4 4 Ammonia equivalents 5 Variations on C N couplings C O C S and C C couplings 6 References 7 External linksHistory editThe first example of a palladium catalyzed C N cross coupling reaction was published in 1983 by Migita and coworkers and described a reaction between several aryl bromides and N N diethylamino tributyltin using 1 mol PdCl2 P o tolyl 3 2 Though several aryl bromides were tested only electronically neutral sterically unencumbered substrates gave good to excellent yields 3 nbsp Original precedent for Pd catalyzed C N coupling Eq 2 In 1984 Dale L Boger and James S Panek reported an example of Pd 0 mediated C N bond formation in the context of their work on the synthesis of lavendamycin which utilized stoichiometric Pd PPh3 4 Attempts to render the reaction catalytic were unsuccessful 4 nbsp C N coupling reaction in the total synthesis of lavendamycin Eq 3 These reports were virtually uncited for a decade In February 1994 Hartwig reported a systematic study of the palladium compounds involved in the original Migita paper concluding that the d10 complex Pd P o Tolyl 3 2 was the active catalyst Proposed was a catalytic cycle involving oxidative addition of the aryl bromide 5 nbsp hartwig 1994 Eq 4 In May 1994 Buchwald published an extension of the Migita paper offering two major improvements over the original paper First transamination of Bu3SnNEt2 followed by argon purge to remove the volatile diethylamine allowed extension of the methodology to a variety of secondary amines both cyclic and acyclic and primary anilines Secondly the yield for electron rich and electron poor arenes was improved via minor modifications to the reaction procedure higher catalyst loading higher temperature longer reaction time although no ortho substituted aryl groups were included in this publication 6 nbsp Buchwald 1994 publication Eq 5 In 1995 back to back studies from each lab showed that the couplings could be conducted with free amines in the presence of a bulky base NaOtBu in the Buchwald publication LiHMDS in the Hartwig publication allowing for organotin free coupling Though these improved conditions proceeded at a faster rate the substrate scope was limited almost entirely to secondary amines due to competitive hydrodehalogenation of the bromoarenes 7 8 See Mechanism below nbsp 1995 Tin free coupling conditions Eq 6 These results established the so called first generation of Buchwald Hartwig catalyst systems The following years saw development of more sophisticated phosphine ligands that allowed extension to a larger variety of amines and aryl groups Aryl iodides chlorides and triflates eventually became suitable substrates and reactions run with weaker bases at room temperature were developed These advances are detailed in the Scope section below and the extension to more complex systems remains an active area of research Mechanism editThe reaction mechanism for this reaction has been demonstrated to proceed through steps similar to those known for palladium catalyzed CC coupling reactions Steps include oxidative addition of the aryl halide to a Pd 0 species addition of the amine to the oxidative addition complex deprotonation followed by reductive elimination An unproductive side reaction can compete with reductive elimination wherein the amide undergoes beta hydride elimination to yield the hydrodehalogenated arene and an imine product 9 Throughout the development of the reaction the group sought to identify reaction intermediates through fundamental mechanistic studies These studies have revealed a divergent reaction pathways depending on whether monodentate or chelating phosphine ligands are employed in the reaction and a number of nuanced influences have been revealed especially concerning the dialkylbiaryl phosphine ligands developed by Buchwald The catalytic cycle proceeds as follows 10 11 12 13 nbsp Catalytic cycle for monodentate phosphine ligand systems Eq 7 For monodentate ligand systems the monophosphine palladium 0 species is believed to form the palladium II species which is in equilibrium with the m halogen dimer The stability of this dimer decreases in the order of X I gt Br gt Cl and is thought to be responsible for the slow reaction of aryl iodides with the first generation catalyst system Amine ligation followed by