Grignard reaction

The Grignard reaction (pronounced /ɡriɲar/) is an organometallic chemical reaction in which alkyl- or aryl-magnesium halides (Grignard reagents) add to a carbonyl group in an aldehyde or ketone.[1] This reaction is an important tool for the formation of carbon–carbon bonds.[2][3] The reaction of an organic halide with magnesium is not a Grignard reaction, but provides a Grignard reagent.[4]

Grignard reactions and reagents were discovered by and are named after the French chemist François Auguste Victor Grignard (University of Nancy, France), who was awarded the 1912 Nobel Prize in Chemistry for this work.[5]

Contents

Reaction mechanism

The Grignard reagent functions as nucleophiles attacking electrophilic carbon atoms that are present within polar bond of the carbonyl group. The addition of the Grignard reagent to the carbonyl typically proceeds through a six-membered ring transition state.[6]

However, with hindered Grignard reagents, the reaction may proceed by single-electron transfer. Similar pathways are assumed for other reactions of Grignard reagents, e.g., in the formation of carbon–phosphorus, carbon–tin, carbon–silicon, carbon–boron and other carbon–heteroatom bonds.

Preparation of Grignard reagent

Grignard reagents form via the reaction of an alkyl or aryl halide with magnesium metal. The reaction is conducted by adding the organic halide to a suspension of magnesium in an etherial solvent, which provides ligands required to stabilize the organomagnesium compound. Empirical evidence suggests that the reaction takes place on the surface of the metal. The reaction proceeds through single electron transfer:[7][8][9]

R−X + Mg → R−X•− + Mg•+
R−X•− → R + X
X + Mg•+ → XMg
R + XMg → RMgX

A limitation of Grignard reagents is that they do not readily react with alkyl halides via an SN2 mechanism. On the other hand, they readily participate in transmetalation reactions:

RMgX + ArX → ArMgX + MgX2

For this purpose, commercially available Grignard reagents are especially useful because this route avoids the problem with initiation.[10]

Reaction conditions

In reaction involving Grignard reagents, it is important to exclude water and air, which rapidly destroy the reagent by protonolysis or oxidation. Since most Grignard reactions are conducted in anhydrous diethyl ether or tetrahydrofuran, side-reactions with air are limited by the protective blanket provided by solvent vapors. Small-scale or quantitative preparations should be conducted under nitrogen or argon atmospheres, using air-free techniques. Although the reagents still need to be dry, ultrasound can allow Grignard reagents to form in wet solvents by activating the magnesium such that it consumes the water.[11]

The organic halide

Grignard reactions often start slowly. As is common for reactions involving solids and solution, initiation follows an induction period during which reactive magnesium becomes exposed to the organic reagents. After this induction period, the reactions can be highly exothermic. Alkyl and aryl bromides and iodides are common substrates. Chlorides are also used, but fluorides are generally unreactive, except with specially activated magnesium.

Magnesium

Typical Grignard reactions involve the use of magnesium ribbon. All magnesium is coated with a passivating layer of magnesium oxide, which inhibits reactions with the organic halide. Specially activated magnesium, such as Rieke magnesium, circumvents this problem.[12]

Solvent

Most Grignard reactions are conducted in ethereal solvents, especially diethyl ether and THF. With the chelating diether dioxane, some Grignard reagents undergo a redistribution reaction to give diorganomagnesium compounds (R = organic group, X = halide):

2 RMgX + dioxane R2Mg + MgX2(dioxane)

This reaction is known as the Schlenk equilibrium.

Testing Grignard reagents

Because Grignard reagents are so sensitive to moisture and oxygen, many methods have been developed to test the quality of a batch. Typical tests involve titrations with weighable, anhydrous protic reagents, e.g. menthol in the presence of a color-indicator. The interaction of the Grignard reagent with phenanthroline or 2,2'-bipyridine causes a color change.[13]

Initiation

Many methods have been developed to initiate sluggish Grignard reactions. These methods weaken the passivating layer of MgO, thereby exposing highly reactive magnesium to the organic halide. Mechanical methods include crushing of the Mg pieces in situ, rapid stirring, and sonication of the suspension. Iodine, methyl iodide, and 1,2-dibromoethane are common activating agents. The use of 1,2-dibromoethane is particularly advantageous as its action can be monitored by the observation of bubbles of ethylene. Furthermore, the side-products are innocuous:

Mg + BrC2H4Br → C2H4 + MgBr2

The amount of Mg consumed by these activating agents is usually insignificant. A small amount of mercuric chloride will amalgamate the surface of the metal, allowing it to react.

Industrial production

Grignard reagents are produced in industry for use in situ, or for sale. As with at bench-scale, the main problem is that of initiation; a portion of a previous batch of Grignard reagent is often used as the initiator. Grignard reactions are exothermic, and this exothermicity must be considered when a reaction is scaled-up from laboratory to production plant.[14]

Many Grignard reagents, e.g. methylmagnesium chloride, phenylmagnesium bromide, and allylmagnesium bromide are available commercially as tetrahydrofuran or diethyl ether solutions.

