Phosphorus(III)Ligands in Homogeneous Catalysis Design and Synthesis,9780470666272

Phosphorus(III)Ligands in Homogeneous Catalysis Design and Synthesis

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Edition: 1st
ISBN13: 9780470666272
ISBN10: 0470666277
Format: Hardcover
Pub. Date: 2012-06-25
Publisher(s): Wiley
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Summary

Over the last 60 years the increasing knowledge of transition metal chemistry has resulted in an enormous advance of homogeneous catalysis as an essential tool in both academic and industrial fields. Remarkably, phosphorus(III) donor ligands have played an important role in several of the acknowledged catalytic reactions. The positive effects of phosphine ligands in transition metal homogeneous catalysis have contributed largely to the evolution of the field into an indispensable tool in organic synthesis and the industrial production of chemicals. This book aims to address the design and synthesis of a comprehensive compilation of P(III) ligands for homogeneous catalysis. It not only focuses on the well-known traditional ligands that have been explored by catalysis researchers, but also includes promising ligand types that have traditionally been ignored mainly because of their challenging synthesis. Topics covered include ligand effects in homogeneous catalysis and rational catalyst design, P-stereogenic ligands, calixarenes, supramolecular approaches, solid phase synthesis, biological approaches, and solubility and separation. Ligand families covered in this book include phosphine, diphosphine, phosphite, diphosphite, phosphoramidite, phosphonite, phosphinite, phosphole, phosphinine, phosphinidenene, phosphaalkenes, phosphaalkynes, P-chiral ligands, and cage ligands. Each ligand class is accompanied by detailed and reliable synthetic procedures. Often the rate limiting step in the application of ligands in catalysis is the synthesis of the ligands themselves, which can often be very challenging and time consuming. This book will provide helpful advice as to the accessibility of ligands as well as their synthesis, thereby allowing researchers to make a more informed choice. Phosphorus(III) Ligands in Homogeneous Catalysis: Design and Synthesis is an essential overview of this important class of catalysts for academic and industrial researchers working in catalyst development, organometallic and synthetic chemistry.

Author Biography

Paul C.J. Kamer, EaStCHEM, School of Chemistry, University of St. Andrews, Scotland.

Piet W.N.M. van Leeuwen, Institute of Chemical Research of Catalonia (ICIQ), Tarragona, Spain.

Table of Contents

List of Contributorsp. xv
Prefacep. xix
Phosphorus Ligand Effects in Homogeneous Catalysis and Rational Catalyst Designp. 1
Introductionp. 1
Properties of phosphorus ligandsp. 7
Electronic ligand parametersp. 7
Steric ligand parametersp. 9
Bite angle effectsp. 10
Electronic bite angle effectp. 11
Steric bite angle effectp. 12
Steric versus electronic bite angle effectsp. 12
Molecular electrostatic potential (MESP) approachp. 13
Asymmetric ligandsp. 15
Rational ligand design in nickel-catalysed hydrocyanationp. 19
Introductionp. 19
