Convenient preparation of optically active 2-halooctanes and related

Nov 4, 1974 - (15) J. M. Patterson, L. T. Burka, and M. R. Boyd, J. Org.Chem., 33, 4033. (1968). ... Joseph San Filippo, Jr.,* and Louis J. Romano. Sc...
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J.Org. Chem., Vol. 40, No. 10, 1975

Notes

(9)N. P. Buu-Hoi, P. Jacquignon, and 0. Perin-Roussel, Bull. SOC.Chim. Fr., 2849 (1965). (IO)E. F Pratt and L. W. Bottimer, J. Am. Chem. SOC.,79,5248 (1957). (11) H. Gilman and J. A. Beel. J. Am. Chem. SOC.,73,774 (1951). (12)J. I. G.Cadogan, J. Chem. Soc., 4257 (1962). (13)J. Kenner and F. S.Statham, J. Chem. SOC.,299 (1935). (14)L. Sobczyk, Bull. Acad. Pol. Scb, Ser. Sci. Chim., 9,237 (1961). (15)J. M. Patterson, L. T. Burka, and M. R. Boyd, J. Org. Chem., 33, 4033 (1968).

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A Convenient P r e p a r a t i o n of Optically Active 2-Halooctanes and Related Compounds1

10

0

5

10

I6

BOND REFRACTION. c-x B O N D (cm3, 20",n,,,) Figure 1. A plot of the molecular rotation, [MI, vs. the common bond refraction, [R] (C-X bond), for 2-halooctanes.

Joseph San Filippo, Jr.,* and Louis J. Romano School of Chemistry, Rutgers University, New Brunswick, New Jersey 08903 Received January 8,1975

Optically active 2-haloalkanes have been of considerable utility in the elucidation of the mechanisms of many organic reactions and also serve as models for the theoretical study of optical activitye2The practical synthesis of these compounds is, therefore, a matter of some importance. We wish t o report that 2-halooctanes can be conveniently prepared in good yields and in generally high optical purity by halide ion displacement on the tosylate formed from optically active 2-octanoL3

In a typical experiment, the tosylate (7.10 g, 25.0 mmol) of (+)-(S)-2-octanol, a z 0 ~ s 9+7.W0, optical purity 99.4%, was stirred vigorously with anhydrous potassium fluoride (7.25 g, 125 mmol) in 25.0 ml of triethylene glycol a t l l O o under a reduced pressure of 4.0 Torr. The volatile materials were allowed to distil from the reaction mixture and collected in a cold trap ( - 5 0 O ) . Analysis of the crude distillate by GLC indicated a 52% yield of 2-fluorooctane (based on starting alcohol), accompanied by a 27% yield of octene(s). This crude distillate was treated with a slight excess of bromine in carbon disulfide, washed with aqueous sodium thiosulfate, dried (MgS04), and distilled to afford pure (-)-(R)-2-fluorooctane ( l ) , aZo589 -9.99°.4 The results of

similar reactions employing lithium chloride, potassium bromide, and lithium iodide are listed in Table I. The synthesis of (-)-(R)-2-fluorooctane (1) is particularly noteworthy. Its preparation provides the first completed series of configurationally related 2-haloalkanes. The resulting relationship can be used to estimate the optical purity of this compound based on the empirically observed linear correlation between the optical rotation and bond re1 shows fraction developed by Davis and J e n ~ e n Figure .~ this relationship plotted for values of optically pure 2chloro-, 2-bromo-, and 2-iodooctane of the same configuration. The extension of this line to include 2-fluorooctane leads to predicted molecular rotation for (-)-(R)-2-fluorooctane of [Mlz0589-16.6°.6 The agreement between this value and the observed molecular rotation of [M]205sg -16.4' suggests that displacement has proceeded with essentially complete inuersion of configuration, to produce optically pure 1. Of the existing procedures for the preparation of optically active 2-chloro- and 2-bromooctane, the reaction of an optically active alcohol with phosphorous trihalides and related reagents provides products of highest optical p ~ r i t y , ~ although overall yields are sometimes poor and conditions frequently critical. It is clear that the reaction of 2-octyl tosylate with halide ion as described above provides a significantly improved procedure for the synthesis of optically

