René Descartes (1596–1650) is regarded as one of the leading figures, if not
Descartes is a protagonist of the conventional narrative about early modern natural philosophy, which starts with a description of a field steeped in scholastic (or Aristotelian) traditions; this is then surpassed by a Cartesian approach around the mid-16th century, which in turn is overthrown by the Newtonian scientific doctrine. According to this narrative, the result was an entirely transformed field by the beginning of the 18th century, one in which experimental methods were the norm. This is the standard account of the Scientific Revolution; that is, through a radical break with what was previously considered “normal science,” the field was completely altered by a new set of scientific principles (Hall, 1966; Koyré, 1957; Kuhn, 1962). In recent decades, this narrative has been challenged by a reappraisal of the importance of scholastic philosophy and an emphasis on the hybridization of different views (Garber, 2016; Gaukroger, 2006, 2010, 2016; Schmaltz, 2016). The idea of one tradition radically superseding another is now seen to be an oversimplification, and such scholarship encourages us to recognize the heterogeneity of early modern natural philosophy.
Despite their undeniable value, current studies usually focus on Descartes as the main driver of change in philosophical and scientific thought. Moreover, existing scholarship tends to work within narrow national or language boundaries in the appraisal of epistemic change in the history of science. Such premises overlook the larger social environment in which Descartes moved and lack an integrated view on the
While we can now move on from the idea of radical breaks in philosophical tradition, the narrative about the three “main traditions” should not be done away with too hastily, as it offers a construct from which we can move forward. In a previous study, for example, our data corroborated the hypothesis that these three “traditions” remain relevant in categorizing the different approaches developed during the period (Sangiacomo et al 2022a). The questions to be answered now are how the alternative hybrid view can be explored further and what methods are appropriate to do this. If used carefully, I suggest that a network approach can provide a suitable and effective methodology.
Historians are no strangers to using network terminology. We are often reconstructing social networks by referring to an individual’s connections and environment and, as such, the “networked positions” of historical actors have often been described, albeit generally from a qualitative perspective. In the past decade, quantitative, data-driven historical network research has seen a rise in popularity (see, for instance, the edited volumes of Brughmans et al., 2016; Kerschbaumer et al., 2020; Raymond & Moxham, 2016), with specific attention being given to early modern networks, such as in Van den Heuvel (2015), and most notably correspondence networks (in the projects of The article by Ryan and Tolonen (this issue) that deals with publishers in the Scottish Enlightenment is a rare example, as they point out: traditional scholarship teaches us a lot about a few individual publishers, but systematic studies of publishing diversity are virtually nonexistent.
Bipartite networks are networks with two types of nodes, allowing the researcher to use a shared attribute as an indicator of an underlying social connection, such as affiliation (Borgatti & Halgin, 2014). This indirect approach is highly useful, especially when faced with limitations in gathering data, such as is often the case with historical subjects. Additionally, human social interactions are often not limited to one specific environment or means of interaction. Multiplex or multilayer networks, that is, several networks of the same group of individuals with different connections in each layer can alleviate this problem by offering multiple layers of connectivity. One can think of a network with a layer for work connections and a layer for friendship connections, which will reveal different kinds of patterns individually, but together can deepen our insight into an actor’s connectivity. Studying the spread of Cartesianism can therefore benefit from a multiplex, bipartite approach. For historical research, network studies that include multiple layers remain underrepresented (De Valeriola et al., 2022; Valleriani et al., 2019) and examples of historical bipartite networks and their projections are even rarer (Riva, 2019; Vozár, 2018). Networks that capture temporal changes are especially underdeveloped in the historical context, though examples can be found (Petz et al., 2020; Vugt, 2017).