deprotonation by base produces the palladium amide Chelating systems have been shown to undergo these two steps in reverse order with base complexation preceding amide formation This key intermediate reductively eliminates to produce the product and regenerate the catalyst However a side reaction can occur wherein b hydride elimination followed by reductive elimination produces the hydrodehalogenated arene and the corresponding imine Not shown are additional equilibria wherein various intermediates coordinate to additional phosphine ligands at various stages in the catalytic cycle For chelating ligands the monophosphine palladium species is not formed oxidative addition amide formation and reductive elimination occur from L2Pd complexes The Hartwig group found that reductive elimination can occur from either a four coordinate bisphosphine or three coordinate monophosphine arylpalladium amido complex Eliminations from the three coordinate compounds are faster Second b hydrogen elimination occurs from a three coordinate intermediate Therefore b hydrogen elimination occurs slowly from arylpalladium complexes containing chelating phosphines while reductive elimination can still occur from these four coordinate species 14 Application editBecause of the ubiquity of aryl C N bonds in pharmaceuticals and natural products the reaction has gained wide use in synthetic organic chemistry with application in many total syntheses and the industrial preparation of numerous pharmaceuticals 22 Industrial applications include a arylation of carbonyl compounds such as ketones esters amides aldehydes and nitriles 23 Scope editAlthough the scope of the Buchwald Hartwig amination has been expanded to include a wide variety of aryl and amine coupling partners the conditions required for any particular reactants are still largely substrate dependent Various ligand systems have been developed each with varying capabilities and limitations and the choice of conditions requires consideration of the steric and electronic properties of both partners Detailed below are the substrates and conditions for the major generations of ligand systems Not included herein are N heterocyclic carbene ligands and ligands with wide bite angles such as Xantphos and Spanphos which also have been developed considerably 9 First generation catalyst system edit The first generation Pd P o Tolyl 3 2 catalyst system was found to be effective for the coupling of both cyclic and acyclic secondary amines bearing both alkyl and aryl functionality though not diarylamines with a variety of aryl bromides In general these conditions were not able to couple primary amines due to competitive hydrodehalogenation of the arene 7 8 Aryl iodides were found to be suitable substrates for the intramolecular variant of this reaction 8 and importantly could be coupled intermolecularly only if dioxane was used in place of toluene as a solvent albeit with modest yields 24 nbsp Bidentate phosphine ligands edit The development of diphenylphosphinobinapthyl BINAP and diphenylphosphinoferrocene DPPF as ligands for the Buchwald Hartwig amination provided the first reliable extension to primary amines and allowed efficient coupling of aryl iodides and triflates It is believed that the bidentate ligands prevent formation of the palladium iodide dimer after oxidative addition speeding up the reaction These ligands typically produce the coupled products at higher rates and better yields than the first generation of catalysts The initial reports of these ligands as catalysts were somewhat unexpected given the mechanistic evidence for monoligated complexes serving as the active catalysts in the first generation system In fact the first examples from both labs were published in the same issue of JACS 25 26 27 nbsp Bidentate ligand examples Eq 8 The chelation from these ligands is thought to suppress b hydride elimination by preventing an open coordination site In fact a chiral amines were found not to racemize when chelating ligands were employed in contrast to the first generation catalyst system 28 nbsp Chiral retention by chelating phosphine ligands Eq 9 Sterically hindered ligands edit Bulky tri and di alkyl phosphine ligands have been shown to be remarkably active catalysts allowing the coupling of a wide range of amines