Table I Reaction of (+)-(S)-2-Octyl Tosylate with Potassium Fluoride, Lithium Chloride, Potassium Bromide, and Lithium Iodide (Eq 1) C-X

Temp, "C

MX (concn, td)

K F (5.0)

LiCl (5.0) KBr (1.2)

LiI (1.2)

Solventa

Triethylene glycol Triethylene glycol Triethylene glycol Tetraethylene glycol

Reaction

(Torr)

time, hr

110 (4.0)

3

110 (1.0)

Optical

(34)

bond

refraction,c cm3, 2 0 ' ( A = 589)

t eocn e !s),

aZ05*9

purity, %

2-Fluorooctane (52)

-9.9ge

-loof

1.44

27

2

2-Chlorooctane (80)

-30.72"

97.2'

6.74

16

65 (0.1)

2

2-Bromooctane (75)

-41.56@

95.4'

9.80

8.0

90 (0.1)

1.5

2-Iodooctane (83)

-19.32e

30.6'1~

14.08

8.0

2-Halooctane

%b'd

All solvents were vacuum distilled under nitrogen immediately prior to use. These values represent GLC yields based on starting alcohol; isolated halocarbon yields were somewhat lower. c The specific value for 2-fluoro-, 2-chloro-, 2-bromo-, and 2-iodooctane are unavailable. This number represents the common bond refraction of a number of fluoro-, chloro-, bromo-, and iodo-substituted alkanes. A tabulation of these values is given in ref 5 . d No attempt was made to distinguish possible octene isomers. e GLC analysis indicated minimum sample purity >99%. f See text for discussion of this value. g Calculated for optically pure (+)-(S)-2-halooctane:a Z o g s g +31.6" (Cl), a Z o 5 8 g +43.6" (Br), cy2058g +63.2" (I), taken from ref 7, Table V, footnote e. h The considerable racemization observed in this instance is presumably a result of iodide exchange; see ref 12.

Notes active 2-halooctanes (and by extension, other 2-haloalkanes) in generally high optical purity. It should be further noted that only 2-halooctanes were observed. Rearranged halocarbons were not detected. Taken together, these data are consistent, with a mechanism for carbon-halogen bond formation which involves an SN2 displacement at carbon. Finally, and not unexpectedly, nucleophiles other than halide ions appear to behave similarly. Thus, for example, (+)-(S)-2-oct,yl tosylate reacts with lithium azide to yield (-) - ( R )-2-azidooctane (93%, aZ0589 -40.20°).8