Reactions of Grignard reagents

Reactions with carbonyl compounds

Grignard reagents will react with a variety of carbonyl derivatives.[15]

The most common application is for alkylation of aldehydes and ketones, as in this example:[16]

Note that the acetal function (a masked carbonyl) does not react.

Such reactions usually involve an aqueous acidic workup, though this is rarely shown in reaction schemes. In cases where the Grignard reagent is adding to a prochiral aldehyde or ketone, the Felkin-Anh model or Cram's Rule can usually predict which stereoisomer will be formed. With easily 1,3-diketones and related substrates, the Grignard reagent RMgX functions merely as a base, giving the enolate anion and liberating the alkane RH.

Reactions with other electrophiles

Grignard reagents will react with other various electrophiles, serving both as a nucleophile for many and as a base for protic substrates.

Not shown, the reaction of bromoethane and Mg in ether followed by the addition of phenol in THF converts the phenol into C6H5-OMgBr. In the presence of paraformaldehyde powder and triethylamine after the addition of benzene and distillation of the latter solvents, salicylaldehyde will be the major product after the addition of 10% HCl. The reaction works also with iodoethane instead of bromoethane.[17]

Formation of bonds to B, Si, P, Sn

Like organolithium compounds, Grignard reagents are useful for forming carbon–heteroatom bonds.

Carbon–carbon coupling reactions

A Grignard reagent can also participate in coupling reactions. For example, nonylmagnesium bromide reacts with methyl p-chlorobenzoate to give p-nonylbenzoic acid, in the presence of Tris(acetylacetonato)iron(III) (Fe(acac)3), after workup with NaOH to hydrolyze the ester, shown as follows. Without the Fe(acac)3, the Grignard reagent would attack the ester group over the aryl halide.[18]

For the coupling of aryl halides with aryl Grignards, nickel chloride in tetrahydrofuran (THF) is also a good catalyst. Additionally, an effective catalyst for the couplings of alkyl halides is dilithium tetrachlorocuprate (Li2CuCl4), prepared by mixing lithium chloride (LiCl) and copper(II) chloride (CuCl2) in THF. The Kumada-Corriu coupling gives access to [substituted] styrenes.

Oxidation

Treatment of a Grignard reagent with oxygen gives the magnesium organoperoxide. Hydrolysis of this material yields hydroperoxides or alcohol. These reactions involve radical intermediates.

The simple oxidation of Grignard reagents to give alcohols is of little practical import as yields are generally poor. In contrast, two-step sequence via a borane (vide supra) that is subsequently oxidized to the alcohol with hydrogen peroxide is of synthetic utility.

The synthetic utility of Grignard oxidations can be increased by a reaction of Grignard reagents with oxygen in presence of an alkene to an ethylene extended alcohol.[19] This modification requires aryl or vinyl Grignards. Adding just the Grignard and the alkene does not result in a reaction demonstrating that the presence of oxygen is essential. Only drawback is the requirement of at least two equivalents of Grignard although this can partly be circumvented by the use of a dual Grignard system with a cheap reducing Grignard such as n-butylmagnesium bromide.

Nucleophilic aliphatic substitution

Grignard reagents are nucleophiles in nucleophilic aliphatic substitutions for instance with alkyl halides in a key step in industrial Naproxen production:

Elimination

In the Boord olefin synthesis, the addition of magnesium to certain β-haloethers results in an elimination reaction to the alkene. This reaction can limit the utility of Grignard reactions.

Degradation of Grignard reagents

At one time, the formation and hydrolysis of Grignard reagents was used in the determination of the number of halogen atoms in an organic compound.[20] In modern usage Grignard degradation is used in the chemical analysis of certain triacylglycerols.[21]

Industrial use

An example of the Grignard reaction is a key step in the industrial production of Tamoxifen[22] (currently used for the treatment of estrogen receptor positive breast cancer in women)[23] :

