2. Precis of the biographical approach to scientific objects

Scientific objects are the entities, processes, and phenomena individuated, represented, investigated and used as tools in scientific practice. They have beginnings in time, when boundaries are carved around them; they are endowed with properties, which enable them to perform their epistemic functions; they have blind spots, for which they become subject to theorizing and experimental investigation; they are often laden with values and emotional significance; and they sometimes pass away, for a multitude of reasons. Because of these characteristics, they lend themselves to biographical narratives.

Biographical approaches to scientific objects have been developed by Hans-Jörg Rheinberger (Reference Rheinberger1997), Lorraine Daston (Reference Daston2000), and myself (Arabatzis Reference Arabatzis2006). In what follows I will focus on my own approach. ^{Footnote 1} In Representing Electrons, I argued that the life of objects of a particular kind, namely theoretical entities, has to be unpacked along two dimensions: positive and negative agency and synchronic and diachronic identity. The first dimension, agency, refers to the fact that scientific objects have lives in the sense that they guide, constrain, and sometimes obstruct research. On the one hand, they enable and facilitate inquiry by raising questions that become the subject of theoretical and experimental investigation. In that respect, they have a heuristic character. On the other hand, they constrain, or even frustrate, research by resisting theoretical manipulation, becoming incoherent when scientists endow them with novel properties. In both of these senses, positive and negative, scientific objects are alive. They are agents (i.e., active participants) in scientific practice.

What about the second dimension, the objects’ identity? The biography of any subject presupposes its stable (albeit evolving) identity. However, since the beliefs and practices associated with any scientific object vary across space and evolve across time, if we are to write its biography we need to know in what sense it remains the “same,” that is, a “unified object of enquiry” to use MacIntyre’s apt phrase (MacIntyre Reference MacIntyre, Rorty, Schneewind and Skinner1984, 38).

Thus, I found the biographical metaphor fruitful for two reasons: First, because it brings to center stage the issue of the identity of scientific objects. Scientific objects grow and mature, remaining at the focus of epistemic activity (theorizing, experimentation, manipulation, etc.), presumably without losing their identity. ^{Footnote 2} Second, because it highlights the heuristic power of scientific objects (their positive life) and draws attention to their recalcitrance (their negative life).

To these first two motivations, I would now add two additional reasons in favor of a biographical approach to scientific objects. First, biographies are associated with beginnings (births) and often endings (deaths). Thus, a biographical approach reminds us that scientific objects are historical entities, which emerge and often pass away. Second, scientific objects have an emotional dimension. For one thing, their “discoverers” often think of them as their offspring. For instance, both J. J. Thomson and Robert Millikan “wanted to be remembered as the father of the electron” (Goodstein Reference Goodstein2001, 59). For another, scientists often develop an emotional attachment to the objects that they study, an attachment that is associated with particular values and becomes evident when those objects are under threat of becoming extinct.

Let me elaborate on the biographical idiom. In Representing Electrons I suggested that the history of the electron’s representation can be narrated using metaphors such as “birth” and “character formation” (Arabatzis Reference Arabatzis2006, 43-44). When the electron was postulated in response to empirical and conceptual problems in late nineteenth-century physics and chemistry, a new representation of a hidden object was born. Various phenomena, from cathode rays to magneto-optics, were thereby linked as experimental traces of that object. Those traces were crucial for the individuation of the electron. After that initial stage, the electron gradually acquired a character, that is, specific properties (e.g., charge, mass, spin) and modes of behavior (e.g., ways of radiating within the atom). Although the electron’s character evolved, some of its properties proved robust and, thereby, it is possible to follow its lifeline across theoretical developments and different experimental situations. The electron’s lifeline, however, has not been broken, and we therefore cannot use it as a case study for understanding the death of scientific objects. ^{Footnote 3}