In this study, I will explore the intersection of bipartite, multiplex, and diachronic networks to comprehensively investigate the spread of Cartesianism in 17th-century natural philosophy. Specifically, I will address two research questions. Firstly, what can be said about the social profile and network embedding of the authors who were prominent in the field, and were they instrumental in spreading or popularizing Cartesian approaches? Secondly, within these networks, do “the old” (scholastics) and “the new” (particularly Cartesians, and to some extent eclectics) coexist in diverse environments, or do most authors belong to subcommunities where a single tradition prevails? For both these questions, I am interested in the development of the field over time to see whether, at several time-intervals, a change in the status of certain authors and the diversity of the environment can be observed. My analysis will help to determine whether and to what extent novel approaches were integrated and adopted among a broad range of intellectuals in the 17th century.
Through a selection of network-based approaches, I will investigate these questions by focusing specifically on two matters: (1) node prominence and (2) network diversity. With regard to the former, the networks are used to analyze the authors’ situation in relation to others in the network and to investigate who held potentially important or influential positions. The idea is to look for individuals who, by their positions in the network, could have had access to relevant information or been able to fulfill pivotal roles in distributing new ideas. Likewise, when such central authors were “old school,” that is, “scholastic,” they could potentially have been powerful agents for the preservation of the traditional ways. Regarding the second matter, network diversity will be examined by looking at the occurrence and spread of different types of authors across networks to see if any homophilous tendencies emerge. Network homophily refers to the idea that people often associate with others who have similar properties. Such patterns have been studied within many types of social networks (e.g., racial and gender segregation (Shrum et al., 1988), music taste (Baym & Ledbetter, 2009), or political networks (Esteve Del Valle, 2022)). In this article, the “type” of an author is determined by an allegiance to one particular traditional approach, using categories of philosophical traditions (which will be explained in more detail below). Diversity, therefore, is understood here as a social environment in which authors typically did not belong to one specific scholarly tradition.
Although I mention diversity, a certain homogeneity is also to be expected since the material used to build the corpus (the sources and details of which are explained in the next section) is meant to reflect the literature of one particular field, namely natural philosophy. Because of the field-boundaries, the authors in the corpus are rather similar in certain respects: upper-class men (and one woman, the British Margareth Cavendish (1623–1673)) with a formal education in natural philosophy. At the same time, given these boundaries, the network approach allows us to distinguish more subtle differences between authors and their social embeddedness and local discontinuities.
My findings show that in all regards, Descartes’ networked position was already very fortunate by the time he published his famous
This study covers the geographical range of the Netherlands (or Dutch Republic at the time), France, and Britain.
Geographical borders at the time were not the same as today’s, but to a large degree, they do coincide for these three countries. Regardless, the demarcation of borders and the decision of who to include based on their nationality have been based on the selection as it appears in the corpus’ source. More about this in section 2. From existing scholarship, we know that after 1700, Cartesianism had certainly not disappeared, but by then Newtonian science had started to emerge. This brought about entirely new dynamics, mostly in the area of the Dutch Republic and Britain (Hutton, 2004; Schmaltz, 2017). The developments of the field toward Newtonianism will be dealt with in a separate study, because they constitute a further transformation of the field of natural philosophy in the 18th century, with different focal points.
The data corpus is based on the thorough scholarship contained in the voluminous Bunge et al. (2003), Pyle (2000), Yolton et al. (1999), and Foisneau et al. (2008).
The resulting database lists the authors, their publications, and publishers, together with several attributes of these entities. The data was processed to create four author-to-attribute edge lists for the bipartite multiplex network.
Network node and edge date can be found at I refer to them interchangeably as knowledge ‘environments’, ‘circles’ or ‘spheres’.
While they can serve as a rich source of information, in their bipartite form, these networks are problematic for two reasons. One is that the two-mode nature of the networks (including two different node types, the authors and a particular circle) is difficult to analyze using the most common network analysis tools. This problem can be overcome by creating “projected networks,” in which only one node-type remains and analysis can, for the most part, be carried out using regular network analysis measures. The second problem is that the networks as a whole cover an entire century, which makes it difficult to make detailed inferences about the data. Thus, to fully grasp the field’s development, I have divided the networks into a few specific timeframes, allowing for progressive and chronological assessment of the networks.