Gallery

See also

References

  1. ^ Smith, Michael B.; March, Jerry (2007), Advanced Organic Chemistry: Reactions, Mechanisms, and Structure (6th ed.), New York: Wiley-Interscience, ISBN 0-471-72091-7, http://books.google.com/books?id=JDR-nZpojeEC&printsec=frontcover 
  2. ^ Shirley, D. A. (1954), Org. Reactions 8: 28–58 
  3. ^ Huryn, D. M. (1991), Comp. Org. Synthesis 1: 49–75 
  4. ^ http://goldbook.iupac.org/G02699.html
  5. ^ Grignard, V. (1900), "Sur quelques nouvelles combinaisons organométaliques du magnésium et leur application à des synthèses d'alcools et d'hydrocabures", Compt. Rend. 130: 1322–1325, http://gallica.bnf.fr/ark:/12148/bpt6k3086n/f1322.table 
  6. ^ Maruyama, K.; Katagiri, T. (1989), "Mechanism of the Grignard reaction", J. Phys. Org. Chem 2 (3): 205, doi:10.1002/poc.610020303 
  7. ^ Garst, J. F.; Ungvary, F. "Mechanism of Grignard reagent formation". In Grignard Reagents; Richey, R. S., Ed.; John Wiley & Sons: New York, 2000; pp 185–275. ISBN 0-471-99908-3.
  8. ^ Advanced Organic chemistry Part B: Reactions and Synthesis F.A. Carey, R.J. Sundberg 2nd Ed. 1983
  9. ^ Rogers, H. R.; Hill, C. L.; Fujiwara, Y.; Rogers, R. J.; Mitchell, H. L.; Whitesides, G. M. (1980). "Mechanism of formation of Grignard reagents. Kinetics of reaction of alkyl halides in diethyl ether with magnesium". Journal of the American Chemical Society 102 (1): 217. doi:10.1021/ja00521a034.  edit
  10. ^ Handbook of Grignard Reagents, Silverman, G. S., Rakita, P. E., Eds.; Marcel Dekker: New York, 1996.
  11. ^ Smith, David H. (1999), "Grignard Reactions in "Wet" Ether", Journal of Chemical Education 76 (10): 1427, doi:10.1021/ed076p1427 
  12. ^ Lai Yee Hing (1981), "Grignard Reagents from Chemically Activated Magnesium", Synthesis 1981 (8): 585–604, doi:10.1055/s-1981-29537 
  13. ^ Arkady Krasovskiy, Paul Knochel "Convenient Titration Method for Organometallic Zinc, Magnesium, and Lanthanide­ Reagents" Synthesis 2006, pp. 890-891. doi:10.1055/s-2006-926345
  14. ^ Philip E. Rakita (1996), "5. Safe Handling Practices of Industrial Scale Grignard Ragents", in Gary S. Silverman, Philip E. Rakita (Google Books excerpt), Handbook of Grignard reagents, CRC Press, pp. 79–88, ISBN 0824795458, http://books.google.com/books?id=82CaxfY-uNkC&pg=PA80 
  15. ^ Henry Gilman and R. H. Kirby (1941), "Butyric acid, α-methyl-", Org. Synth., http://www.orgsyn.org/orgsyn/orgsyn/prepContent.asp?prep=cv1p0361 ; Coll. Vol. 1: 361 
  16. ^ Haugan, Jarle André; Songe, Pål; Rømming, Christian; Rise, Frode; Hartshorn, Michael P.; Merchán, Manuela; Robinson, Ward T.; Roos, Björn O. et al. (1997), "Total Synthesis of C31-Methyl Ketone Apocarotenoids 2: The First Total Synthesis of (3R)-Triophaxanthin", Acta Chimica Scandinavica 51: 1096–1103, doi:10.3891/acta.chem.scand.51-1096, http://actachemscand.dk/pdf/acta_vol_51_p1096-1103.pdf, retrieved 2009-11-26 
  17. ^ Peters, D. G.; C. Ji. J. Chem. Educ., 2006, 83 (2), p 290 http://pubs.acs.org/doi/abs/10.1021/ed083p290
  18. ^ A. Fürstner, A. Leitner, G. Seidel (2004), "4-Nonylbenzoic Acid", Org. Synth. 81: 33–42, http://www.orgsyn.org/orgsyn/orgsyn/prepContent.asp?prep=v81p0033 
  19. ^ Youhei Nobe, Kyohei Arayama, and Hirokazu Urabe (2005), "Air-Assisted Addition of Grignard Reagents to Olefins. A Simple Protocol for a Three-Component Coupling Process Yielding Alcohols", J. Am. Chem. Soc. 127 (51): 18006–18007, doi:10.1021/ja055732b, PMID 16366543 
  20. ^ Steinkopf, Wilhelm; V. Petersdorff, Hans-JüRgen (1940), "Studien in der Thiophenreihe. LI. Atophanartige Derivate des Dithienyls und Diphenyls", Justus Liebig s Annalen der Chemie 543: 119, doi:10.1002/jlac.19405430110 
  21. ^ Myher JJ, Kuksis A (February 1979), "Stereospecific analysis of triacylglycerols via racemic phosphatidylcholines and phospholipase C", Can. J. Biochem. 57 (2): 117–24, doi:10.1139/o79-015, PMID 455112 
  22. ^ "Grignard Reagents: New Developments", ISBN: 0–471 
  23. ^ Jordan VC (1993), "Fourteenth Gaddum Memorial Lecture. A current view of tamoxifen for the treatment and prevention of breast cancer", Br J Pharmacol 110 (2): 507–17, PMC 2175926, PMID 8242225, http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2175926 

Further reading