The biographical approach indicates several ways in which a scientific object may pass away. First, it may lose its identity, mutating into a different object altogether. This may happen, for instance, when the concept that denotes an object is “radically reconfigured, sometimes beyond recognition.” ^{Footnote 4} A symptom of that kind of death is the dissolution of the ties among an object’s observable manifestations. For instance, when phlogiston was “killed,” the connection between the combustibility of a substance and its metallic properties, both of which had been attributed to phlogiston, was broken.Footnote ⁵ Second, it may acquire multiple personalities, being endowed with different characteristics depending on the circumstances in which it is used. This also happened in the case of phlogiston, which by the end of the eighteenth century had turned into a protean entity, or so its opponents complained (Best Reference Best2015, 149). Third, an object may lose its heuristic power and its capacity to generate surprises, thus becoming sterile and of no use to further research. As I will indicate below, that may have been a reason for the death of the ether. Typically, when an object dies, it is replaced by another one, which takes over some of the epistemic functions of its predecessor (cf. Rheinberger Reference Rheinberger2016). The transition from phlogiston- to oxygen-based chemistry is one example of this replacement process.

3 The metaphorical character of “biography of objects”

According to Lakoff and Johnson’s now-classic book Metaphors We Live By, metaphors are “pervasive in everyday life” (Lakoff and Johnson Reference Lakoff and Johnson2003, 3). “Personification” metaphors, in particular, enable us “to comprehend a wide variety of experiences with nonhuman entities in terms of human … characteristics” (ibid., 33). Those metaphors may also have added value for historiographical and philosophical purposes. For our purposes, the biographical metaphor is a “conceit” that brings into focus salient aspects of the history of scientific concepts, the objects to which they refer, and the practices associated with them. ^{Footnote 6}

However, metaphors have limitations. They cannot be used without qualifications in the domain to which they are applied. The use of the term “biography” in connection with inanimate entities might create misunderstandings and give rise to extravagant claims. Thus, it is important to indicate the scope and limits of that metaphor. To that effect, I will draw upon the work of Mary Hesse on analogy and metaphor.

Hesse was concerned with analogies between different physical systems, but some of her insights are also relevant to our case. In Models and Analogies in Science, she drew a distinction between positive and negative analogies. Positive analogies comprise the properties that two systems have in common, whereas negative analogies concern the differences between those systems (Hesse Reference Hesse1966, 8, 58, 160).

The source and the target of the analogy in our case are, respectively, biographies of persons and biographies of scientific objects. The positive analogies between the former and the latter concern, among other things, the issues of identity and agency. Take identity first. In both cases we are dealing with the lifeline of an entity, either animate (such as a human being) or inanimate (such as a concept or an object). In an ordinary biography there is an obvious sense in which the biographee remains the same throughout his or her life. There is sufficient continuity in a person’s life to justify their selection as the subject of a biography. When it comes to the biography of a scientific object, however, one needs to show that the evolving representation of the object picks out the same “thing” and can, thus, become the subject of a coherent biography. ^{Footnote 7} If this cannot be shown, because the object in question has been radically reconceptualized over time, then prosopography will have to replace biography as the pertinent metaphor for studying the history of that object.

Moving to agency, there is a clear sense in which scientific objects are active participants in scientific practice. They play a heuristic role by giving rise to questions that generate novel theoretical and experimental work; and they often exhibit a recalcitrant character by becoming incoherent when new properties are attributed to them. There are limits to their agency, however, and it is here that Hesse’s negative analogies become relevant.

The negative analogies between ordinary biographies and biographies of scientific objects involve two issues: intentionality and reality. Scientific objects, unlike people, have no intentions. Furthermore, again unlike people, they may turn out not to be real, as happened with phlogiston, caloric, and the ether. In that sense, my approach is quite unlike that of Bruno Latour, who (in)famously wants to obliterate any distinction between human and non-human agents (cf. Schaffer Reference Schaffer1991).

As regards the death of scientific objects, there are both positive and negative analogies with the death of people. On the positive side, the death of scientific objects can be painful for their adherents and is associated, as in ordinary death, with feelings of loss and denial. On the negative side, the death of objects, unlike the death of people, is not an event but a process. The biographical metaphor suggests that the demise of scientific objects has the character of a brief extinction episode. However, as Hasok Chang has shown for the case of phlogiston and Jaume Navarro for the case of the ether, scientific objects may persist well beyond their productive phase, the period when they generate novel questions and results (Chang Reference Chang2012, Navarro Reference Navarro and Navarro2018b). So, their death is often a protracted affair. ^{Footnote 8} Furthermore, human death has a finality to it, whereas the death of objects does not preclude the possibility of their resurrection and revival. The history of the ether, as we will see below, exemplifies this possibility. ^{Footnote 9}

