Autobiography from the 1960s to the 1990s. This book is an enthusiastic account of Pierre Laszlo’s life and pioneering work on catalysis of organic reactions…
A scientist and a writer
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Autobiography from the 1960s to the 1990s. This book is an enthusiastic account of Pierre Laszlo’s life and pioneering work on catalysis of organic reactions…
Carsten Reinhardt, Shifting and Rearranging. Physical Methods and the Transformation of Modern Chemistry.
Science History Publications, Watson Publishing International, Sagamore Beach, MA, 2006, ix + 428 pp., ISBN 0-88135-354-X, $ 49.95.
Organic spectroscopy applies physical methods to determining the structure of the molecules organic chemists isolate, make and test. It came of age during the Golden Sixties. The twin engines to lift it to prominence were mass spectrometry (ms), which engineers developed in the nineteen-fifties for analyzing hydrocarbons present in oil; and nuclear magnetic resonance (nmr), discovered in the aftermath of World War II. Carsten Reinhardt, an historian from the University of Regensburg, Germany, has now chronicled the early times of organic spectroscopy.
Organic spectroscopy rose in a bleak landscape. Available instrumental techniques were indirect (dipolemetry, ultraviolet electronic spectra interpreted with the Woodward rules, infrared spectroscopy), limited to small or highly symmetrical molecules in the gas phase (electron diffraction, microwave spectrometry), or yet excruciatingly labor- and time-intensive (X-ray diffraction).
Carsten Reinhardt. Shifting and Rearranging. Physical Methods and the Transformation of Modern Chemistry.
vii + 428 pp. figs., ill., app., index. Sagamore Beach, MA: Science History Publications/USA, 2006. $49.95 (cloth).
The history of chemistry after World War II is a relatively uncultivated field, not only compared with the chemical revolution in the late 18th century but also with chemistry in the 19th century. (In this respect, history of chemistry differs from history of physics.) And yet it can be argued that chemistry underwent a second revolution in the 1950s and 1960s, an “instrumental revolution” that profoundly changed the field. Carsten Reinhardt is not the first historian to call attention to this revolutionary phase, but he does it in a new way which focuses on the transfer of instrumental research methods from physics to chemistry. At the center of the transformation were instruments based on physical methods and knowledge, of which Reinhardt deals in particular with NMR (nuclear magnetic resonance) spectroscopy and mass spectrometry. The development of chemical NMR is the main subject of the chapters 2, 4 and 6, whereas mass spectrometry and its wide-ranging use in organic chemistry is examined in the chapters 3 and 5. In a final chapter on “The Spectrum of Methods,” Reinhardt summarizes and reconsiders the complex interplay of physical and chemical methods, both in academic science and as it influenced the academic-industrial collaboration.
Shifting and Rearranging – Physical Methods and the Transformation of Modern Chemistry
von Carsten Reinhardt, Science History Publications, Watson Publishing International, Sagamore Beach, MA, U.S.A., 2006, 428 S., XX,XX Euro, ISBN 0-88135-354-X.
Zur Strukturbestimmung chemischer Substanzen wurden bis in die Mitte des 20. Jahrhunderts im wesentlichen zwei physikalische Geräte eingesetzt: die Waage und das Thermometer. Es gab zwar bereits Geräte zur Bestimmung des Dipolmoments, des Brechungsindex, des pH-Werts und anderer physikalischer Größen, sie spielten aber im Alltag präparativer Chemiker eine eher untergeordnete Rolle. Das Thermometer (Schmelzpunkt, Siedpunkt, Mischschmelzpunkt) diente der Reinheitskontrolle, auf die Waage war man bei der Bestimmung der Elementarzusammensetzung angewiesen. Dass diese einfachen Geräte so wirkungsvoll eingesetzt werden konnten, lag jedoch vor allen Dingen daran, dass im Zentrum der Strukturbestimmung die chemische Reaktion, bzw. die Verknüpfung chemischer Reaktionen durch den Experimentator stand und die die eigentliche intellektuelle Leistung bei der Strukturbestimmung bildete.
Das sollte sich nach dem Zweiten Weltkrieg so tiefgreifend ändern, dass mit Fug und Recht von einer Revolution gesprochen werden kann. Diese hatte sich bereits durch die (recht langsame) Einführung von UV- und auch IR-Spektrometern angekündigt, brach jedoch erst dann wirklich aus, als NMR-Spektroskopie und Massenspektrometrie zu Routinelabormethoden wurden. Mit der „Übernahme“ der Strukturbestimmung durch diese beiden physikalischen Methoden beschäftigt sich das vorliegende Buch und auf sie bezieht sich auch der zunächst vielleicht ein wenig rätselhafte Titel.
Organic spectroscopy, the application of spectroscopic methods to determination of the structure of the molecules organic chemists are interested in, came of age during the Golden Sixties. The twin engines which lifted it to prominence were mass spectrometry (ms), which had been developed extensively in the nineteen-fifties when engineers analyzed the hydrocarbons present in oil; and nuclear magnetic resonance (nmr), which had been discovered in the immediate aftermath of World War II.