In a network projection, the network data containing the ties between two different node sets is compressed to show the connections within one of the node sets, tying the nodes based on a shared neighbor node. This approach considers the shared spaces as potential environments where social ties could develop, with subsequent opportunities for the exchange of ideas between the nodes. In fact, even though one-mode (nonprojected) networks are most common, many real-world social networks may be modeled quite naturally using bipartite structures, representing members and the groups to which they belong (Latapy et al., 2008). Some scholars even suggest that
Since the authors are the constant factor in the multiplex network, and my current analytical interest relates to them, it is their projections that are considered here.
Alternatively, a projection of the environments could be made, where for instance two universities would be linked if they employed the same author. This is less justified, especially for Layers 1, 2, and 4, since these are institute and city-nodes without (human) agency and, thus, less suitable for social network analysis. Furthermore, the authors are the initial source for the networks, making their information more complete, as opposed to projections of the circles that are only gathered through this particular set of authors. Building and measuring the networks was done with the Python library NetworkX.
In the projections, each tie receives a weight value attribute, representing the number of common environments the authors have, such as a university. By using weighted projections, information about the number of different connections that exist between two unique authors is maintained (Vasques Filho & O’Neal, 2018). Nevertheless, with the creation of a projection, some information from the bipartite structure is lost, such as the specific environment shared by a pair of authors and how prominent that particular node was in the network. Applying weighted edges can alleviate some of this information loss, although in principle, some information still becomes inaccessible in the projections. However, for analytical purposes, the original networks can always still be used as a reference, as I show in the following analysis.
The study of temporal dimensions in networks is currently at an underdeveloped stage, and there is no consensus of how such studies should be done (Graham et al., 2022, p. 227).
Time-slicing, or creating chunks of time at particular intervals, is a frequently used approach for analyzing networks over time. There is no “right” way to temporally divide a corpus, and it could even be argued that any chronological split of the corpus is altogether arbitrary. There are no comparable examples of the approach I have taken to slicing the multiplex network here.
Ultimately, the approach adopted depends on the goals of a study, the data that is available, and how it can offer historians “novel ways to think about the multiple dimensions of change” (Lemercier, 2015). In this case, the data corpus covers over 100 years, and there are three “time-stamps” collected based on the information from the For author-affiliation, 34% is unknown or none. Of the life-span information, one-fifth is unknown. Only two titles, dissertations by the French Paul Bacuet (1626–1670), have unknown publication dates. These can be estimated at 1634, the year he published another
Description of the time slices for each network layer.
1 | Pre-Cartesian | 1586–1637 | 51 | 36 | Netherlands, Britain, France |
2 | Cartesian | 1586–1687 | 101 | 160 | Netherlands, Britain, France |
3 | Newtonian | 1586–1700 | 114 | 175 | Netherlands, Britain, France |
Subsequently, the slicing is determined by the publication dates of the seminal works that typify the intellectual turning points of the century. These seminal works are Descartes’ Note that this is not to indicate that Newtonian science from this point onward was widespread; the cut-off point indicates the date from which we can consider the appearance of the well-known major competitor for Descartes.
The final multiplex network consists of four layers with three slices each: dividing the multiplex into these time frames results in a total of 12 sublayers for analysis. The networks are accumulative; that is, for every new slice, publishing authors in that time range are added, but previous ones do not disappear. While the odds of two authors being alive at the same time decrease, accumulative networks can be made intelligible by realizing that an author at the end of the century would have had access to the information published by authors they are tied to. Even when the latter author was no longer alive, the influence of their work would have extended forward in time as their publications were still part of the field. We can envisage how this works by imagining, for instance, the University of La Flèche educating and then employing Pierre Gautruche (1602–1681) during most of the years between 1624 and 1653, increasing the odds that he was familiar with authors like Etiènne Noël (1581–1659) and Marin Mersenne (1588–1648), who some years (or decades) before his arrival were active in the same city, studying the same field and writing on related subjects. It seems highly probable that Gautruche would have been acquainted with the work of Noël and Mersenne and thus they are linked in the network.
