NITRATION THEORIES^55This was based on infra-red absorption spectra which show frequencies of the
oxonium ion bond (O+-H, ca. 2600 cm-1) and of the nitrate ion.
Houben [6] gives the following sequence of transformations for “benzaldehyde
nitrate” :
+ H 2 O -> C 6 H 5 CHO + HNO 3 (a)left in a hermetic vessel -> C 6 H 5 COOH + HNO 2 (b)+ (CH 3 CO) 2 O -> C 6 H 5 CH(OOC.CH 3 ) 2 + HNO 3 (c)
C 6 H 5 CHO.HNO 3
+ H 2 SO 4 -> m- C 6 H 4 (NO 2 )CHO + H 2 O (d)
H 2 SO 4 + (CH 3 CO) 2 O -> p- C 6 H 5 (NO 2 )CHO + H 2 O (e)
C 10 H 8 -> C 6 H 5 CHO + Cl0H 7 .NO 3 (f)
An interesting point is the influence of the compounds which react with an addi-
tion compound (reactions d and f) on the position of the nitro group introduced.
Following Thiele’s view [7] that any aromatic substitution is preceded by the
formation of an addition product Holleman [8] suggested in 1910 that the reaction
of nitration, like that of chlorination, consisted in addition, followed by splitting
off, according to the following scheme for chlorination:(5)A similar scheme for the nitration process was given by Reddelien [5] who
expressed the view that nitration of aromatic hydrocarbons with mixtures of nitric
and sulphuric acids gave addition products, e.g.(6)The product (III) undergoes decomposition, the group OH being attached to
H 2 SO 4 as H 2 O (IV). The addition product is hydrolysed by water, and mono- or
polynitro compounds are formed.
Mainly on the basis of Holleman’s hypothesis and studies on the nitration of
olefins, Wieland [9,10] assumed the addition of a nitric acid molecule to the
double bond, resulting in the formation of a cyclohexadiene derivative (V), fol-
lowed by the loss of a water molecule: