Catching Nature in the Act: Réaumur & the Practice of Natural History in the Eighteenth Century
By Mary Terrall
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At the center of Terrall’s study is René-Antoine Ferchault de Réaumur (1683–1757)—the definitive authority on natural history in the middle decades of the eighteenth century—and his many correspondents, assistants, and collaborators. Through a close examination of Réaumur’s publications, papers, and letters, Terrall reconstructs the working relationships among these naturalists and shows how observing, collecting, and experimenting fit into their daily lives. Essential reading for historians of science and early modern Europe, Catching Nature in the Act defines and excavates a dynamic field of francophone natural history that has been inadequately mined and understood to date.
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Catching Nature in the Act - Mary Terrall
MARY TERRALL is professor of history at the University of California, Los Angeles. She is the auhor of The Man Who Flattened the Earth: Maupertuis and the Sciences in the Enlightenment, also published by the University of Chicago Press.
The University of Chicago Press, Chicago 60637
The University of Chicago Press, Ltd., London
© 2014 by The University of Chicago
All rights reserved. Published 2014.
Printed in the United States of America
23 22 21 20 19 18 17 16 15 14 1 2 3 4 5
ISBN-13: 978-0-226-08860-0 (cloth)
ISBN-13: 978-0-226-08874-7 (e-book)
DOI: 10.7208/chicago/9780226088747.001.0001
Library of Congress Cataloging-in-Pubication Data
Terrall, Mary, author.
Catching nature in the act : Réaumur and the practice of natural history in the eighteenth century / Mary Terrall.
pages cm
Includes bibliographical references and index.
ISBN 978-0-226-08860-0 (cloth : alkaline paper)
ISBN 978-0-226-08874-7 (e-book)
1. Natural history—History—18th century. 2. Réaumur, René-Antoine Ferchault de, 1683–1757. 3. Naturalists—History—18th century. I. Title
QH15.T47 2014
508—dc23
2013016604
This paper meets the requirements of ANSI/NISO Z39.48-1992 (Permanence of Paper).
Catching Nature in the Act
Réaumur and the Practice of Natural History in the Eighteenth Century
Mary Terrall
The University of Chicago Press
Chicago & London
For Noah and Adam
CONTENTS
1 The Terrain of Natural History
2 Catching Nature in the Act
3 Seeing Again and Again: Illustration and Observation in Domestic Surroundings
4 Recruiting Observers and Training Philosophical Eyes
5 Natural Prodigies: Asexual Reproduction and Regeneration
6 A Spectacle Pleasing to the Mind: Natural History on Display
7 Chickens, Eggs, and the Perennial Question of the Generation of Animals
Epilogue
Acknowledgments
Notes
Bibliography
Index
1
The Terrain of Natural History
AN EIGHTEENTH-CENTURY READER familiar with contemporary natural history would recognize this passage by the Dutch naturalist and artist Pierre Lyonet as rather typical of the genre:
The fact [of insect respiration] seems to me clearly demonstrated for many kinds of aquatic insects; I mean those that one often sees lifting the end of the tail to the surface of the water, and remaining there as if suspended [from the surface]. These tails are their organs of respiration, and they only hold them thus in the air in order to breathe. To convince yourself of this, you have only to cover the surface of the water where they are kept, with something that prevents them from lifting their tails to the surface. Right away you will see them rush about and search with extraordinary distress for some opening where they can insert this extremity of their body. If they do not find such an opening, very soon you see them go to the bottom and die, often in much less time than it would take to drown the most delicate terrestrial insect. . . . Anyone who might wish to do this experiment should be aware that not all aquatic insects that breathe through the hind end die equally quickly when they are prevented from getting to the air.¹
This snippet of text exposes to view a peculiarity of insect life—the behavior of a particular kind of water bug, and the deduction that insects require air for respiration—alongside instructions for readers who might want to see such things for themselves. The naturalist-author assumes the participation of his readers, with such offhand phrases as those that one often sees
or you will see them rush about,
and demonstrates almost casually how to devise an experiment to test a proposition and how to reason from the results. Lyonet could almost be talking to someone across a tub full of aquatic insects (the water where they are kept
), giving his interlocutor the benefit of his long experience with such creatures. He knows how long it takes to drown terrestrial insects as well as different sorts of aquatic ones not enumerated here. He has evidently lived with these insects, not only watching their movements, but interfering with them—depriving them of air and timing their death throes.
