Grignard Reagents – Review

1. Grignard Reagents – Review Katharine Goodenough 31/08/05

2. Background • Discovered by Victor Grignard in 1900 • Key factors are ethereal solvent and water-free conditions • Awarded Nobel Prize in 1912 • By 1975, over 40000 papers published using Grignard reagents • Mostly synthetic applications • Physical nature complicated • Important aspects: • Schlenk Equilibrium • Degree of Association in solution • Alkyl Grignards are most widely studied • Allyl and cyclic Grignard reagents will also be covered Victor Grignard

3. Formation • Classically formed from an organic halide and magnesium turnings in either ether or THF • Moisture-free conditions and an inert atmosphere are necessary • Magnesium must be of high purity • Activating agent such as iodine or dibromoethane often added • This removes the oxide layer from the Mg and exposes active metal surface • Reactivity of organic halide decreases I>Br>Cl>F • Iodides produce more side products so chloride or bromide usually used. • Other ethers such as DME, THP, anisole, di-n-propyl ether can be used, although solubility of magnesium halide can be a problem • Amine solvents (e.g. triethylamine, N-methyl morpholine) can also be effective for primary alkyl halides. Again, solubility is a problem.

4. Formation (2) • It is also possible to form a Grignard reagent from an organolithium compound and one equivalent of magnesium halide. This gives access to Grignard reagents which are difficult to prepare directly. • Occurs with retention of stereochemistry so can form chiral Grignard reagents • Dialkyl magnesium compounds obtained by addition of dioxane to ethereal Grignard reagent solution, which results in precipitation of the magnesium halide-dioxane complex that can then be filtered off. • Can also be formed by transmetallation from the diorganomercury compound

5. Reactions of Grignard reagents

6. Mechanism of reaction with ketones2

7. Wurtz Coupling • The main side-reaction during organomagnesium formation • Most common with larger R-group, organoiodides and especially allylic and benzylic halides • Can be avoided by slow addition of halide or a larger excess of magnesium • May arise by radical coupling or by reaction of the initially formed organometallic with more organic halide

8. Schlenk Equilibrium • An equilibrium exists in solution between the Grignard reagent RMgX and the diorganomagnesium MgR2 • This equilibrium can be driven to the right by the addition of dioxane • This causes the precipitation of magnesium halide, and the solution can then be filtered off and will contain solely the diorganomagnesium • Useful for formation of diorganomagnesium reagents • Complicates the characterisation of the Grignard reagent • Established using 25Mg and 28Mg that exchange occurs readily between labelled MgBr2 or metallic Mg and both MgEt2 and MgEtBr • Only occurs with pure forms of magnesium (inhibition may take place by impurities in less pure grades of Mg or exchange may be catalysed by O2) • Dependent on nature of X and R, concentration, temperature and solvent

9. Mechanism • Single electron transfer from Mg to organic halide • Shortlived radical anion decays to give organic radical R• and halide anion X- • X- adds to the Mg+, forming MgX. This combines with R• to form the Grignard reagent RMgX A second SET may also occur (4), forming R-, which could then combine with MgX+ to give RMgX (5). R2Mg is not formed directly, but by establishment of the Schlenk equilibrium

10. Alkyl Grignard Reagents Structure (solid state) • Dietherates (e.g. [MgBr(Ph)(OEt2)2]) exist as isolated, monomeric units • Mg is at centre of a distorted tetrahedron • Mg – C distance 2.1 – 2.2 Å (covalent bond length 1.7 Å) • MgBrMe(THF)3 crystallises as monomeric trigonal bipyramidal complex with 3 THF ligands • Bromoethylmagnesium crystallises from diisopropyl ether as a dimer [MgBr(Et)(OiPr2)]2 with bridging Br ligands • Each Mg is 4 coordinate, O-Mg-C = 120.7°; Br-Mg-Br = 116.2°

11. Alkyl Grignard Reagents Structure (solution)2 The structure of Grignard reagents in solution has been found to be dependent on the solvent used. The degree of association (i) was measured via ebullioscopy, cryoscopy and rates of quasi-isothermal distillation of solvent EtMgCl EtMgCl EtMgBr EtMgBr

12. Alkyl Grignard Reagents • In THF, RMgX (X = Cl, Br, I) are monomeric over a wide concentration range • For X = F, compounds are dimeric (ie [RMgF]2) • In Et2O, RMgX (X = Cl, F) are dimeric over a wide concentration range. • For X = Br, I, association patterns are more complex. • At low concentration, monomeric species exist (in accordance with Schlenk equilibrium) • At high concentration, association increases to greater than 2 (ie dimers and larger present) • Four possible structures for dimer of RMgX (or MgR2+ MgX2):