Before expanding upon this discussion of the death of scientific objects, it would be pertinent to briefly sketch a tentative taxonomy of objects I have suggested elsewhere. ^{Footnote 10} This taxonomy will indicate that the precise manner in which an object loses its life depends on the kind of object it is. Thus, an awareness of the plurality of scientific objects will further strengthen the biographical metaphor: in the life of objects, as in ordinary life, there are many ways to die.

4. The plurality of scientific objects and their modes of passing away

For analytic and historiographical purposes, it would be helpful to distinguish between several types of scientific objects:

• Natural entities (e.g., heavenly bodies) versus artificially created ones (e.g., certain particles in high energy physics).

• Regularities that occur in nature (e.g., planetary motions) versus phenomena that appear in the controlled environment of a laboratory (e.g., various effects in physics). The latter often do not occur in the wild.

• Manifest entities, the existence of which is undisputed, versus hidden entities (e.g., atoms), the existence of which is hypothetical, at least when they are introduced.

• Theoretical entities that resist experimental detection (e.g., dark matter) versus entities that are routinely manipulated in the laboratory (e.g., electrons).

These distinctions indicate that the demise of scientific objects may happen in different ways, depending on the type of object we are focusing on. ^{Footnote 11} For instance, natural entities are transformed into scientific objects via a classificatory scheme (think of “planets” in Ptolemaic astronomy) and die out when the scheme in question is abandoned. Artificially created objects, on the other hand, exist in the context of man-made laboratory conditions and pass away when those conditions are not in place. Sometimes we may even discover that they were not real to begin with, but mere experimental artefacts. ^{Footnote 12}

As regards the death of scientific objects, several questions need to be addressed:

• How and why does a scientific object pass away?

• When this happens, what is it that ceases to be? The representation of the object? The set of practices and skills associated with it? The values and aims embodied by it? Its explanatory function? Something else?

• Where does an object lose its life? Or, to put it another way, what is the geography of its death? ^{Footnote 13}

• For whom is an object considered dead and who persists in treating it as alive?

• How is an object’s demise received by its adherents? What emotional reactions are generated by its loss?

• What replaces an object after its death? How are its epistemic functions met by its successor(s)?

These questions are meant as an aid for exploring the demise of scientific objects and have to be “addressed at a local level, the level of particular kinds of objects” (Arabatzis Reference Arabatzis2011, 379). Hence the need for a taxonomy such as that outlined above.

Take, for instance, the distinction between manifest and hidden objects. The former are held together by conceptual ties, under a particular system of classification. Their demise goes hand in hand with the crumbling of that particular system, the realization that it does not “reflect a pre-existing order in the world,” and the rise of a novel taxonomic system (Arabatzis Reference Arabatzis2011, 383). The latter, on the other hand, are “inferred entities,” the existence of which is usually posited to account for certain phenomena. ^{Footnote 14} Their identity is fixed by their epistemic aim, namely the phenomena that they are meant to explain, and their properties, which are figured out in the process of fulfilling that aim. They may pass away in various ways and for various reasons, such as:

1. 1. Because of radical conceptual change: the concept associated with a hidden object changes so dramatically that the object is essentially wiped out (Chang Reference Chang2011, 415).

2. 2. Because the ties between the phenomena attributed to an object are dissolved (Chang Reference Chang2011, 419; Arabatzis Reference Arabatzis2011, 385).

3. 3. Because they give rise to intractable conceptual problems or resist persistently experimental detection.

4. 4. Because their explanatory potential is exhausted, and they consequently lose their fertility and become sterile (cf. MacIntyre Reference MacIntyre, Rorty, Schneewind and Skinner1984, 42; Clain and Maršálek Reference Clain and Maršálek2016, 263).

5. 5. A related reason: they become irrelevant to scientific practice. A hidden object may pass away not because scientists become convinced that it does not exist, but rather because it ceases to be a target of scientific investigation and to play any active role in theoretical and experimental research (cf. Rheinberger Reference Rheinberger2016).