Mechanistic insightsp. 20
Rational designp. 20
Conclusionsp. 22
Referencesp. 23
Chiral Phosphines and Diphosphinesp. 27
Introductionp. 27
Early developmentsp. 27
Chiral chelating diphosphines with a linking scaffoldp. 30
Building chiral backbones from naturally available materialsp. 30
Early developmentp. 30
Syntheses of DIOP variantsp. 31
Synthesis from other natural chiral backbonesp. 33
Design and synthesis of chiral backbonesp. 35
Chiral backbones synthesized through asymmetric catalysisp. 35
Design and synthesis of ligands containing spiro backbonesp. 37
Design and synthesis of chiral ferrocene backbonesp. 40
Design and synthesis of other chiral backbonesp. 41
Synthesis from optical resolution of phosphine precursors or intermediatesp. 43
Chiral atropisomeric biaryl diphosphinesp. 46
Synthesis of BINAP and its derivativesp. 46
Synthesis of atropisomeric biaryl ligandsp. 49
General strategies of synthesizing of atropisomeric biaryl ligandsp. 52
Chiral phosphacyclic diphosphinesp. 52
Fundamental discovery and syntheses of BPE and DuPhosp. 52
Design and synthesis of bisphosphetanesp. 56
Design and synthesis of bisphospholanesp. 58
BPE and DuPhos analogue ligandsp. 58
P-stereogenic bisphospholane ligandsp. 60
Design and synthesis of bisphospholesp. 63
Design and synthesis of bisphosphinanesp. 65
Design and synthesis of bisphosphepinesp. 66
Summary of synthetic strategies of phosphacyclesp. 68
P-stereogenic diphosphine ligandsp. 68
Experimental procedures for the syntheses of selected diphosphine ligandsp. 69
Synthesis procedure for DIOP* ligandp. 69
Synthesis procedure of SDP ligandsp. 70
Synthesis procedure of ( R , R )-BICPp. 71
Synthesis procedure of SEGPHOSp. 71
Synthesis procedure of Ph-BPEp. 72
Synthesis procedure of TangPhosp. 73
Synthesis procedure of Binaphanep. 74
Concluding remarksp. 75
Referencesp. 75
Design and Synthesis of Phosphite Ligands for Homogeneous Catalysisp. 81
Introductionp. 81
Synthesis of phosphitesp. 82
Monophosphitesp. 82
Symmetrically substituted monophosphitesp. 82
Nonsymmetrically substituted monophosphitesp. 83
Caged monophosphitesp. 84
Monophosphites bearing dioxaphospho-cyclic unitsp. 84
Diphosphite ligandsp. 94
Diphosphites not containing a dioxaphospho-cyclic unitp. 94
Diphosphites bearing dioxaphospho-cyclic unitsp. 95
Triphosphitesp. 105
Highlights of catalytic applications of phosphite ligandsp. 106
Hydrogenation reactionsp. 106
Functionalization of alkenes: hydroformylation and hydrocyanationp. 108
Hydroformylationp. 108
Hydrocyanationp. 110
Addition of nucleophiles to carbonyl compounds and derivativesp. 110
1,2-additionp. 111
1,4-additionp. 111
Allylic substitution reactionsp. 113
Miscellaneous reactionsp. 117
General synthetic proceduresp. 122
Symmetrically substituted phosphitesp. 122
Nonsymmetrically substituted phosphitesp. 123
Phosphites bearing dioxaphospho-cyclic unitsp. 123
Referencesp. 124
Phosphoramidite Ligandsp. 133
Introductionp. 133
Historyp. 134
Synthesis of phosphoramiditesp. 134
Reactivity of the phosphoramiditesp. 135
Types of phosphoramidite ligandsp. 136
Acyclic monodentate phosphoramiditesp. 136
Cyclic monodentate phosphoramidites based on diolsp. 136
