“Phosphinooxazolines”的意思、由来-开放百科全书

The synthesis of phosphinooxazolines is modular and it is not normally necessary to introduce the phosphine and oxazoline moieties in any particular order. However while examples exist of the phosphine being introduced first,^[2] it is more common to see the synthesis of a phenyloxazoline which is subsequently combined with a source of diphenylphosphine. Methods for doing this depend on the nature of the subsituent in the X position:

Of these methods the copper iodide catalysed reaction method is by far the simplest to carry out, as it does not require the synthesis of discrete anionic or organometallic species and is able to couple a wide range of materials in good to excellent yields.

In catalysis

Phosphinooxazolines are able to influence both the enantioselectivity and regioselectivity of a range of metal catalysed reactions.^[7] In reactions involving symmetric transition states these properties work in concert to induce asymmetry and thus promote the formation of a single product. Enantioselectivity is controlled by the chirality of the ligand which is normally located on the oxazoline ring, however the P-centre may also be stereogenic.^[8] Regioselectivity is controlled by variety of steric and electronic factors^[9] the most important of which being a form of trans effect, in which atoms complexed trans to the P‑atom become more electrophilic than ones located trans to the N‑atom. This is caused by the P‑atom engaging in back bonding, as it is a π‑electron acceptor.

Allylic substitutions

Phosphinooxazolines are used as ligands in allylic substitution reactions as both enantio- and regioselectivity is required to give an enantiomerically pure product due to the transition state being highly symmetric. In the example below all additions are enantioselective however the symmetric complex has no regiocontrol, resulting in a racemic product. The asymmetric complex is both regioslective and enantioselective, resulting in a single enantiomer.

The primary application of PHOX ligands is in palladium catalysts used for enantioselective allylic substitutions. They are able to effect a wide range of substitiuations including allylic alkylations (Tsuji-Trost reaction),^[10] aminations^[11] and sulfonylations.^[12]

Heck Reaction

Palladium complexes containing chiral phosphinooxazolines have been shown to be efficient catalysts for the Heck reaction.^[13] High yields and good to excellent enantioselectivities have been obtained, with the formation of by-products via C=C bond migration being greatly reduced.^[14] Pd-PHOX catalysts have also been used for intramolecular Heck reactions and examples exist where they have been shown to be superior to more common ligands such as BINAP.^[15]

Asymmetric Hydrogenation

The high enantio- and regiocontrol afforded by phosphinooxazoline ligands has fuelled research into their use for asymmetric hydrogenation. Iridium complexes incorporating phosphinooxazoline ligands have been shown to be effective for 'classic' hydrogenation using H₂,^[16] with ruthenium and palladium catalysts having also been investigated for transfer hydrogenation.^[1] In addition to theoretical studies,^[17] the structural^[18] and kinetic properties^[19] of Ir-PHOX complexes have been investigated to better understand their behaviour as hydrogenation catalysts.

