a more drastic oxidation with potassium permanganate yields acetone and B-methyladipic acid.
l-Rhodin-ol, CmH19Ol-l or(CH3)2C: CH-(CH¢)2-CH(CH5)-(CH2)2-OH, or 2-6 dimethyl-octene-2-ol-8, occurs in the essence of geranium and of rose. It is a structural isomer of citronellol (P. Barbier and L. Bouveault, Comptes rendus, 1896, 122, pp. 529, 673; Bull. Soc. Chim., 1900, [3], 23, p. 459), and its inactive form has been synthesized from ethyl heptenone. It is an oil of strong rose odour, which boils at 110° C. (10 mm.). Chromic acid mixture oxidizes it to rhodinal and rhodinic acid, whilst by drastic oxidation it yields acetone and, S-methyladipic acid.
Geranial, CIQHUOH, or (CH;,)2C:Cl'l~(CH2)2-C(CH;,):CH~Cl-IQOH, 2-6 dimethyl-octadiene-2-6-ol-8, is found in the oils of geranium, citronella, neroli, petit-grain, spike, lang-ylang, and in Turkish and German rose oil. It is prepared lifom the oils by treating them with alcoholic potash and then fractionating in vacuo. The geraniol fraction is then mixed with freshly dried calcium chloride and the mixture allowed to stand in vacuo at a low temperature, when the compound CIOHNO-CaCl2 separates out, This is washed with absolute ether and finally decomposed by water, when pure gcraniol is liberated (O. jacobsen, Ann., 1871, 157, p. 232; ]. Bertram and E. Gildemeister, Jour. prak. Chem., 1897 (2), 56, p. 507). It may also be prepared by reducing the corresponding aldehyde (citral) with sodium amalgam. It IS a colourless, pleasant-smelling oil, which boils at 230° C. Oxidation converts it into citral and geranic acid, (Cl-l3)2C:CH-(CH2)2~C(CH3):CH-COQH. By shaking it with 5 per cent. sulphuric acid it yields terpin hydrate, and when heated with concentrated alcoholic potash to 150° C. it is converted into dimethylheptenol (P. Barbier, Complex rendus, 1899, 128, 110). Geraniol may be converted into linalool by distilling a fiaintly alkaline solution of acid geranyl phthalate with steam. Nerol, CMH, -, OH, was obtained in 1902 from neroli oil by A. Hesse and O. Zeitschel (Jour. prak. Chem., 1902 (2), 66, p. 481); it also is found in petit-grain oil. It boils at 226-227° C. (755 mm.), and has a distinctive rose odour. It is inactive and is to be regarded as a stereo-isomer of geraniol. It does not form a compound with calcium chloride. It combines with four atoms of bromine to form a characteristic tetra bromide. It is formed (alon with other products) by the action of acetic acid on linalool %O. Zeitschel, Ber., 1906, 39, p. 1780) and also by the reduction of citral-b. LiHGl00l, C1gH17OH, Of<CH3)2C ICH' CHQ,
is 2-6-dimethyloctadiene-2~7-ol-6. d-Linalool was first found in coriander oil, and l-linalool in oil of linaloe. It is also found in oil of bergamot, petit-grain, lavender, neroli, spike, sassafras leaves and lemon, either in the free condition or as esters. It is a pleasant smelling liquid which boils at 197-199° C. (according to its source). The inactive variety can be prepared from geraniol, this alcohol on treatment with hydrochloric acid yielding a mixture of chlorides, which when digested with alcoholic potash are transformed into i-linalool (F. Tiemann and F. W. Semmler, Bef., 1898, 31, p. 832). It is oxidized by chromic acid to citral. Wihen shaken for some time with dilute sulphuric acid it yields terpin hydrate. Citronellal, CwH,8O, is the aldehyde of eitroncllol. It is a constituent of many essential oils, and was first discovered in citronella oil b' F. D. Dodge (Amer. Chem. Jour., 1889, II, p. 456); it is also found in eucalyptus oil and in