Published online by Cambridge University Press: 05 January 2009
Since the eighteenth century chemistry has been deemed to be useful, yet how it might find widespread application, particularly in the case of its most advanced developments, was generally unclear. The discovery of synthetic dyestuffs has often been considered as the turning point towards much closer linkage between chemistry and the manufacture of useful products. How this occurred can best be seen in the case of August Wilhelm Hofmann, who for two decades after 1845 was director of the Royal College of Chemistry in London. As the teacher of many pioneers of the dye industry, Hofmann can be considered its first scientific leader. Indeed, the compounds he studied from 1860 were products made in the factories of his former students and assistants. They in turn were the first to recognize Hofmann's role in stimulating the practical application of science. Henry Armstrong, the chemist and educator, went so far as to imply that this was germane to Hofmann's pedagogic and research strategies: ‘it is clear that the influence he exercised in introducing scientific method into industry was in no sense accidental, but the considered expression of innate convictions’. These convictions were also encouraged by the need to attract funds from industrial sponsors for the Royal College of Chemistry, and they charged the rhetoric that served to enhance Hofmann's ambition and the discipline of chemistry before international audiences.
For contributions towards reinterpretation of the role of type formulae, I thank Willem J. Hornix. Henk van den Belt, Robert Bud, Ernst Homburg and Peter J. T. Morris are thanked for helpful discussions. For criticism of an earlier version of this paper I wish to express my gratitude to Seymour H. Mauskopf.
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8 In 1857, Kekulé had suggested the marsh gas, or methane, type. This led to the beginning of valency theory, and a move towards bonding formulations and modern structures as an alternative to types. Henceforth, it was possible to draw molecular structures for aliphatic compounds. The aromatic compounds, however, were expressed by graphie formulae only after 1865.
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14 McLeod recorded that ‘a friend of William Hofmann Dr. Clemm’ (Carl or August Clemm, soon to become partners in the forerunner of the Badische Anilin und Soda Fabrik) had been in London to obtain details of ‘Perkin's dye’. Clemm had tried to bribe a workman loyal to Nicholson, and, according to McLeod, was ‘tarred and feathered’ for his troubles. It is surprising that McLeod was unaware of the fact that Simpson, Maule & Nicholson did not manufacture Perkin's dye (mauve), or that they were the largest British manufacturers of aniline red, which was, no doubt, the object of Clemm's attentions. So, if we are to rely on McLeod's diary, Hofmann was not advising Nicholson on aniline dyes before the autumn of 1860, at the earliest. Clemm's nefarious activities do, however, attest to Nicholson's success as a dye-maker. McLeod Diary, 22 09 1860Google Scholar. See also Chem. News (1860), 2, 180.Google Scholar
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16 Referring to rosaniline and leucaniline, Hofmann described them as ‘the prototypes of two series of homologous colouring matters which cannot fail to be obtained from the homologues of aniline. Toluidine appears to yield perfectly similar bases’ (a claim which Hofmann later retracted). He had also subjected both rosaniline and leucaniline to treatment with nitrous acid – Piria's reaction, carried out at higher temperatures than Griess' reaction – ‘new bases being thus generated, the platinum-salts of which are remarkable for their fulminating properties’. Although Piria's and Griess' processes were poorly understood, they would come to feature greatly in the eventual structural elucidation of fuchsine dyes.
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