Synthesis of binaphthol- and biphenol-based phosphoramiditesp. 137
Synthesis of TADDOL-based phosphoramiditesp. 140
Synthesis of spiro-based phosphoramiditesp. 141
Synthesis of 1,2-diol-based phosphoramiditesp. 141
Phosphoramidites based on unusual diolsp. 141
Cyclic phosphoramidites based on amino alcoholsp. 142
Bis-phosphoramiditesp. 143
Bis-phosphoramidites based on diaminesp. 143
Bis-phosphoramidites based on diolsp. 144
Other bidentate phosphoramiditesp. 145
Mixed bidentate ligandsp. 145
Phosphoramidite-phosphinesp. 145
Phosphoramidite-phosphitep. 147
Phosphoramidite-aminesp. 148
Other bidentate phosphoramidite ligandsp. 149
Polydendate phosphoramiditesp. 149
Conclusionp. 153
Synthetic proceduresp. 153
Referencesp. 153
Phosphinite and Phosphonite Ligandsp. 159
Introductionp. 159
General methods for synthesis of complexesp. 160
Syntheses and applications of phosphinite ligandsp. 162
Early studiesp. 162
Phosphinite ligands from carbohydratesp. 163
Rh-catalyzed asymmetric hydrogenation of dehydroaminoacidsp. 164
Ni(0)-catalyzed asymmetric hydrocyanationp. 166
Ni(0)- and Pd(0)-catalyzed allylic substitution by carbon nucleophilesp. 170
Rh(I)-catalyzed hydroformylation of vinylarenesp. 171
Ni(II)-catalyzed asymmetric hydrovinylation of alkenesp. 171
Ligands for homogeneous catalysis in waterp. 172
Phosphinite ligands from other alcoholsp. 172
Phosphine-phosphinite and amine-phosphinite ligandsp. 173
Phosphinites from amines, amino alcohols, and amino acidsp. 174
Aminophosphinesp. 174
Aminophosphine-phosphinite (AMPP) ligandsp. 176
Bisphosphinite ligands with other scaffoldingsp. 179
1,1'-Diaryl-2,2'-phosphinites and dynamic conformational control in asymmetric catalysisp. 180
Monophosphinite ligandsp. 182
Hybrid ligands containing phosphinitesp. 182
Thioether-phosphinite ligandsp. 182
Oxazoline-phosphinite and pyridine-phosphinite ligandsp. 184
An alkene-phosphinite ligandp. 186
Chiral transition metal Lewis acids bearing electron-withdrawing phosphinitesp. 187
Synthesis and applications of phosphonite ligandsp. 188
Early studiesp. 188
Phosphonites from TADDOL and related compoundsp. 189
Phosphonites derived from 2,2'-hydroxybiaryls and related compoundsp. 193
Phosphine-phosphonite ligandsp. 196
Phosphonites with paracyclophane backbonep. 196
Phosphonites with a spirobisindane backbonep. 197
Miscellaneous phosphonite ligandsp. 198
Development of phosphonite ligands for industrially relevant processesp. 199
Phosphonite ligands in hydroformylationp. 199
Phosphonite ligands in Ni(0)-catalyzed hydrocyanationp. 201
Oxazoline-phosphonite ligands and olefin dimerizationp. 203
Use of the phosphonite functionality to synthesize other ligandsp. 206
Experimental procedures for the syntheses of prototypical phosphinite and phosphonite ligandsp. 208
Phosphinite ligandsp. 208
Me 2 P(OMe)p. 208
Et 2 POEt and EtP(OEt) 2p. 209
Synthesis of methyl 3,4-bis- O -[bis(3,5-dimethylphenyl)phosphino]- 2,6-di- O -benzoyl- a - D -glucopyranoside (Ligand 8)p. 209
Preparation of phenyl 2,3-bis- O -[bis[3,5-bis(trifluoromethyl) phenyl]-phosphino)-4,6- O -benzylidene-glucopyranosidep. 211
Preparation of bis-(pentafluorophenyl)chlorophosphinep. 212