primary secondary electron withdrawn heterocyclic etc with aryl chlorides bromides iodides and triflates Additionally reactions employing hydroxide carbonate and phosphate bases in place of the traditional alkoxide and silylamide bases have been developed The Buchwald group has developed a wide range of dialkylbiaryl phosphine ligands while the Hartwig group has focused on ferrocene derived and trialkyl phosphine ligands 29 30 31 32 33 34 nbsp Bulky ligands in the Buchwald Hartwig amination Eq 10 The dramatic increase in activity seen with these ligands is attributed to their propensity to sterically favor the monoligated palladium species at all stages of the catalytic cycle dramatically increasing the rate of oxidative addition amide formation and reductive elimination Several of these ligands also seem to enhance the rate of reductive elimination relative to b hydride elimination via the electron donating arene palladium interaction 19 20 Even electron withdrawn amines and heterocyclic substrates can be coupled under these conditions despite their tendency to deactivate the palladium catalyst 35 36 nbsp Heteoaryl and amide substrates in the Buchwald Hartwig amination Eq 11 Ammonia equivalents edit Ammonia remains one of the most challenging coupling partners for Buchwald Hartwig amination reactions a problem attributed to its tight binding with palladium complexes Several strategies have been developed to overcome this based on reagents that serve as ammonia equivalents The use of a benzophenone imine or silylamide can overcome this limitation with subsequent hydrolysis furnishing the primary aniline 37 38 39 nbsp Ammonia equivalents in the Buchwald Hartwig amination Eq 12 A catalyst system that can directly couple ammonia using a Josiphos type ligand 40 Variations on C N couplings C O C S and C C couplings editUnder conditions similar to those employed for amination alcohols can be coupled with aryl halides to produce the corresponding aryl ethers This serves as a convenient replacement for harsher analogues of this process such as the Ullmann condensation 41 42 nbsp Aryl ether synthesis Eq 13 Thiols and thiophenols can be coupled with aryl halides under Buchwald Hartwig type conditions to produce the corresponding aryl thioethers Furthermore mercaptoesters have been employed as H2S equivalents in order to generate the thiophenol from the corresponding aryl halide 43 Enolates and other similar carbon nucleophiles can also be coupled to produce a aryl ketones malonates nitriles etc The scope of this transformation is similarly ligand dependent and a number of systems have been developed 44 Several enantioselective methods for this process have been developed 45 46 nbsp Enolate coupling as an extension of the Buchwald Hartwig amination Eq 14 Several versions of the reaction employing complexes of copper and nickel rather than palladium have also been developed 18 References edit Forero Cortes Paola A Haydl Alexander M 2 July 2019 The 25th Anniversary of the Buchwald Hartwig Amination Development Applications and Outlook Organic Process Research amp Development 23 8 1478 1483 doi 10 1021 acs oprd 9b00161 S2CID 198366762 Weygand Conrad 1972 Hilgetag G Martini A eds Weygand Hilgetag Preparative Organic Chemistry 4th ed New York John Wiley amp Sons Inc p 461 ISBN 0471937495 Kosugi M Kameyama M Migita T 1983 Palladium Catalyzed Aromatic Amination of Aryl Bromides With n n Di Ethylamino Tributyltin Chemistry Letters 12 6 927 928 doi 10 1246 cl 1983 927 Boger D L Panek J S 1984 Palladium 0 mediated beta carboline synthesis Preparation of the CDE ring system of lavendamycin Tetrahedron Letters 25 30 3175 3178 doi 10 1016 S0040 4039 01 91001 9 Paul F Patt J Hartwig J F 1994 Palladium catalyzed formation of carbon nitrogen bonds Reaction intermediates and catalyst improvements in the hetero cross coupling of aryl halides and tin amides J Am Chem Soc 116 13 5969 5970 doi 10 1021 ja00092a058 Guram A S Buchwald S L 1994 Palladium Catalyzed Aromatic Aminations with in situ Generated Aminostannanes J Am Chem Soc 116 17 7901 7902 doi 10 1021 ja00096a059 a b Louie J Hartwig J F 1995 Palladium catalyzed synthesis of arylamines from aryl halides Mechanistic studies lead to coupling in the absence of tin reagents Tetrahedron Letters 36 21 3609 3612 doi 10 