In Lyonet’s day, natural history was many things to many people—diversion, obsession, medically or economically useful knowledge, evidence for God’s providence and wisdom, or even the foundation of all natural knowledge. Everything from the realms of animal, vegetable, and mineral became grist for the mill of its investigations. This science was so extensive and multifaceted, and practiced by such a variety of people around the globe, that it could hardly be considered a discipline, nor did its practitioners necessarily share institutions, training, or theoretical predilections. They were, however, unified by their dedication to observing, cultivating, chasing, collecting, experimenting, dissecting, preserving, drawing, and describing all manner of creatures (as well as plants and fossils and rocks). Pursuing these activities with varying degrees of intensity, they formed elaborate clusters and networks of exchange, collaboration, and debate.²
An exploration of these exchanges and disputes will expose the dynamics of the production of knowledge about the living world and the way that different kinds of people made natural history an intimate part of their daily lives. Natural history was at once diffuse, with its subject matter everywhere, and intensely focused, as its practitioners amassed minute and seemingly inconsequential details of structure or function. Working from the letters, drawings, and printed material that circulated through a dispersed community of naturalists, I attempt in this book to capture the motivations and interests that drove people to invest enormous time and effort into investigation of the intricacies of insects, worms, birds, and such. By picking out some interconnected individuals, studies of particular species, and large theoretical issues, I assemble a collage of scientific practices operating in different registers and on different scales across Europe and around the globe. Along the way, I examine the place of natural history relative to other sciences in the francophone world of the early Enlightenment. For the most part, I leave aside taxonomic questions, because these were not central concerns of the men and women whose observations and collections fill the pages of this book. In leaving aside taxonomy, I am, of course, leaving aside botany, where classification and nomenclature were central matters of debate.³ The natural history of animals, especially insects, was not primarily a taxonomic endeavor. My concern throughout will be to discover what went into making and consuming natural history and how these activities fit into the lives of those who found the details of the natural world around them so engaging.⁴ What did natural history mean to those who participated in it in one way or another? What drew them into such intricacies as the mechanics of metamorphosis or the mating behavior of mayflies or the sex of bees? How did they tie these phenomena to pressing theoretical issues like spontaneous generation or materialism? What techniques did they develop for seeing what had never been seen before?
In practice, boundaries between the sciences were generally fluid in the eighteenth century. Most fields, with the exception of medicine, required no particular training regimens, and men of science often moved among different subjects, from mathematics to astronomy to chemistry to botany. Many others, like Pierre Lyonet, pursued their scientific interests only when their other obligations allowed them the time to do so. This is not to say that there were no specialist traditions in these fields; certainly much of the knowledge produced in any of these areas was opaque to outsiders. But even when institutional divisions reified subject areas, as in the classes of the Paris Academy of Sciences, academicians frequently crossed these divisions between fields when choosing their research topics and staking their claims. In any case, the Academy of Sciences had no designated class of natural history, although natural historical observations and experiments found their way into virtually every meeting and every issue of its journal. Many of these reports were communicated by distant correspondents, making the institution a vital node in the informal network of naturalists and travelers worldwide.
Natural history was closely tied to the mission of the Academy of Sciences to test, authorize, and initiate useful knowledge of all kinds. It was also part of the larger culture of curiosity, amusement, and polite learning shared by urban and provincial elites. Partly because natural history encompassed so many areas and kinds of knowledge, it engaged readers, collectors, and observers without appealing to all of them for the same reasons. At the academy, natural history brought the institution into contact with its public, as systematic studies of particular creatures, substances, or phenomena took their places in the pages of the annual journal alongside eclectic and singular observations of curiosities or rarities, often sent in by distant correspondents. The semiannual public assemblies usually included a presentation on some natural historical topic, which would then be reported—often in considerable detail—in the press.