6. 6. Because of Ockham’s razor: they become superfluous and are eliminated in the interests of conceptual economy.

7. 7. Because their epistemic aims cease to be considered important or legitimate. For instance, when non-accelerated motions ceased to be considered a legitimate explanandum, the medieval notion of impetus was discredited.

8. 8. Because some of their epistemic functions are taken over by competing objects. The death of a hidden object is often accompanied by the birth of its successor. Phlogiston was substituted by oxygen, caloric by molecular motion, and the ether by the electromagnetic field.

The point of the above was to make plausible the thesis that scientific objects, and in particular hidden ones, may die in different ways and for different reasons. Nevertheless, there are some common elements that are worth pointing out.

First, the death of scientific objects is often a process, rather than an event. They fade away rather than disappear instantly. ^{Footnote 15} This is easy to see in the case of manifest objects. Since their death goes hand in hand with the rejection of a particular system of classification and its replacement by another one, it is small wonder that it is an extended process. Moreover, in the case of hidden objects, the death-as-a-process-view is fully borne out by two salient instances: phlogiston and the ether. The persistence of the former well beyond the emergence of Lavoisier’s oxygen theory of combustion has been amply documented (Chang Reference Chang2012, chapter 1). As regards the latter, there is also abundant historical evidence that it did not abruptly disappear but gradually withered away over a period of three decades (Navarro Reference Navarro2018a).

Second, when a hidden object passes away, some of the practices associated with it become obsolete. Again, the phlogiston and ether cases are instructive. Experimental practices of phlogiston chemistry, such as the transfer of phlogiston between two different substances, and the theoretical practices of nineteenth-century ether physics, such as the construction of elaborate mechanical models of the ether, were abolished together with the objects that were constitutive of them. As Andrew Warwick has shown in a masterful study, “now discredited notions as the electromagnetic ether … were not only made familiar and legitimate entities to a generation of Cambridge mathematical physicists but routinely deployed by them in a number of highly technical and ongoing research projects” (Warwick Reference Warwick2003, 43).

Third, after the death of an object, history gets rewritten. What once was seen as a momentous discovery may turn into an unfortunate mistake. The examples of phlogiston and ether serve us well here too. Both objects were once considered very important discoveries. Joseph Priestley claimed that phlogiston “was at one time thought to have been the greatest discovery that had ever been made in the science. … [T]here had hardly been any thing that deserved to be called a discovery subsequent to it” (quoted in Conant Reference Conant, Conant and Nash1957, 169). And Henry Williams asserted that the ether’s “discovery may well be looked upon as the most important feat of our century” (Williams Reference Williams1901, 231; cf. Swenson Reference Swenson1972, 137).

5. The life and death of the ether

The ether was a preeminent object of nineteenth-century physics and its history has been meticulously studied (Whittaker Reference Whittaker1951; Swenson Reference Swenson1972; Schaffner Reference Schaffner1972; Cantor & Hodge Reference Cantor and Hodge1981a; Navarro Reference Navarro2018a; Navarro Reference Navarro, Forstner and Walker2020). ^{Footnote 16} It was considered an all-pervading medium that was able to store and transmit energy. Its main function was to provide the resources for understanding light and electromagnetic phenomena as continuous wave processes.

The term “ether” goes back all the way to Aristotle, who regarded ether as the fifth element, the constituent of the heavens. The representation and epistemic function of Aristotelian ether were thus worlds apart from those of its nineteenth-century counterpart. In the early modern period, Newton conceived the ether as a medium that conveyed gravitational forces; its main function was to dispel the specter of action at a distance. In the eighteenth century, several ethers were put forward to account for other prima facie action-at-a-distance phenomena, such as electricity and magnetism (Swenson Reference Swenson1972, 37; Heimann Reference Heimann, Cantor and Hodge1981). Those ethers, however, fell short of their epistemic aims. As Maxwell pointed out in 1878, in his Encyclopaedia Britannica entry on the ether, “the nature of the motion of these media” remained obscure and their proponents could not show how they “would produce the effects they were meant to explain” (Maxwell Reference Maxwell and Niven1890, 764).