lemon-grass oil. It is a dextrorotatory liquid which boils at 203'-204° C. It is readily reduced by sodium amalgam to citronellol, and oxidized by ammonia cal silver oxide to citronellic acid. Potassium permanganate oxidizes it to acetone and B-methyladipic acid. It forms a dimethyl acetal, C,0l-l, g(OCHs)2, which on oxidation with potassium permanganate yields a dioxydihydro-citronellaldimethyl acetal, CH;-C (CHQOH) (OH) - (Cl-li);-CH (CH3) -CH2~CHO, which must possess the above composition, since on further oxidation by chromic acid it yields a keto-aldehyde of the constitution CH3CO(Cl-l2)3~Cl-l(CHQ)-CHQ-CHO (C. D. Harries and O. Schauwecker, Bef., 1901, 34, p. 2981); this reaction leads to the formulation of citronella as a dimethyl-2~6-0ctene-1-al-8. Citronellal is readily converted into an isomeric cyclic alcohol isopulegol (A8(9)terpenol-3) by acids or acetic an hydride (F. Tiemann, Ber., 1896, 29, p. 913). It combines with sodium bisulphite, giving a normal bisulphite and also a mono- and dihydrosulphonic acid. Geramfal (citral), C,0H15O, is the aldehyde corresponding to geraniol. It occurs in the oils of lemon, orange, lemon-grass, citronella, ba ', verbena, and in various eucalyptus oils. It may be obtained from the oils by means of its bisulphite compound, provided the operation is carried out at low temperature, otherwise loss occurs owing to the formation of sulphonic acids. Synthetically it may be produced by the oxidation of geraniol with chromic acid mixture, or by distilling a mixture of calcium formate and calcium geraniate. Its aldehyde nature is shown by the facts that it forms an alcohol on reduction, and that on oxidation it yields an acid (geranic acid) of the same carbon content. The osition of the ethylene linkages in the molecule is proved by the formation of addition compounds, by its products of oxidation (acetone, laevulinic acid), and by the fact that on warming with potassium carbonate solution it yields methyl heptenone and acetaldehyde (F. Tiemann, Bef., 1899, 32, p. 107). On fusion with potassium bi sulphate it forms para-cymene. It combines with B-naphthylamine and pyruric acid, in alcoholic solution, to form the characteristic citryl-,6-na hthocinchonic acid, CHHHNOZ-51120, which is useful for identifying citral. The crude citral obtained from essential oils is a mixture of two ethylene stereo isomers which are designated as citral-a and citral-b (F. Tiemann and M. Kerschbaum, Bef., 1900, 33, p. 877). Citral-a boils at 110-1 12° C. (12 mm.) and citral-b at 102-IO4° C. The structural identity of the two forms has been confirmed by C. Harries (Ben, 1907, 40, p. 2823), who has shown that their ozonides (prepared from the citrals by the action of ozone on their solution in carbon tetrachloride) are quantitatively decomposed in both cases into acetone, laevulinic aldehyde and glyoxal. Lemon-grass oil contains 73 per cent. of citral-a and 8 per cent. of citral-b. Citral combines with sodium bisulphite to form a normal bisulphite compound, a stable dihydrosulphonate, an unstable dihydrosulphonate and a hydromonosulphonate (F. Tiemann, Revue gén. de ehim. pure et appl., 1, 16, p. ISO). Citral condenses readily with acetone, in the presence of alkalis, to form pseudo-ionone (see Ionone, below). The compounds of the citral series are readily converted into cyclic isomers by acids, the ring closing between the first and sixth carbon atoms in the chain. Two series of such compounds exist, namely the o. and /3 series, differing from each other in the position of the double linkage