13. Alkyl Grignard Reagents • b should be most stable • Association of Mg through the halogen (MgBr2 and MgI2) is much stronger than through the alkyl group (Et2Mg or Me2Mg). • Association of Grignard reagents is predominately through the halogen • Linear structure e is also possible due to the position of the Schlenk equilibrium in Et2O towards RMgX

14. Alkyl Grignard Reagents Thermodynamics of Schlenk equilibrium3 • In ether, MgRX is prevalent (K~10 – 103) but in THF (K = 1-10), a more random distribution is seen. • Since THF adducts tend to have higher coordination numbers than those of Et2O, differences attributed to degree of solvation. • In hydrocarbon solvent, K is very small; in triethylamine it is very large

15. Alkyl Grignard Reagents NMR Studies4 • MgR2 and RMgX can be distinguished provided exchange is slow on the NMR timescale • α-H atoms of magnesium-bound alkyl group R resonate at δ-2 – 0 ppm (average under conditions of fast exchange) • MgXR is at lower field than MgR2 due to shielding by halogen • MeMgBr δ -1.55 ppm; MgMe2δ -1.70 ppm in Et2O at -100 °C • Can detect variation in composition • Varies with nature of solvent, organic group, halide, temperature and concentration • Alkyl groups undergo exchange under the reaction conditions • Rate of alkyl group exchange determined by structure of alkyl group and secondarily by nature of solvent

16. Alkyl Grignard Reagents • For Me2Mg in Et2O: • The lower field signals are attributed to bridging Me groups in associated dimethylmagnesium • The higher field signal is attributed to terminal methyl groups of the associated molecules, and to monomers • In THF: • Signal at 11.76 at +20 °C, shifts to 11.83 at -76 °C • Supports its existence as a monomeric species in THF • At low temp, a small signal was seen at 11.70, attributed to small amounts of associated species

17. Alkyl Grignard Reagents • For MeMgBr in Et2O: • At low temperature, two distinct signals are seen. • The lower field signal (τ 11.55) is attributed to MeMgBr • The higher field signal (τ 11.70) is Me2Mg as before • Equilibrium constants for the Schlenk equilibrium cannot be obtained due to precipitation during cooling • In THF: • Chemical shifts are very dependant on temperature, moving to higher field with lower temperature. • It was not possible to observe distinct signals for MeMgBr and Me2Mg as was possible in ether. • The Schlenk equilibrium seems to shift towards the dialkylmagnesium at lower temperature, since the spectrum approaches that of Me2Mg at -76 °C • May be partially due to MgBr2 precipitating • From these data, equilibrium constant was calculated for MeMgBr in THF, K = 4 ± 2.6

18. Alkyl Grignard Reagents Further solvent effects5 • Increasing donation by solvent shifts the α-H resonance to higher fields • Determined for EtMgBr and Et2Mg at 40 °C • Low concentrations employed to avoid association effects • Leads to an order of solvent basicity: Anisole < iPr2O < Et3N < nBu2O < Et2O < THF < DME

19. Allyl Grignard Reagents Allylic Grignard reagents6 • Allylic Grignard reagents can give products derived from both the starting halide and the allylic isomer • There is potential for them to exist as the η1 structure which can then equilibrate, or as the η3 structure, as is known to exist for e.g. π-allyl palladium complexes • Allylmagnesium bromide has a very simple nmr spectrum with only two signals: the four α- and γ-protons (δ 2.5) are equivalent with respect to the β-proton (δ6.38) • The same was found for β-methylallylmagnesium bromide, which has a methyl group and only one other type of proton • Either rapid interconversion of the η1 structures must make the methylene groups equivalent or the methylene groups of the η3 structure must rotate to make all four of the hydrogens equivalent

20. Allyl Grignard Reagents • H2 is coupled equally to both of the protons of C1, and these non-equivalent hydrogens could not be frozen out. • There must therefore be rapid rotation of the C1-C2 bond on the nmr time scale • The value of J12 (~9.5 Hz) shows that this is not an equilibrium between Z and E hydrogens on C1 in a planar allylic system, which should have a value of ~12 Hz (average of 9Hz for Z, 15 Hz for E) • The compounds cannot have exclusively the planar structure. • Data supports single bond character in C1-C2 and C1 having significant sp3 character. • Mg is localised at C1; its presence controls the geometry at C1