The central figure in this book is René Antoine Ferchault de Réaumur, preeminent naturalist of the generation before Buffon and a commanding presence on the scientific scene in Paris from the 1720s until his death in 1757. In exploring Réaumur’s world—his social relationships, his intellectual production, and the natural world he investigated so vigorously—I develop a picture of natural history that revises and complicates its characterization as a science of straightforward description, devoted to amassing observations as the raw material for taxonomic systems. In his classic work on the life sciences in the eighteenth century, Jacques Roger presented natural history before the landmark work of Georges-Louis Leclerc de Buffon as predominantly descriptive, rather than theoretical or interpretive, with an emphasis on the structures and mechanisms of animal bodies. Roger divided naturalists in this period into classifiers
and observers
; in this scheme, Réaumur was the prototypical observer, mired in providentialist theology. Roger contrasted Réaumur’s style of natural history to the philosophical, high-Enlightenment work of Buffon, whose sweeping gaze extended back to the beginning of time, across the ocean to the Americas, and down into the submicroscopic realm of forces and organic molecules.⁵ This historiography unabashedly privileges theory and synthesis, reducing natural history before Buffon to plodding catalogs of structures, with no room for general explanations or scientific laws. Réaumur, whatever his merits as an observer, could not break free of "the mentality [esprit] of the age, in effect blinkered by his theological orthodoxy.⁶
For the observers, according to Roger,
the structure of things is interesting for its diversity and for its perfect ‘fit’ with the way of life and the milieu of each species. . . . And the observer delights in seeing each insect use to perfection the tool that Nature gave it to do what must be done to survive and reproduce. But neither the observers nor the classifiers are much interested in ‘physics’ [la physique], that is to say plant or animal physiology. . . . By its very definition, according to the terms of the time, ‘physics’ is excluded from natural history."⁷ With no interest in physics, observers limited themselves to describing structures or mechanisms and admiring their design. This radical bifurcation between natural history and physics, based on the classical distinction going back to Aristotle between description and causal explanation, seems to miss the central character of natural historical investigation in our period. If we can avoid reading Réaumur through Buffon’s eyes, we will see that natural philosophy and experimental physics both entered crucially into natural history.⁸
Figure 1.1. R. A. F. de Réaumur, in formal dress, ca. 1735. Engraved by Philippe Simonneau from a painting (now lost) by A. S. Belle. Wellcome Library, London.
. . .
A close examination of the actual work naturalists were doing reveals the integral and sometimes surprising role played by experiment and measurement, through the direct application of techniques and instruments typical also of chemistry and physics. Marc Ratcliff’s research on the extensive networks of microscopists across Europe and Britain in the eighteenth century effectively collapses the distinction between observation and experiment, and explores one of the experimental aspects of natural history. By zeroing in on the microscope, he shifts his perspective from philosophy to practice, without losing sight of the philosophical ramifications of what observers saw with their instruments.⁹ In fact, naturalists often described their work as part of "la physique, meaning physical science broadly construed, or what in English was then called natural philosophy. This is a crucial point for understanding not just the methods used by naturalists but their conception of the whole enterprise. We even find Réaumur pointing out the common
spirit" shared by natural history observations and the techniques of the mathematician, to remind his readers that the naturalist does much more than describe and catalog whatever wanders across his field of view:
The spirit of observation, the kind of spirit essential to naturalists, and commonly assigned to them, is equally necessary to progress in every other science. It is the spirit of observation that causes us to perceive what has escaped others, that allows us to grasp the relations among things that appear different, or that causes us to find the differences among those that seem similar. We resolve the most difficult problems of mathematics only once we can observe relations that do not reveal themselves except to a penetrating and extremely attentive mind. Observations make possible the resolution of problems in physics as in natural history—because natural history has its problems to solve; it even has a great many that have not yet been resolved.¹⁰
How a wasp constructs its nest, how dragonflies mate, or how a clam propels itself are examples of such problems, and the solutions must come from watching the animals at work, rather than speculating about hidden structures or even about final causes.