1016 0040 4039 95 00605 C a b c Guram A S Rennels R A Buchwald S L 1995 A Simple Catalytic Method for the Conversion of Aryl Bromides to Arylamines Angewandte Chemie International Edition 34 12 1348 1350 doi 10 1002 anie 199513481 a b c Muci A R Buchwald S L 2002 Practical Palladium Catalysts for C N and C O Bond Formation Topics in Curr Chem Topics in Current Chemistry 219 131 209 doi 10 1007 3 540 45313 x 5 ISBN 978 3 540 42175 7 Driver M S Hartwig J F 1997 Carbon Nitrogen Bond Forming Reductive Elimination of Arylamines from Palladium II Phosphine Complexes J Am Chem Soc 119 35 8232 8245 doi 10 1021 ja971057x Hartwig J F Richards S Baranano D Paul F 1996 Influences on the Relative Rates for C N Bond Forming Reductive Elimination and b Hydrogen Elimination of Amides A Case Study on the Origins of Competing Reduction in the Palladium Catalyzed Amination of Aryl Halides J Am Chem Soc 118 15 3626 3633 doi 10 1021 ja954121o Driver M S Hartwig J F 1995 A Rare Low Valent Alkylamido Complex a Diphenylamido Complex and Their Reductive Elimination of Amines by Three Coordinate Intermediates J Am Chem Soc 117 16 4708 4709 doi 10 1021 ja00121a030 Widenhoefer R A Buchwald S L 1996 Halide and Amine Influence in the Equilibrium Formation of Palladium Tris o tolyl phosphine Mono amine Complexes from Palladium Aryl Halide Dimers Organometallics 15 12 2755 2763 doi 10 1021 om9509608 a b Hartwig J F 1999 Approaches to catalyst discovery New carbon heteroatom and carbon carbon bond formation Pure Appl Chem 71 8 1416 1423 doi 10 1351 pac199971081417 S2CID 34700080 Hartwig J F 1997 Palladium Catalyzed Amination of Aryl Halides Mechanism and Rational Catalyst Design Synlett 1997 4 329 340 doi 10 1055 s 1997 789 S2CID 196704196 Hartwig J F 1998 Carbon Heteroatom Bond Forming Reductive Eliminations of Amines Ethers and Sulfides Acc Chem Res 31 852 860 doi 10 1021 ar970282g Wolfe J P Wagaw S Marcoux J F Buchwald S L 1998 Rational Development of Practical Catalysts for Aromatic Carbon Nitrogen Bond Formation Acc Chem Res 31 805 818 doi 10 1021 ar9600650 a b Hartwig J F 1998 Transition Metal Catalyzed Synthesis of Arylamines and Aryl Ethers from Aryl Halides and Triflates Scope and Mechanism Angew Chem Int Ed 37 15 2046 2067 doi 10 1002 sici 1521 3773 19980817 37 15 lt 2046 aid anie2046 gt 3 0 co 2 l PMID 29711045 a b Hartwig J F 2008 Evolution of a Fourth Generation Catalyst for the Amination and Thioetherification of Aryl Halides Acc Chem Res 41 11 1534 1544 doi 10 1021 ar800098p PMC 2819174 PMID 18681463 a b Surry D S Buchwald S L 2008 Biaryl Phosphane Ligands in Palladium Catalyzed Amination Angew Chem Int Ed 47 34 6338 6361 doi 10 1002 anie 200800497 PMC 3517088 PMID 18663711 Surry D S Buchwald S L 2011 Dialkylbiaryl phosphines in Pd catalyzed amination a user s guide Chem Sci 2 1 27 50 doi 10 1039 c0sc00331j PMC 3306613 PMID 22432049 15 16 14 9 17 18 19 20 21 Thomas J Colacot The 2010 Nobel Prize in Chemistry Palladium Catalysed Cross Coupling Archived 2020 06 02 at the Wayback Machine Platinum Metals Rev 2011 55 2 doi 10 1595 147106711X558301 Wolfe J P Buchwald S L 1996 Palladium Catalyzed Amination of Aryl Iodides J Org Chem 61 3 1133 1135 doi 10 1021 jo951844h Driver M S Hartwig J F 1996 A Second Generation Catalyst for Aryl Halide Amination Mixed Secondary Amines from Aryl Halides and Primary Amines Catalyzed by DPPF PdCl2 J Am Chem Soc 118 30 7217 7218 doi 10 1021 ja960937t Wolfe J P Wagaw S Buchwald S L 1996 An Improved Catalyst System for Aromatic Carbon Nitrogen Bond Formation The Possible Involvement of Bis Phosphine Palladium Complexes as Key Intermediates J Am Chem Soc 118 7215 7216 doi 10 1021 ja9608306 Louie J Driver M S Hamann B C Hartwig J F 1997 Palladium Catalyzed Amination of Aryl Triflates and Importance of Triflate Addition Rate J Org Chem 62 5 1268 1273 doi 10 1021 jo961930x Wagaw S Rennels R A Buchwald S L 1997 Palladium Catalyzed Coupling of Optically Active Amines with Aryl Bromides J Am Chem Soc 119 36 8451 8458 doi 10 1021 ja971583o Old D W Wolfe J P Buchwald S L 1998 A Highly Active Catalyst for Palladium Catalyzed Cross Coupling Reactions Room Temperature Suzuki Couplings and Amination of Unactivated Aryl Chlorides J Am Chem Soc 120 37 9722 9723 doi 10 1021 ja982250 Wolfe J P Buchwald S L 1999 A Highly Active Catalyst for the