See also

References

1. ^¹{{cite journal|last1=Braunstein|first1=Pierre|last2=Naud|first2=Fre´de´ric|last3=Rettig|first3=Steven J.|title=A new class of anionic phosphinooxazoline ligands in palladium and ruthenium complexes: catalytic properties for the transfer hydrogenation of acetophenone|journal=New Journal of Chemistry|volume=25|issue=1|year=2001|pages=32–39|issn=1144-0546|doi=10.1039/b004786o}}
2. ^{{cite journal|last=Koch|first=Guido|author2=Lloyd-Jones, Guy C. |author3=Loiseleur, Olivier |author4=Pfaltz, Andreas |author5=Prétôt, Roger |author6=Schaffner, Silvia |author7=Schnider, Patrick |author8= von Matt, Peter |title=Synthesis of chiral (phosphinoaryl)oxazolines, a versatile class of ligands for asymmetric catalysis|journal=Recueil des Travaux Chimiques des Pays-Bas|date=2 September 2010|volume=114|issue=4–5|pages=206–210|doi=10.1002/recl.19951140413}}
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4. ^{{cite journal|last=Sprinz|first=Jürgen|author2=Helmchen, Günter|title=Phosphinoaryl- and phosphinoalkyloxazolines as new chiral ligands for enantioselective catalysis: Very high enantioselectivity in palladium catalyzed allylic substitutions|journal=Tetrahedron Letters|volume=34|issue=11|pages=1769–1772|doi=10.1016/S0040-4039(00)60774-8|year=1993}}
5. ^{{cite journal|last=Tani|first=Kousuke|author2=Behenna, Douglas C. |author3=McFadden, Ryan M. |author4= Stoltz, Brian M. |title=A Facile and Modular Synthesis of Phosphinooxazoline Ligands|journal=Organic Letters|date=1 June 2007|volume=9|issue=13|pages=2529–2531|doi=10.1021/ol070884s |pmid=17536810|url=https://authors.library.caltech.edu/74475/2/ol070884ssi20070513_123443.pdf}}
6. ^{{cite journal|last=Zhang|first=Xumu |author2=Liu, D. |author3=Dai, Q.|title=A new class of readily available and conformationally rigid phosphino-oxazoline ligands for asymmetric catalysis|journal=Tetrahedron|date=27 June 2005|volume=61|issue=26|doi=10.1016/j.tet.2005.03.111|url=http://www.sciencedirect.com/science/article/pii/S0040402005006150|pages=6460–6471}}
7. ^{{cite journal|last=Helmchen|first=Günter|author2=Pfaltz, Andreas|title=PhosphinooxazolinesA New Class of Versatile, Modular P,N-Ligands for Asymmetric Catalysis|journal=Accounts of Chemical Research|volume=33|issue=6|pages=336–345|doi=10.1021/ar9900865|pmid=10891051|date=June 2000}}
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9. ^{{cite journal|last=Armstrong|first=Paul B.|author2=Dembicer, Elizabeth A. |author3=DesBois, Andrew J. |author4=Fitzgerald, Jay T. |author5=Gehrmann, Janet K. |author6=Nelson, Nathaniel C. |author7=Noble, Amelia L. |author8= Bunt, Richard C. |title=Investigation of the Electronic Origin of Asymmetric Induction in Palladium-Catalyzed Allylic Substitutions with Phosphinooxazoline (PHOX) Ligands by Hammett and Swain–Lupton Analysis of the ¹³C NMR Chemical Shifts of the (π-Allyl)palladium Intermediates|journal=Organometallics|volume=31|issue=19|pages=6933–6946|doi=10.1021/om3007163|year=2012}}
10. ^{{cite journal|last=Wiese|first=Burkhard|author2=Helmchen, Günter|title=Chiral phosphinooxazolines with a bi- or tricyclic oxazoline moiety - applications in Pd-catalyzed allylic alkylations|journal=Tetrahedron Letters|volume=39|issue=32|pages=5727–5730|doi=10.1016/S0040-4039(98)01173-3|year=1998}}
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12. ^{{cite journal|last=Eichelmann|first=Holger|author2=Gais, Hans-Joachim|title=Palladium-catalyzed asymmetric allylic sulfonylation|journal=Tetrahedron: Asymmetry|volume=6|issue=3|pages=643–646|doi=10.1016/0957-4166(95)00049-U|year=1995}}
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15. ^{{cite journal|last=Ripa|first=Lena|author2=Hallberg, Anders|title=Intramolecular Enantioselective Palladium-Catalyzed Heck Arylation of Cyclic Enamides|journal=The Journal of Organic Chemistry|volume=62|issue=3|pages=595–602|doi=10.1021/jo961832b|pmid=11671454|year=1997}}
16. ^{{cite journal|last=Roseblade|first=Stephen J.|author2=Pfaltz, Andreas|title=Iridium-Catalyzed Asymmetric Hydrogenation of Olefins|journal=Accounts of Chemical Research|volume=40|issue=12|pages=1402–1411|doi=10.1021/ar700113g|pmid=17672517|date=December 2007}}
17. ^{{cite journal|last=Hopmann|first=Kathrin Helen|author2=Bayer, Annette|title=On the Mechanism of Iridium-Catalyzed Asymmetric Hydrogenation of Imines and Alkenes: A Theoretical Study|journal=Organometallics|volume=30|issue=9|pages=2483–2497|doi=10.1021/om1009507|year=2011}}
18. ^{{cite journal|last=Smidt|first=Sebastian P.|author2=Pfaltz, Andreas |author3=Martínez-Viviente, Eloísa |author4=Pregosin, Paul S. |author5= Albinati, Alberto |title=X-ray and NOE Studies on Trinuclear Iridium Hydride Phosphino Oxazoline (PHOX) Complexes|journal=Organometallics|volume=22|issue=5|pages=1000–1009|doi=10.1021/om020805a|year=2003}}
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