21. Allyl Grignard Reagents IR Studies • As nmr timescale was found to be too slow to observe the unsymmetrical isomers of allylmagnesium bromide, IR was employed. • Two otherwise identical isomers a and b were distinguished by deuterium substitution • The mass effect of D directly substituted on a double bond lowers the stretching frequency, remote deuteration has smaller effect • Non-deuterated has absorption at 1587.5 cm-1 • Deuterated has two peaks at 1559 and 1577.5 cm-1 • For methallylmagnesium bromide, one peak at 1584 cm-1 was transformed to two bands at 1566 and 1582 cm-1 • Methallyllithium does not undergo similar splitting

22. Allyl Grignard Reagents 13C nmr studies • 13C spectrum of allylmagnesium bromide has two lines of similar width: the methylene carbons at δ58.7 and the methine carbon at δ148.1 ppm. • As temperature was reduced, the methylene resonance broadened and disappeared into baseline noise, while the methine signal remained constant. • At the lowest temperatures studied (~180K at 62.9 MHz) there was no sign of the appearance of separate high- and low-field methylene resonances; only the broadening of the average signal • The allylic rearrangement is the only process that could be taking place with a large enough shift difference to account for the observed broadening • Similar behaviour is also observed for methallylmagnesium bromide

23. Cyclic Grignard Reagents Cyclic reagents7 • As with the Schlenk equilibrium, the bifunctional Grignard reagent generated from Br(CH2)5Br could exist as: • To establish whether this occurs, firstly the magnesiacyclohexane was made in such a way that no MgBr2 could contaminate the cyclic compound: • Titration of a hydrolysed aliquot of the reaction product gives a ratio for basic Mg/total Mg of 1/1 as required for dialkylmagnesium compounds

24. Cyclic Grignard Reagents Association • The monomeric magnesiacyclohexane was found to be in equilibrium with its dimer. • Equilibrium in favour of dimer: K1 (28.25 °C) = 531 ± 81 l/mole K1 (48.50 °C) = 223 ± 41 l/mole ΔH = -8 kcal/mole (i.e. dimerisation exothermic) i = 1.4 – 1.7 • Established that 12-membered dimer was present by crystallisation and X-ray structure • Each Mg has two THF molecules attached

25. Cyclic Grignard Reagents • The degree of association was then measured for: • Degree of association i = 1.28 – 1.58 (for BrMg(CH2)5MgBr i = 2) • → equilibrium between linear and cyclic species exists • Schlenk equilibrium constant: • K2 (28.25 °C) = 250 ± 65 l/mole K2 (48.53 °C) = 300 ± 92 l/mole • Magnesium bromide was then added to the previously generated solution of (CH2)5Mg and the same parameters measured: • i = 1.49 (28.25 °C); i = 1.53 (48.50 °C) • This is identical to i as measured above → solutions are of similar composition • K2 (28.25 °C) = 299 ± 30 l/mole K2 (48.50 °C) = 361 ± 50 l/mole ΔH ~ +2 kcal/mole (endothermic reaction)

26. Cyclic Grignard Reagents • Less reduction to alcohol seen for cyclic organomagnesium reagent • Reduction takes place via a 6-centre transition state in an elimination of MgH by an E2 cis mechanism • In Et2O,i = 2 • i.e. Schlenk equilibrium lies to the left in diethyl ether and monomer is present • Influence of cyclic structure on reactivity was investigated for:8

27. Conclusions • Deceptively simple nature of Grignard reactions complicated by behaviour in solution • In Et2O, Grignard reagents tend to exist as RMgX, but at higher concentrations are highly associated in solution • In THF, there is an equilibrium between RMgX and R2Mg. However, the organomagesium reagents tend to be monomeric. • Allylic Grignard reagents are complicated by the nature of their conjugation • Di-Grignard reagents can exist as the cyclic species

28. References • Magnesium, Calcium, Strontium and Barium, W.E. Lindsell, Comprehensive Organometallic Chemistry1, 1982, 155 • E.C. Ashby, Quarterly Reviews of the Chemical Society, 1967, 21, 259 • M.B. Smith, W.E. Becker, Tetrahedron, 1966, 22, 3027; 1967, 23, 4215 • G.E. Parris, E.C. Ashby, J. Am. Chem. Soc.1971, 93, 1206 • G. Westera, C. Blomberg, F. Bickelhaupt, J. Organomet. Chem. 155 (1978) C55 • A) E.A. Hill, W.A. Boyd, H. Desai, A. Darki, L. Bivens, J. Organomet. Chem. 514 (1996) 1. B) D.A. Hutchison, K.R. Beck, R.A. Benkeser, J. Am. Chem. Soc. 1973, 95, 7075 • H.C. Holtkamp, C. Blomberg, F. Bickelhaupt, J. Organomet. Chem. 19 (1969) 279. • B. Denise, J.-F. Fauvarque, J. Ducom, Tetrahedron Lett.5 (1970), 355