Organic spectroscopy arose out of a bleak, almost desertic landscape. In the early nineteen-fifties, available instrumental techniques were indirect only (dipolemetry, ultraviolet electronic spectra interpreted with the Woodward rules, infrared spectroscopy), limited to rather small or highly symmetrical molecules in the gas phase (electron diffraction, microwave spectrometry), or yet excruciatingly labor- and time-intensive (X-ray diffraction).
Newton’s Darkness: Two Dramatic Views. By CARL DJERASSI and DAVID PINNER. Pp. 184. Imperial College Press: London. 2003. £18.00, $24.00 (hbk); £11.00, $15.00 (pbk). ISBN: 1-86094-390-6 (hbk); 1-86094-390-X (pbk).
Newton’s darkness is threefold. In his science, there is an obscure undercurrent of alchemy.In his religion, there is a strand of heretical Arianism. And at the root of his sentiments, there is an area of repressed homosexuality. These darknesses play a role in the plays written by David Pinner and Carl Djerassi on Newton’s fights against Robert Hooke and Gottfried Wilhelm Leibniz.
Pinner’s dramatic view is called “Newton’s Hooke.” Here, Newton’s darknesses are only hinted at. What kinds of assistant are John Wickins and Nicolas Fatio de Duillier? Arius appears only once, at Trinity College, Cambridge, during the official redefinition of the Lucasian Chair; and Newton’s nocturnal alchemy is symbolised by a crucible covered with a cloth and the Star Regulus of Antimony as a gateway to the true Law of Universal Gravitation. But these alchemical experiments and theories should be left in the dark because, as Newton whispers, “the Art is not to be shouted abroad.”
The Road to Scientific Success: Inspiring Life Stories of Prominent Researchers. Volume 1. Edited by DEBORAH D.L. CHUNG. Pp. xi + 230, illus., index. World Scientific: Singapore and London. 2006. £33.00 (hbk); £17.00 (pbk).
ISBN: 981-256-600-7 (hbk); 981-256-466-7 (pbk).
Nature not Mocked: Places, People and Science. By PETER DAY. Pp. x + 262, illus., index. Imperial College Press: London. 2005. $48.00. ISBN: 1-86094-576-7.
Candid Science: Conversations with Famous Chemists. By István Hargittai, and edited by Magdolna Hargittai. Pp. xii + 516, illus., index. Imperial College Press: London. 2000. £48.00 (hbk); £21.00 (pbk). ISBN: 1-86094-151-6 (hbk); 1-86094-228-8 (pbk).
Candid Science V: Conversations with Famous Scientists. By Balazs Hargittai and István Hargittai. Pp. xiii + 695, illus., index. Imperial College Press: London. 2005. £34.00. ISBN: 1-86094-506-6 (pbk).
These four books elicit biographical information from the subjects themselves. They exemplify pitfalls of biography well-familiar to historians.1 They signal paths for biographers in general, oral biographers in particular. Their marginal value is to point to new directions which chemical science has entered.
One should not underestimate, as is currently fashionable, the merits of a biographical approach. To put it into a nutshell: “Read no history: nothing but biography, for that is life without theory.”2
Maurice Scève (1501?-1564?) is a major French poet of the sixteenth century best known for Délie (1544), a series of decasyllabic dizains dedicated to his beloved lady. He also wrote a most ambitious encyclopaedic poem, Microscosme (1562), embracing the whole creation. This paper analyzes in some detail the twelve lines he devotes to gardens and relates them to the contemporary art of gardens.
The molecule is central to structural chemistry; while the reaction holds a similar position for chemical dynamics. The trap for any history of the molecule is to swell into a history of chemistry. True, there is considerable overlap. But there is all the more need for focus that the molecule has just risen again to the apex of chemistry. The advent of molecular computers is imminent, some believe. Single molecule chemistry has become a research boulevard. ‘Vizualizing’ individual molecules is a related hype-producing topic. Duplicating by synthesis molecules of nature, however formidable, is now routine.
A book review by Tim Longville, in Hortus, 23(2), summer 2009, pp. 113-8
This book, unfussily but handsomely designed and produced (good paper, print given room to breathe, a central section of colour illustrations on art paper, sharply printed at a good size), is not about either gardens or gardening. But it is a book about plants and people and how the latter have used the former – for pleasure, profit and ‘psychological relief’ (including that provided by religious symbolism) – and therefore of considerable interest to any curious gardener. Its author is a retired professor of chemistry who has lived, taught and engaged in research all over the world, including in France, Britain, Belgium, Brazil, America and New Zealand. So, unsurprisingly, there is much in his pages about the biology and chemistry of his chosen group of plants – a group which of course includes all the many varieties of oranges, lemons, grapefruits and limes but also such relative oddities as calamandrins, kumquats and uglis. (At the end of one of the more formidable of those episodes of chemical analysis, he adds with characteristic charm – and the equally characteristic gentle teacher-ly hint that you could do better if you tried -, ‘You are forgiven if you skipped the last paragraph.’ Not all of the Professor’s scientific detail is formidable, though. Some is simply, ah, fascinating. For example, if I understand him correctly, the effects of Viagra are apparently increased by a regular intake of grapefruit, since that fruit contains chemicals [bergapten and bergamotin] which deactivate an enzyme in the small intestine which otherwise damages such ‘medications’ before they get into the bloodstream. Cue a rush on grapefruit once the news gets out?)