Experimental Sectiong (+)-(S)-2-Ootyl tosylate was prepared from (+)-(S)-2-octanol (a20589 +7.97') by the procedure described by Streitwieser and coworkers.1° (-)-(R)-2-Fluorooctane (1). Into a dry two-neck 50-ml flask containing a Teflon-coated stirrer bar was placed 7.25 g (125 mmol) of anhydrous potassium fluoride. One neck was capped with a rubber septum, the other was connected t o a cold trap, and the apparatus was flushed with nitrogen. Anhydrous triethylene glycol (25 ml) and 7.10 g (25 mmol) of the tosylate of (+)-(S)-2octanol (aZo589 +7.97', optical purity 99.4%) were added by syringe. The rubber septum was replaced with a glass stopper and the flask was heated to 110' with vigorous stirring under reduced pressure (4 Torr). The volatile materials were allowed to distil from the reaction mixture and collected in the cold trap (-50') over a period of 3 hr. Analysis of the crude distillate by GLC indicated a 52% yield of 2-fluorooctane accompanied by a 27% yield of octene(s). The crude distillate was treated with a slight excess of bromine in carbon disulfide, washed with aqueous sodium thiosulfate, dried (MgSOJ, and distilled to afford 1.45 g (44%) of (-)(R)-2-fluorooctane (1):0 1 ~ ~ 5 8-9.99', 9 bp 55-57' (43 Torr) [lit.'l bp 139O (760 Torr)]; 'H NMR (CC14) 6 4.50 [ l H, d of multiplets, J(HCF) = 48 Hz], -1.4 110 H, br, complex multiplet, (CH2)5],1.26 13 H, d of d, J(CH3-CHF) = 23 Hz, J(CH3-CHF) = 7.0 Hz], 0.96 (3 H, t); ir (CC14) 870 cm-' (vs, C-F). (-)-(R)-2-Chlorooctane was prepared from 4.24 g (100 mmol) of anhydrous lithium chloride and 5.68 g (20.0 mmol) of the tosylate of (+)-(S).2-octanolin 20 ml of triethylene glycol by a procedure analogous to that described for the synthesis of 1. After treatment with a slight excess of bromine (CS2) and subsequently with aqueous sodium thiosulfate, the crude product mixture was dried (MgS04) and fractionated to yield 1.80 g (61%) of (-)-(R)-2-chlorooctane, bp 74-76O (25 Torr) [lit.12 bp 61-62' (17 Torr)], a20589 -30.72'. (-)-(R)-2-]3romooctane was synthesized by a procedure similar to that described for the preparation of 1 using anhydrous potassium bromide (1.97 g, 18.0 mmol) and 4.26 g (15.0 mmol) of the tosylate of (+)-(S)-2-octanol in 15 ml of triethylene glycol a t 65' (0.1 Torr). The reaction was conducted over a period of 2 hr. Direct fractionation of the crude product afforded 1.84 g (63%) of (-)-(R)-2-bromooctane, bp 74-76' (14 Torr) [lit.12 bp 72' (9 Torr)], a 2 0 j s g -41.56'. (-)-(R)-2-l[odooctane was prepared according to the procedure outlined for the preparation of 1 using lithium iodide (0.806 g, 6.00 mmol) and 1.42 g (5.00 mmol) of the tosylate of (+)-(S)-2-octanol in 10 ml of tetraethylene glycol. The reaction was carried out under a reduced pressure of 0.1 Torr a t a temperature of 90° over a period of 90 min. Direct fractionation of the crude product gave 0.80 g (67%) of (-)-(R)-2-iodooctane, bp 54-55O (1.5 Torr) [lit.12 bp 42' (0.5 Torr)], a20589 -19.32O. (-)-(R)-2-Azidooctane was prepared from 2.45 g (50.0 mmol) of lithium azide and 2.84 g (10.0 mmol) of the tosylate of (+)-(S)2-octanol by a procedure analogous to that described for the preparation of 1. Direct fractionation of the crude product yielded 1.11 g (72%) of (-j-(R)-2-azidooctane: bp 59-60' (5 Torr) [lit.13 bp 6 8 O (9 Torr)]; (YZ0589 -40.20'; 'H NMR (CCld) 6 3.33 (1 H, sextet), 1.9-1.2 (13 H, br, complex multiplets), 0.90 (3 H, t); ir (CC14)2110 cm-I (vs, -N3).

Acknowledgment. We thank Professor Donald B. Denney for a generous gift of optically active 2-octanol. Registry No.-2-Fluorooctane, 54632-06-3; 2-chlorooctane, 18651-57-5; 2-bromooctane, 5978-55-2; 2-iodooctane, 29117-48-4; (+)-(S)-2-octyl tosylate, 34817-25-9; (-)-(R)-2-azidooctane, 53475-02-8.

J.Org. Chem., Vol. 40, No. 10, 1975 1515 References and Notes (1) Supported by the Research Corporation, the donors of the Petroleum Research Fund, administered by the American Chemical Society, and a

research grant from the Exxon Corp.