An alternate general procedure for phosphinite incorporation. [(2S,3R)-3-phenylthio-4-methylpent-2-oxy]diphenylphosphinep. 212
Metal-template synthesis of an amino1,2-diarylphosphinediarylphophinite complexp. 213
Procedure for the preparation of a bis-aminodiaryphosphine (R)-37p. 213
(-)-(S)-4- tert -butyl-2-{1-di(2'-methylphenyl)phosphinite- 1-methyl-ethyl}-4,5-dihydro-oxazolep. 214
(R)-7-(2-phenyl-6,7-dihydro-5H-[1]pyrindin)-di-(2'-methylphenyl)- phosphinitep. 215
Phosphonite ligandsp. 217
(IR,7R)-9,9-dimethyl-2,2,4,6.6-penta(2-naphthyl)-3,5,8,l0-tetraoxa- 4-phosphabicyclo[5.3.0]-decanep. 217
(IR,7R)-9,9-dimethyl-2,2,4,6.6-penta(2-naphthyl)-3,5,8,l0-tetraoxa- 4-phosphabicyclo/5.3.0]-decanep. 218
Synthesis of (S)-2-[2-(diphenylphosphino)phenyl]-1,3,2-dinaphtho [d1,2,f1,2]dioxaphosphe-pinep. 219
4,5-Bis{di[(2-tert-butyl)phenyl]phosphonito}-9,9-dimethylxanthenep. 219
Acknowledgmentsp. 221
Abbreviationsp. 221
Referencesp. 222
Mixed Donor Ligandsp. 233
Introduction: general design principlesp. 233
Synthesis of bidentate P,X-ligandsp. 235
P,N-ligandsp. 235
Oxazoline-based P,N-ligandsp. 235
Imidazoline-based P,N-ligandsp. 243
Oxazole-, thiazole-, and imidazole-based P,N-ligandsp. 243
Pyridine-based P,N-ligandsp. 245
Amine- and imine-based P,N-ligandsp. 247
Other P,N-ligandsp. 250
P,O-ligandsp. 250
P,S-ligandsp. 252
P,C-ligandsp. 255
Conclusionp. 257
Experimental proceduresp. 257
Synthesis of PHOX ligandp. 257
Synthesis of NeoPHOX ligandp. 259
Referencesp. 260
Phospholesp. 267
Introductionp. 267
Creation of phospholes for use as ligandsp. 269
Reactions of phosphorus dihalides with metallated dienesp. 269
Reactions of phosphorus dihalides with dienesp. 270
Michael addition of primary phosphines to dienesp. 271
Postsynthetic functionalisationp. 271
Functionalisation at phosphorusp. 271
Use of electrophilesp. 272
Use of nucleophiles and aromaticsp. 272
Elaboration about the phosphole nucleusp. 272
Phosphole coordination chemistryp. 273
Phospholes in catalysisp. 276
Experimental proceduresp. 279
Referencesp. 280
Phosphinine Ligandsp. 287
Introductionp. 287
Ligand propertiesp. 288
Electronic propertiesp. 288
Structural characteristics and steric propertiesp. 289
Reactivity of phosphininesp. 290
Synthesis of Phosphininesp. 292
O + /P exchange reactionp. 292
Tin routep. 294
[4 + 2] cycloaddition reactionsp. 294
Ring expansion methodsp. 295
Metal-mediated functionalizationsp. 296
Coordination chemistryp. 297
Reactivity of transition metal complexesp. 300
Application of phosphinines in homogeneous catalysisp. 300
Experimental procedure for the synthesis of selected phosphininesp. 303
Referencesp. 305
Highly Strained Organophosphorus Compoundsp. 309
Introductionp. 309
Three-membered ringsp. 310
Rearrangementsp. 312
Homogeneous catalysisp. 313
Conclusionsp. 314
Experimental proceduresp. 315
Synthesis of BABAR-Phos 49a (R = i-Pr)p. 315
Synthesis of BABAR-Phos 49b (R = 3,5-(CF3)2C6H3)p. 316
Referencesp. 317
Phosphaalkenesp. 321
Introductionp. 321
Frontier molecular orbitals of phosphaalkenesp. 322
Synthesis of phosphaalkenesp. 324
Diphosphinidenecyclobutene (DPCB) synthesis (P,P chelates)p. 324
Bidentate-chelating P,P phosphaalkene ligandsp. 325
Phosphaalkenes capable of P,N-chelation to metalsp. 326