Another ether, however, proved to be more robust. It was the ether “invented by Huygens to explain the propagation of light” (ibid.; cf. Swenson Reference Swenson1972, 9). After receiving a boost in the early nineteenth century, when Thomas Young and Augustin-Jean Fresnel made it the foundation of the wave theory of light, the “luminiferous” ether enjoyed a thriving career. In the 1860s, Maxwell employed the ether in his construction of electromagnetic theory. His calculation of the speed of electromagnetic waves indicated that it was close to the velocity of light. Thereby, the luminiferous and the electromagnetic ether merged into a single object. That fusion led to tremendous theoretical and experimental achievements, such as the unification of electromagnetism and optics, and Heinrich Hertz’s confirmation of Maxwell’s prediction of electromagnetic waves (Swenson Reference Swenson1972, 100).

By the late nineteenth century, the ether had become well-entrenched in physics. Physicists in Britain and on the Continent thought of the ether as the best established entity of natural philosophy. Three examples would suffice to show this. First, Maxwell claimed that “there can be no doubt that the interplanetary and interstellar spaces are not empty, but are occupied by a material substance or body, which is certainly the largest, and probably the most uniform body of which we have any knowledge” (Maxwell Reference Maxwell and Niven1890, 775). Second, in 1884 William Thomson asserted that the ether “is the only substance we are confident of in dynamics. One thing we are sure of, and that is the reality and substantiality of the luminiferous ether” (quoted in Swenson Reference Swenson1972, 77). And, third, Hermann von Helmholtz, in his preface to Hertz’s The Principles of Mechanics, expressed his commitment to the ether in no uncertain terms: “There can no longer be any doubt that light waves consist of electric vibrations in the all-pervading ether” (quoted in ibid., 101). The ether’s epistemic status was now perfectly secure.

Furthermore, by that time the ether had become the center of epistemic activity in theoretical and experimental physics: “the major problems in physics seemed to divide into two broad categories, namely, the physics of matter and the physics of the aether” (ibid., 28; cf. Cantor and Hodge Reference Cantor, Hodge, Cantor and Hodge1981b, 50-53). Physicists theorized about it, used it to explain and predict optical and electromagnetic phenomena, and designed experiments to study its interactions with matter. The ether, thus, provided the foundation for a “theory of everything,” including the structure of matter (Kragh Reference Kragh2002). As Joseph Larmor, one of the protagonists of British ether physics, put it, theoretical physics had become the “science of the aether” (Larmor Reference Larmor1911, 292; cf. Swenson Reference Swenson1972, 165; Navarro Reference Navarro, Forstner and Walker2020, 285). By implication, the death of the luminiferous/electromagnetic ether in the early twentieth century must have left the older generation of physicists, who had invested so much in its existence, without their main object of study; but more on this below.

Several historians have used biographical language to narrate the vicissitudes of the ether. Loyd Swenson’s study of the Michelson-Morley experiment is framed in biographical terms: the aim of The Ethereal Aether was to “narrate how Michelson’s great failure, and its conceptual raison d’être, the aether, were born, suffered, and died” (Swenson Reference Swenson1972, xvi). Jed Buchwald, at the end of his article on “The quantitative ether in the first half of the nineteenth century,” pointed out that “the hypothesis of the molecular ether gave birth to the science of the differential equations of wave optics” (Buchwald Reference Buchwald, Cantor and Hodge1981, 233). Here the biographical metaphor was connected with the productive role of the ether hypothesis. The same theme is found in a later essay by Buchwald, this time on the role of the ether in the emergence of microphysics in the early twentieth century (Buchwald Reference Buchwald and Daston2000). ^{Footnote 17} Biographical language can also be found in several of the contributions to the recent collection Ether and Modernity (Navarro Reference Navarro2018a). Here the motivation for a biographical approach is to trace the “multiple lives of the ether in the first decades of the last century … [from] pure mathematics to wireless technologies, from modernist art to spiritualism and from popular to alternative views of physics” (Badino and Navarro Reference Badino, Navarro and Navarro2018, 2). Furthermore, in that collection we see three themes that could further justify a biographical approach to the ether: its identity, its heuristic character, and its recalcitrance. ^{Footnote 18}