Réaumur started out his scientific life as a mathematician; the parallels he finds among problem-solving in mathematics, in physics, and in natural history underscore not only some unexpected shared ground linking these fields, but also the pragmatic way that naturalists framed their questions. If we follow Réaumur in thinking of natural history as problem-solving, we are on the way to a richer conception of what it meant to do this kind of science. Some of the problems were indeed mechanical, as Réaumur notes. He includes under this rubric the operations by which an insect builds its cocoon, lays its eggs, changes its skin, or traps its prey—none of which could provide a basis for structural classification. To see the answer to a problem, the naturalist has to know how to look, how to be attentive, and very often how to devise ways of looking that will uncover hidden maneuvers or mechanisms—like the respiratory apparatus of the insect described by Lyonet at the beginning of this chapter. By observing the habitual lifting of the tail to the water’s surface in many different species, and then testing the consequences of preventing this behavior, the naturalist can not only describe but explain why the insects behave as they do. As in mathematics, finding the right point of entry into a question takes not just training and skill, but long experience.
The written histories of different species incorporated as much knowledge as possible—including anatomy, physiology, and behavior, as well as the useful consequences of this knowledge. Understanding the habits and physiology of a pest, for example, could inspire experiments on how to control it. The contemporary term history,
which I use here in preference to description, emphasizes the dynamic and fluid aspect of these accounts, which often move from anatomical details to narratives of mating behaviors or metamorphoses.¹¹ Writing these histories, and illustrating them, entailed sustained programs of experimentation and manipulation. Naturalists developed techniques of microscopy, dissection, feeding, confining, breeding, and simply watching and recording, all tailored to the various species that crossed their paths every day. When the naturalist wrote up a history
—or problem solution, in Réaumur’s language—he not only reported what he saw, but regaled his reader with tales of the procedures, tricks, and techniques that made the observation possible. These texts were histories of human investigations and histories of animal life at the same time, so that the hero of the narrative could be the naturalist or his subject, or both, depending on circumstances. The attentive reader of natural history books could learn as much about how to be a naturalist as about the habits and attributes of a particular insect or worm or spider.
INSECTS AND NATURAL THEOLOGY
The eighteenth century witnessed an efflorescence of providentialist natural theology drawing on many areas of natural knowledge. Book buyers indulged an apparently insatiable appetite for works of natural theology that used examples from natural history to reveal God’s hand in the tiniest details of nature.¹² But while insect enthusiasts in the eighteenth century were hardly averse to final causes or to seeing the handiwork of God in nature, most of them were not primarily motivated by theological considerations. Naturalists took for granted the existence of design and fitness in insects—a category in which they included everything from coral to worms to mites to aphids to butterflies and bees.
One revealing example of the complex relations between physicotheology and natural history can be found in the book where Lyonet’s comments on water bugs appeared. This was the French translation of Friedrich Christian Lesser’s Insectotheologie, originally published in German in 1738.¹³ Lesser, an erudite Lutheran pastor, amassed bits of evidence and arguments from sources ranging from the church fathers and the Bible to natural history works of every era, in order to demonstrate divine providence in the insect world. Before printing a French edition of Lesser’s work, the Dutch publisher asked Lyonet to look it over. Lyonet came from a Huguenot family and worked in The Hague as a lawyer, as well as a cryptographer and translator for the government. He was also a gifted artist, a collector of shells and fine art, and a fanatical observer of insects.¹⁴ Though he had not yet published anything of his own when asked to review the Lesser translation, Lyonet was well known locally for his ongoing study of the insects of the region. Writing to Réaumur, he described Lesser’s book, sardonically, as a work composed in the German style, where pedantic work and reading play a greater part than genius and direct experience.
¹⁵ As he made his way through the text, Lyonet could not restrain himself from correcting numerous factual errors and misapprehensions and adding extensive footnotes, sometimes so voluminous as to displace the original text entirely from the page.