P,X achiral phosphaalkene ligands (X=P, O, S)p. 326
Synthesis of enantiomerically pure P,X ligands (X=P, N)p. 328
Catalysis with phosphaalkene ligandsp. 329
Ethylene polymerizationp. 329
Cross-coupling reactionsp. 330
Hydro- and dehydrosilylationp. 332
Hydroamination and hydroamidationp. 333
Isomerization reactionsp. 334
Allylic substitutionp. 335
Asymmetric catalysisp. 336
Concluding remarksp. 337
Experimental procedures for representative ligandsp. 338
Synthesis of DPCBp. 338
Synthesis of PhAk-Oxp. 338
Acknowledgmentsp. 339
Referencesp. 339
Phosphaalkynesp. 343
Introductionp. 343
General experimentalp. 344
Preparation of PC t Bup. 344
Tris(trimethylsilyl)phosphine, P(SiMe 3 ) 3p. 345
tert -butylphosphaalkene, Me 3 SiP = C(OSiMe 3 ) t Bu (systematic name [2,2-dimethyl-1-(trimethylsiloxy)propylidene]-(trimethylsilyl) phosphine)p. 346
(2,2-dimethylpropylidyne)phosphine; t BuC=Pp. 347
Adamanylphosphaalkyne, AdC=Pp. 348
Adamant-1-yl(trimethylsiloxy)methylidene (trimethylsilyl) phosphanep. 348
(Adamant-1-ylmethylidyne)phosphanep. 348
Mesitylphosphaalkyne, MesC=Pp. 349
Preparation of potassium bis(trimethylsilyl)phosphide {KP(SiMe 3 ) 2 }p. 349
Mesityl(trimethylsiloxy)methylene trimethylsilylphosphanep. 349
Mesitylphosphaalkynep. 350
Phospholide anionsp. 350
Preparation of Cp 2 Zr(PC t Bu) 2p. 351
Preparation of ClP(PC t Bu) 2p. 351
Preparation of the triphospholide anion and derivation to give the triphenylstannylphospholep. 352
Preparation of Cl 3 P 3 (C t Bu) 2p. 352
Preparation of the triphospholide anionp. 352
1,3,5-Triphosphabenzenep. 352
Preparation of Cl 3 VN t Bup. 353
Preparation of 1,3,5-triphospabenzene; P 3 (C t Bu) 3p. 353
Referencesp. 353
P-chiral Ligandsp. 355
Introductionp. 355
Designing P-chiral ligands using alcohols as chiral auxiliariesp. 357
Designing P-chiral ligands using amino alcohols as chiral auxiliariesp. 363
Synthesis starting from tricoordinated 1,3,2-oxazaphospholidinesp. 363
Synthesis starting from tetracoordinated 1,3,2-oxazaphospholidinesp. 364
Synthesis starting from 1,3,2-oxazaphospholidine borane complexesp. 366
Interest of the borane-phosphorus complex chemistryp. 366
Ephedrine methodp. 366
Methyl phosphinite boranes as P-chiral electrophilic building blocksp. 367
Chlorophosphine boranes as P-chiral electrophilic building blocksp. 368
Designing P-chiral aminophosphine phosphinites (AMPP*)p. 371
P-chiral o -hydroxyaryl phosphinesp. 371
P-chiral secondary phosphine boranesp. 373
P-chiral 1,2-diphosphinobenzenesp. 373
Strategies for the enantiodivergent synthesis of P-chiral ligandsp. 375
Designing of P-chiral ligands using amines as chiral auxiliariesp. 377
Sparteine as chiral auxiliaryp. 377
a -Arylethylamines as chiral auxiliariesp. 381
Conclusionp. 381
Experimental proceduresp. 383
Referencesp. 385
Phosphatrioxa-Adamantane Ligandsp. 391
Introductionp. 391
Synthesis of phosphatrioxa-adamantanesp. 393
Catalysis supported by phosphatrioxa-adamantane ligandsp. 395
Alkoxycarbonylationp. 395
Hydroformylation and hydrocyanationp. 397
Pd-catalysed coupling reactionsp. 399
Asymmetric hydrogenationp. 400
Experimental procedures for phosphatrioxa-adamantanes ligandsp. 401
Preparation of CgPHp. 401