Room Temperature Amination and Suzuki Coupling of Aryl Chlorides Angew Chem Int Ed 38 16 2413 2416 doi 10 1002 sici 1521 3773 19990816 38 16 lt 2413 aid anie2413 gt 3 0 co 2 h PMID 10458806 Hamann B C Hartwig J F 1998 Sterically Hindered Chelating Alkyl Phosphines Provide Large Rate Accelerations in Palladium Catalyzed Amination of Aryl Iodides Bromides and Chlorides and the First Amination of Aryl Tosylates J Am Chem Soc 120 29 7369 7370 doi 10 1021 ja981318i Wolfe J P Tomori H Sadighi J P Yin J Buchwald S L 2000 Simple Efficient Catalyst System for the Palladium Catalyzed Amination of Aryl Chlorides Bromides and Triflates PDF J Org Chem 65 4 1158 1174 doi 10 1021 jo991699y PMID 10814067 Stambuli J P Kuwano R Hartwig J F 2002 Unparalleled Rates for the Activation of Aryl Chlorides and Bromides Coupling with Amines and Boronic Acids in Minutes at Room Temperature Angew Chem Int Ed 41 24 4746 4748 doi 10 1002 anie 200290036 PMID 12481346 Huang X Anderson K W Zim D Jiang L Klapars A Buchwald S L 2003 Expanding Pd Catalyzed C N Bond Forming Processes The First Amidation of Aryl Sulfonates Aqueous Amination and Complementarity with Cu Catalyzed Reactions J Am Chem Soc 125 22 6653 6655 doi 10 1021 ja035483w PMID 12769573 Anderson K W Tundel R E Ikawa T Altman R A Buchwald S L 2006 Monodentate Phosphines Provide Highly Active Catalysts for Pd Catalyzed C N Bond Forming Reactions of Heteroaromatic Halides Amines and H N Heterocycles Angew Chem Int Ed 45 39 6523 6527 doi 10 1002 anie 200601612 PMID 16955526 Ikawa T Barder T E Biscoe M R Buchwald S L 2007 Pd Catalyzed Amidations of Aryl Chlorides Using Monodentate Biaryl Phosphine Ligands A Kinetic Computational and Synthetic Investigation J Am Chem Soc 129 43 13001 13007 doi 10 1021 ja0717414 PMID 17918833 Wolfe J P Ahman J Sadighi J P Singer R A Buchwald S L 1997 An Ammonia Equivalent for the Palladium Catalyzed Amination of Aryl Halides and Triflates Tetrahedron Lett 38 36 6367 6370 doi 10 1016 S0040 4039 97 01465 2 Lee S Jorgensen M Hartwig J F 2001 Palladium Catalyzed Synthesis of Arylamines from Aryl Halides and Lithium Bis trimethylsilyl amide as an Ammonia Equivalent Org Lett 3 17 2729 2732 doi 10 1021 ol016333y PMID 11506620 Huang X Buchwald S L 2001 New Ammonia Equivalents for the Pd Catalyzed Amination of Aryl Halides Org Lett 3 21 3417 3419 doi 10 1021 ol0166808 PMID 11594848 Vo G D Hartwig J F 2009 Palladium Catalyzed Coupling of Ammonia with Aryl Chlorides Bromides Iodides and Sulfonates A General Method for the Preparation of Primary Arylamines J Am Chem Soc 131 31 11049 11061 doi 10 1021 ja903049z PMC 2823124 PMID 19591470 Mann G Incarvito C Rheingold A L Hartwig J F 1999 Palladium Catalyzed C O Coupling Involving Unactivated Aryl Halides Sterically Induced Reductive Elimination To Form the C O Bond in Diaryl Ethers J Am Chem Soc 121 3224 3225 doi 10 1021 ja984321a Torraca K E Huang X Parrish C A Buchwald S L 2001 An Efficient Intermolecular Palladium Catalyzed Synthesis of Aryl Ethers J Am Chem Soc 123 43 10770 10771 doi 10 1021 ja016863p PMID 11674023 Heesgaard Jepsen Tue 2011 Synthesis of Functionalized Dibenzothiophenes An Efficient Three Step Approach Based on Pd Catalyzed C C and CS Bond Formations European Journal of Organic Chemistry 2011 53 57 doi 10 1002 ejoc 201001393 Culkin D A Hartwig J F 2003 Palladium Catalyzed r Arylation of Carbonyl Compounds and Nitriles Acc Chem Res 36 4 234 245 doi 10 1021 ar0201106 PMID 12693921 Hamada T Chieffi A Ahman J Buchwald S L 2002 An Improved Catalyst for the Asymmetric Arylation of Ketone Enolates J Am Chem Soc 124 7 1261 1268 doi 10 1021 ja011122 PMID 11841295 Liao X Weng Z Hartwig J F 2008 Enantioselective r Arylation of Ketones with Aryl Triflates Catalyzed by Difluorphos Complexes of Palladium and Nickel J Am Chem Soc 130 1 195 200 doi 10 1021 ja074453g PMC 2551326 PMID 18076166External links editBuchwald Hartwig Coupling Recent Literature Buchwald Hartwig Chemistry Ian Mangion MacMillan Group Meeting July 30 2002 Link Buchwald Hartwig reaction Precious Metal catalysts from Acros Organics for coupling reactions in organic synthesis Link Retrieved from https en wikipedia org w index php title Buchwald Hartwig amination amp oldid 1208543105, wikipedia, wiki, book, books, library,

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