In his annotations and explications, typographically distinct at the bottom of the page, Lyonet adopted the persona of a working naturalist, playing off the foil of the learned pastor. Lesser had culled his evidence from various authorities without distinguishing between them or evaluating them; Lyonet drew on contemporary natural history literature but frequently supplied his own very detailed observations to challenge generalizations and misstatements. His religious convictions were entirely in sympathy with those of the German author, but he objected to the sloppy use of natural knowledge to argue for God’s providence. Natural theology ought to be held to the same rigorous standards as natural history. In his notes, Lyonet sometimes simply corrected mistaken descriptions; sometimes he elaborated on a point made in passing in the text, explaining what he had observed in relevant cases; sometimes he undermined one of Lesser’s generalizations with detailed counterexamples; and sometimes, strikingly, he introduced his own radically new discoveries. In effect, Lyonet hijacked the original text and claimed it for his own style of natural history, a style very much informed by his reading of Réaumur. The first-person narratives of what he had seen with his own eyes or understood as a result of his own experiments contrasted with Lesser’s compilation from written sources, many of dubious credibility. In matters of natural history,
Lyonet admonished his reader, it is dangerous to admit the marvelous on simple hearsay; but neither must we reject everything marvelous, because it seems unlikely to us. One must examine nature, and pay attention to the proofs [of such marvels].
¹⁶ If an inexpert observer reports something without saying how he knows it, or how he was able to see it, or how he performed the experiment, the reader is justified in withholding acceptance of the result. If, however, a faithful and enlightened
author reports something extraordinary like the regeneration of a crayfish claw, if he explains that he cut off the claws of numerous crayfish, kept them under observation in jars, and charted the growth of the new appendages, I should believe it, however marvelous it appeared to me.
¹⁷ (The example here was an implicit reference to Réaumur’s study of regeneration in marine animals.)¹⁸ After completing his extensive notes, Lyonet convinced the publisher to include in the French edition two elaborate plates packed with meticulous illustrations drawn by himself, which only underscored the immediacy and legitimacy of his eyewitness accounts of insect behavior.
Figure 1.2. Pierre Lyonet, drawings of aquatic beetle, observed in captivity: male reproductive organs (figs. 13–15); female beetle constructing egg case (figs. 16–19). Enclosed in Lyonet to Réaumur, 17 May 1743. Ms. Fr. 99, Houghton Library, Harvard University.
. . .
Figure 1.3. Lyonet’s revision of Swammerdam’s four classes of insects. Drawn from life
by Pierre Lyonet; engraved by J. van der Schley for F. C. Lesser, Théologie des insectes (1742). Corrected proof copy of the plate enclosed in Lyonet to Réaumur, 22 February 1743. Ms. Fr. 99, Houghton Library, Harvard University.
. . .
By piggybacking on Lesser’s earnestly pedantic physicotheology, Lyonet undertook a kind of proselytizing of his own, for an observational natural history that took nothing on faith, that looked beneath the surface, and that could ultimately be made into more convincing and more legitimate evidence for divine wisdom. Many of the good pastor’s mistakes had nothing to do with the validity of his providential argument—they were mistakes of natural history, not of theology, and his commentator would not let them pass unnoticed. When Lesser mentioned that caterpillars lack ears, for example, Lyonet pointed out that caterpillar ears would not necessarily look like the ears of other animals, and it might not be so obvious how to recognize them if they did exist. In any case, he went on, we know next to nothing about the caterpillar’s ability to detect sounds. When Lesser asserted categorically that all living creatures breathe, Lyonet challenged the universality of respiration with evidence from his own experiments. In one of these, he took a large chrysalis, covered its stigmata with soapy water, and watched through a magnifying lens to see if soap bubbles would form as the chrysalis breathed. No matter how much attention I devoted, I never saw anything of the sort.
¹⁹ Then he tried carefully placing a bubble over each pore and watching to see if the bubbles expanded; they did not. In another case, when Lesser noted that insects lack intelligence, Lyonet insisted to the contrary that his own close observations had shown how insects can vary their actions according to the situation, and even, when placed in troublesome circumstances, where they would never naturally find themselves in the ordinary course of things, we see some that always make the best choice, and that know how to recover from mishaps and pull themselves out of very difficult situations.