in the molecule. The constitution of the a-series is determined by the fact that on oxidation they yield isogeronic acid, which can be further oxidized to BB-dimethyladipic acid; the B-series in the same way yielding geronic acid and aa-dimethyladipic acid. The eyclocitrals themselves cannot be obtained direct from citral by the action of acids, since under these conditions para-cymene results, but they are prepared by boiling citrylidenecyanacetic ester with dilute sulphuric acid and subsequent hydrolysis of the cyclic ester with caustic potash (F. Tiemann, Ber., 1900, 33, p. 3719), or citral may be condensed with primary amines to the corresponding aldehydeimino compounds, which are then isomerized by concentrated acids, the amine group being hydrolysed at the same time (German Patent, 123747 (1901))-Ionone,
C13N¢0O. By condensing citral with acetone F. Tiemann (Bern, 1893, 26, p. 2691) obtained pseudo-ionone (1), an oil of boiling-point 143-145° C. (12 mm.), which on boiling with sulphuric acid is converted into a mixture of the isomeric a- and B-iononcs (2 and 3)
(1) (CH3)2C: CH~ (CHz)2~ C(CH1) I CH- CH: CH~ CO- CH; C(CHa)z C(CHa)z
()H2CqCH~CH:CH~CO-CH;)H1C 'C~CH:CH-C0~CH.|
2
H¢C&%C~ CH; (3 HQC iC'CHs
CH C
a-lonone is an oil which boils at 127-128° C. (12 mm.) and possesses a characteristic violet odour. The Q8-compound boils at 128-129° C. (10 mm.) and possesses a similar odour. They are largely used in perfumery. An isomer of ionone is irone, the odoriferous principle of the iris root. It boils at 144° C. (16 mm.). When heated with hydriodic acid and phosphorus it yields the hydrocarbon irene, CMH” (F. Tiemann, loc. cit.).
SESQUITERPENES
Cadinene, C15H21, is found in the oils of cade (from the wood of Juniperus oxyeldrus), cubeb, atchouli, galbanum, cedar-wood and juniper. It may be obtained by fractionating oil of cade, converting the crude hydrocarbon into its dihydrochloride and decomposing this by boiling with aniline. It is an oil which boils at 274-275° C. and decomposes on exposure. Caryophyllene is found in oil of cloves and in oil of copaiba balsam. Various other sesquiterpenes have been described, e.g. zingiberene (from essence of gmgfxl), ceggerile (frzfm oildoflcedar-wood), santalene (from oil of san(a -woo, umu ene an c ovene.
Of the sesquiterpene alcohols pure santalol, C15H26O, has been obtained from essence of sandal-wood by conversion into the acid phthahc esters and saponification of these bfy potash (Schimmel &Co., Biillelin, April TSQQ, p 41). A mixture 0 two alcohols is thus obtained, one boiling at 165-167° C . (13 mm.) and the other at 173° C. They are distinguished by the1r different optical activities, one li/tfinépragticagy inactive, ;he other strongly laevo-rotatory (sie also uer et, omptes ren us, 1900, 130, p. 417; Bull. Soc. him., 1900 (3), 23, p. 540). Caryophyllene alcohol is obtained from oil gif cliovesj hbyt; ihmination of évater it yields clovene, CUH24, a 1qu1 w ic oi s at 261-263°
Mzilny di-himdhtri-terpene; have been described, but as yet are not t oroug y c araeterize
References.-Gildemeister and Hoffman, The Volalile Oils (Milwaukee, 1900); R. Meldola, The Chemical Synthesis of Vital Products (London, 1904); F. W. Semmler, Die aetherischen Oele (Leipzig, 1906); G. Cohn, Die Riechstojfe (Brunswick, 1904); 1. M. Klimont, gieklsynihetisiien Tumi isoégten Arolznatiea)(Leipzig, 1899); and eus er, ie erpene runswic, 1896 . For cam hor see A. Lapworth, Bril. Assoc. Rep. for 1900, and O. Aschan, l)'7ie Konstilution des Kamphers (Brunswick, 1903). (F. G. P.*)