Preparation of CgPH(BH 3 )p. 402
Preparation of CgPBrp. 402
Preparation of CgPCH 2 CH 2 CH 2 PCg (L1)p. 402
Preparation of CgPPh (L7)p. 402
Referencesp. 402
Calixarene-based Phosphorus Ligandsp. 405
Introductionp. 405
Conformational propertiesp. 407
Calixarene-based phosphorus ligandsp. 409
Phosphines and phosphinitesp. 409
Phosphites and phosphonitesp. 414
Applications in homogeneous catalysisp. 422
Experimental proceduresp. 424
Referencesp. 425
Supramolecular Bidentate Phosphorus Ligandsp. 427
Introduction: general design principlesp. 427
Construction of bidentate phosphorus ligands via self-assemblyp. 429
H bondingp. 429
Metal template assemblyp. 440
Ion templationp. 445
Conclusionsp. 446
Experimental proceduresp. 447
General remarksp. 447
Synthesis of UREAPhosp. 447
Synthesis of METAMORPhosp. 448
Synthesis of supraphosp. 450
Referencesp. 459
Solid-phase Synthesis of Ligandsp. 463
Introductionp. 463
Insoluble supports in ligand synthesisp. 466
Soluble polymeric supportsp. 470
Supported ligands in catalysisp. 472
Solid-phase synthesis of nonsupported ligandsp. 473
Conclusions and outlookp. 475
Experimental proceduresp. 476
Referencesp. 478
Biological Approachesp. 481
Introductionp. 481
Peptide-based phosphine ligandsp. 481
Solid-phase synthesis using phosphine-containing amino acidsp. 481
Synthesis of phosphine-containing amino acidsp. 482
Synthesis and application of phosphine-containing peptidesp. 484
Functionalisation of peptides with phosphinesp. 485
Phosphinomethylation of aminesp. 485
Phosphine modification of peptides via imine or amide formationp. 485
Oligonucleotide-based phosphine ligandsp. 487
Covalent anchoring of phosphines to DNAp. 487
Phosphine-based artificial metalloenzymesp. 488
Supramolecular anchoring of phosphines to proteinsp. 489
Avidin-biotinp. 489
Antibodiesp. 490
Covalent anchoring of phosphinesp. 491
Conclusions and outlookp. 492
Representative synthetic proceduresp. 493
Artificial hydrogenases based on the biotin-streptavidin technologyp. 493
Site-selective covalent modification of proteins with phosphines via hydrazone linkagep. 494
Acknowledgmentsp. 495
Referencesp. 495
The Design of Ligand Systems for Immobilisation in Novel Reaction Mediap. 497
Introductionp. 497
Aqueous biphasic catalysisp. 499
Fluorous biphasic catalysisp. 503
Ionic liquids as reaction mediap. 507
Supercritical fluids as solvents in single- and multiphasic reaction systemsp. 512
Biphasic systems based on CO2p. 516
Experimental sectionp. 518
Trisodium salt of 3,3′,3″-phosphinetriylbenzenesulfonic acid (TPPTS)p. 518
2,7-bis(SO3Na)-Xantphosp. 519
Sulfonated BINAPp. 519
Synthesis of Tris(1H,1H,2H,2H-perfluorooctyl)phosphinep. 520
Synthesis of Tris (4-tridecafluorohexylphenyl)phosphinep. 520
(Meta-sulfonatophenyl)diphenylphosphine, sodium salt (monosulfonated triphenylphosphine, TPPMS)p. 522
1-Propyl-3-methylimidazolium diphenyl(3-sulfonatophenyl)-phosphine ([PrMIM][TPPMS])p. 523
4,4′-Phosphorylated 2,2′-Bis(diphenylphosphanyl)-1,1′-binaphthylp. 523
Synthesis of (R)-6,6′-bis(perfluorohexyl)-2,2′ bis (diphenylphosphino)-1,1′-binaphthyl ((R)-Rf-BINAP)p. 524
Referencesp. 526
Index
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