²⁰ The naturalist, placing the insects in these situations to see what would happen, is irresistably tempted
to assign some degree of reason to these creatures.
In practice, in the heyday of physicotheology, natural history drew on much more than a reflexive providentialism. The reports of observers and experimenters, even those committed to providential theology, rarely put design arguments at center stage, and often were remarkably understated in this regard. The narratives and illustrations embedded in the effusive details that filled natural histories of insects yield many kinds of clues about a lively scientific practice that cannot be reduced to, or dismissed as, natural theology. This is not to deny that insect-watchers sometimes rhapsodized about the divine workmanship on display in the insect world. But this kind of physicotheology is often only the bare scaffolding surrounding the substantial edifice built from long hours of observation and experiment. As in the footnotes Lyonet offered as correctives to some of Lesser’s uninformed claims about evidence for God’s providence, that sustained dedication outweighed theological arguments, without necessarily challenging them.
The most accomplished and committed naturalists were driven by passionate fascination with their small subjects, often enriched with the conviction that knowledge of these elusive creatures might have practical as well as intellectual benefits. And beyond possible practical benefits—medical remedies, say, or methods for pest control, or new sources of textile dyes—they maintained a general but profound commitment to the progress of knowledge,
a sense that every new history of another species, whether mundane or exotic, contributed to the ever-expanding stock of knowledge about nature. The demonstration of God’s wisdom was more of a by-product than a motivating force, as naturalists used whatever methods they could devise to allow them to understand how spiders spin their silk or lizards grow new tails or dragonflies fertilize their eggs.²¹ In the painstaking observations of the naturalists,
Lorraine Daston points out, the argument from design became less an argument from evidence than an experience of self-evidence.
²²
NATURAL HISTORY IN PARIS
In Paris, natural history clustered around two institutional nodes, the Academy of Sciences and the royal botanical garden, the Jardin du roi. Most of the botanists in the academy had some affiliation at the garden, as did several of the chemists. There was considerable cooperation between academy and garden, usually mediated by personal friendships and patronage ties. In spite of the overlap in personnel, there was also a certain amount of tension and competition between the two institutions, and this intensified after the appointment of Buffon as director of the garden in 1739.²³ The francophone community of people observing insects and trading specimens, results, and drawings extended far beyond the borders of the Paris institutions, however. The botanical garden maintained a network of travelers and correspondents to supply its greenhouses and seed collections and other cabinets, and the academy also cultivated connections with naturalists reporting from distant locations, appointing particularly useful contacts as official corresponding members.²⁴ In addition to the experiments and observations produced locally, the academy became a clearinghouse for new observations of all kinds. Reports and specimens from distant places were presented at meetings and formally evaluated by academicians; some of them were then published in the annual journal. The publicity the institution could offer through its widely disseminated publications gave provincial naturalists or collectors living in colonial or commercial outposts an incentive to communicate novel, curious, or potentially useful observations. At the same time, many people pursued natural history far from the capital and communicated with each other locally, through networks that could bypass the capital entirely. Outside of France there were many other nodes of intensive natural historical activity, again with their own networks. Geneva was one such center, the Netherlands had several others, including The Hague, where Lyonet worked. Farther afield, in places like Madagascar and Cayenne, observers and collectors had their own operations. They make their appearances in our story when they communicate with Paris, but they had their local circles of exchange and collaboration as well, activities that usually left only sporadic traces in the archives.
The Parisian naturalist Réaumur, a prolific academician, proprietor of an ever-expanding collection, and the author of a multivolume work on insects, actively recruited collaborators and contributors to his various projects. In the service of his collections and his research programs, he maintained a voluminous correspondence, sending books and instruments across Europe and around the globe in exchange for specimens and letters. This correspondence gives considerable insight into the practice of many kinds of people, their various interests, motivations, and methods, as well as the questions they were asking. Some of them were looking for support for their own publishing ventures; some volunteered to contribute to Réaumur’s collections and to the academy’s journal; others were recruited for their special skills or for their access to distant locales. The observations and experiments presented directly to the academy represent only the tip of the iceberg of natural historical investigation in the period. I cannot pretend to survey all of the venues and all of the people engaged in these practices; instead I will draw on an eclectic sample of letters, published papers, and books to discover how this diffuse community operated, and to retrieve the meanings and values its members attached to their work.