(2) J. G. Kirkwood, J. Chem. Phys., 5, 479 (1937); E. U. Condon. W. Altar, and H. Erying, ibid., 5, 753 (1937);L. L. Jones and H. Erying, Tetrahe-

dron, 13, 235 (1961). (3) Previous studies have reported that the 2-haloalkanes produced by the displacement of tosylate by halide ion were extensively racemized: A. J. H. Houssa, J. Kenyon. and H. Phillips, J. Chem. Sac., 1700 (1929); J. Cason and J. S. Correia, J. Org. Chem., 26, 3645 (1961). (4) This and all other rotations reported here have been corrected for the optical purity of the starting al~ohol.~ (5) D. D. Davis and F. R. Jensen, J. Org. Chem., 35, 3410 (1970). (6) The best-fit equation, calculated for the points CI, Br, I shown in Figure 1, is [M]205gs= 7.58[RIz05g9 5.64, which leads to a molecular rotation of [M]205sg- 16.6' for optically pure (-)-(R)-Z-fluorooctane,calculated for carbon-fluorine bond refraction of 1.44. The molecular optical rotation (molecularrotation, M) as used here corresponds to the quantity [MI = [a](mol wt)/100; [R] is the common bond refra~tion.~ The density of 2-fluorooctane is unavailable. The density of I-fluorooctane, 8 ' = 0.810 ["Handbook of Chemistry and Physics", 53rd ed, 1972, p C-3991. was substituted. For a Feview of these procedures, see H. R. Hudson, Synthesis, 1, 112 (1969). Yield determined by GLC analysis. The observed rotation for purportedly optically pure 2-azidooctane is ( a ( 2 0 5 8 938.6' [R. A. Moss and P. E. Schueler, J. Am. Chem. Soc., 96, 5792 (1974)]. All boiling points are uncorrected Infrared spectra were determined within sodium chloride cells on a Perkin-Elmer Model 137 spectrophotometer. NMR spectra were determined with a Varian T-60 NMR spectrometer. 'H chemical shifts are reported in parts per million relative to internal tetramethyisilane. All coupling constants are in hertz. Mass spectra were determined on a Hitachi Perkin-Elmer RMU-7E mass spectrometer. Analytical GLC analyses were performed on a Hewlett-Packard Model 5750 flame ionization instrument. Absolute product yields were calculated from peak areas using internal standard techniques with response factors obtained from authentic samples. Reported rotations were recorded as neat liquids in a 1-dm cell using a Perkin-Elmer Model 141 spectropolarimeter.Alkali salts were purchased from Alfa Inorganics. Solvents were distilled immediately prior to use. A. Streitwieser, Jr., T. D. Walsh, and J. R. Wolfe, Jr., J. Am. Chem. SOC.,87, 3682 (1965). F. Swarts, Bull. SOC.Chim. Beig., 30, 302 (1921). E. J. Coulson, W. Gerrard, and H. R. Hudson, J. Chem. Sac., 2364

+

(1965). P. A. Levene, A. Rothen, and N. Kuna, J. B i d . Chem., 115, 415 (1936).

Sodium Bismuthate as a Phenolic Oxidant Emil Kon and Edward McNelis*

Chemistry Department, N e w York University, N e w York, N e w York 10003 Received November 4,1974

The oxidative polymerization of 2,6-xylenol (I) to its corresponding polyphenylene oxide (11) has been carried out with homogeneous and heterogeneous one-electron oxidants. An excellent catalytic oxidant is the homogeneous cuprous halide-oxygen-pyridine system developed by Hay and c0workers.l Heterogeneous oxidants such as silver oxide,2 activated manganese d i ~ x i d e ,lead ~ d i ~ x i d e and ,~ nickel peroxide4 have been reported to be noncatalytic and less effective in achieving with facility the high molecular weights of the Hay system. Nonetheless, studies of these heterogeneous oxidants have been important in eliciting the mechanism of the polymerization and understanding the oxidative capabilities of nonstoichiometric oxides. Despite the disparity of oxidants for this polymerization, the mechanism is a free-radical one characterized by a polycondensation via quinone-ketal intermediate.3,5*6 Sodium bismuthate is another interesting and possibly more useful heterogeneous oxidant for the polymerization of I and other phenols (Table I). Scant attention has been given to sodium bismuthate as an oxidant for phenols, even though its potential was indicated by Hewitt, who used it to oxidize the monobenzyl ether of bis-2-hydroxy-lnaphthylmethane to a spironaphthalenone in 90% yield.