KNITTING WITH SPIDER SILK
As an introduction to this mode of engaging with the natural world, I turn to an example from the first decade of the eighteenth century, when papers on insects and other small creatures started to crop up with increasing frequency in the minutes and publications of the academy.²⁵ These investigations often began as chance observations of odd phenomena, or as evaluations of novelties sent in from other places. The strength and use of the silk of spiders was brought dramatically to the attention of the Parisian academicians by a communication from their sister institution in Montpellier, the Royal Society of Sciences.²⁶ In December 1709, François-Xavier Bon de Saint-Hilaire read a paper on the usefulness of spider silk
to the public session of the Montpellier academy, where he was an honorary member, and then sent it on to Paris. Bon belonged to the lower nobility and served as a magistrate in Montpellier.²⁷ His paper reported on experiments on the fiber from the egg cases (coques) of short-legged spiders. He had found that the fibers could be made into serviceable thread no less beautiful than ordinary silk,
which could even be dyed. He passed around a pair of stockings and a pair of mittens knitted from spider silk, and he ended with a chemical analysis, displaying the distillation products and comparing their properties to those of silkworm cocoons. Bon also reflected on the benefits of natural history for someone like himself, who needed some respite from the press of his daily work. He did not need to remind his local colleagues of his considerable experience with natural history investigations in the years before he took up his hereditary position in Montpellier’s judicial administration. As a young man, Bon had worked with the famous Italian naturalist and adventurer, Count Luigi Marsigli, on his study of coral in the coastal waters near Marseilles. This had included chemical analyses similar to the distillations of spider silk.²⁸
Bon’s paper is much more than a description of spiders and their egg cases. The magistrate-naturalist had evidently devoted himself to watching spiders spin, examining their anatomy and physiology to discern the mechanics of silk production, as well as collecting, processing, and experimenting with the silk itself. He had lived with spiders over many months, pursuing a sustained investigation, with the help of anonymous assistants of various kinds. Curiosity, amusement, and utility all motivated his work. In order to determine whether spiders could be cultivated viably as a source of silk, Bon needed to know more about their life cycle and habits. I ordered all the large short-legged spiders found in the months of August and September to be brought to me. I enclosed them in paper cones and in pots; I covered these pots with paper pierced with several jabs of a pin, as I did with the cones, so that they would have air. I had flies given to them [to eat], and I found some time later that most of them had made their egg cases.
He obtained large quantities of additional egg cases simply by offering to buy them by the pound, just as one would acquire ordinary silk from silkworm cultivators. Thirteen ounces of the spider shells yielded four ounces of clean silk, more than enough to make a pair of stockings for the largest man.
²⁹
Bon’s spider paper has all the features of a typical academic memoir on a natural history subject. His methods—including direct observation, laboratory analysis, quantitative comparisons, and even the production of artifacts—put him squarely in the mainstream of natural historical practice. He systematically observed a variety of spiders, came up with a rough categorization (dividing them into long- and short-legged species), discovered their eating and mating habits, and kept them in captivity while they produced their egg cases. He performed calculations as well, comparing spider silk to the more familiar fiber made from silkworm cocoons. Although he did not conclude definitively that spider thread could be economically profitable, his comparison to silkworms was favorable on several counts, and he imagined that spider cultivation could yield practical benefits, represented materially by the stockings and gloves he showed to his confrères.
Bon was sufficiently pleased with his results to communicate them immediately to the Royal Society in London, where an English translation of his paper appeared in the Philosophical Transactions for 1710, as well as to Paris.³⁰ Exploiting his family connections, he wrote directly to Father Jean-Paul Bignon, the state minister responsible for the royal academies. Bignon asked Bernard de Fontenelle, perpetual secretary of the Paris Academy, to read a summary