Formal quantitative analysis of social networks commonly uses measurements of centrality. High centrality values are associated with occupying positions of some kind of importance or visibility and are therefore important measures for revealing important individuals or groups in a network. Three centrality measures are taken into account when analyzing the slices in the multiplex. These are degree, betweenness, and eigenvector. Degree is the number of direct ties an author has. High degree authors would have had a high potential
Betweenness gives a value based on the frequency with which a node (an author) falls in between a pair of other nodes (authors) on the shortest path connecting them in the network. As such, it is more closely related to potential Network measurements are done on the weighted projections using NetworkX, a Python package for creation and analysis of networks. Details and equations can be found on (
Higher scoring authors are most likely to have been involved in the development of the field. They would have had particular advantages that enabled them to fulfill positions of importance, where they were either influential themselves or influenced by others, based on their structurally central position in a particular network. At the network level, “being central” is determined quantitatively, explicitly omitting a predetermined idea of who should be considered central or prominent.
In the assessment of the results, I focus mostly on the authors who score the highest on several of the centrality measures. Their position and relevance are further determined by assessing biographical information in secondary literature. Finally, by taking a close look at the particular works written by these central authors, a more comprehensive understanding of them as potentially important authors emerges.
Since I work with projected networks primarily, proximity can easily be misunderstood as social similarity; that is, two authors tied to one university become directly tied in the projection. In a sense, this does indeed denote similarity, because they had the same professional environment, but they may have taught competing views on a topic, and this is invisible through this bird’s eye view. To create a more nuanced picture, assortativity can be measured.
Assortativity is a measurement of
In the time slices, I measure assortativity of the “tradition” attribute, to consider whether authors tend to be linked to authors within the same philosophical tradition. For instance, are Cartesians found in environments that are filled with other Cartesians (indicating assortative mixing), or are they found among other types of thinkers, such as Newtonians, scholastics, or eclectics (indicating disassortative mixing)? The measurement can indicate how mixed these author communities were with regard to their scientific practice and therefore can help with answering the main question about the diversity of the environments, in terms of traditional allegiance. It is to be expected that the networks overall become more diverse over time, based on the introduction of new categories in each time slice such as “Cartesian” and “Newtonian,” and the question is how these traditions existed alongside each other. An earlier assessment of the projected networks of the overall corpus has already shown a neutral to slightly positive score on assortative mixing of the traditional categories, but this study included only “primary authors” (the authors of explicitly systematic works dealing with natural philosophy) (Sangiacomo et al., 2022b). Now, the network has become more complete and the introduction of time slices has made the results more comprehensive.
Limitations to the application of centrality measures to historical networks must be taken into account. Results for high degree and eigenvector will show typical projection-cliques (see Figure 1), causing the main clusters to have the highest degree authors, with these authors appearing at the top.
For instance, we see high clustering reflected in a very high level of “triadic closure” (in layman’s terms, this is captured in the phrase “a friend of my friend is also my friend”). This is measured with the transitivity clustering coefficient, indicating the level of situations where, if a relation “∘” is transitive, and a ∘ b, and b ∘ c, then a ∘ c is implied (Newman, 2010, p. 198). Values for transitivity were found to be very high, ranging from 0.7 to 0.9 (1 being perfectly transitive).
For example, in the affiliation layers, top degree and eigenvector positions are occupied by the Dutch authors because many of them were at Leiden University, the most popular university overall, and they shared one or two other university affiliations. Regardless, this still shows us which environment was the most tightly knit, namely that of the Dutch universities. In addition, the well-connectedness would have allowed for a more frictionless transmission of knowledge in the Dutch university circles. The kind of interconnectedness we see among these authors is not nearly as prevalent in the French and British spheres. By using weighted graphs, the cliques are more refined as some of the original information is maintained and presented. The inclusion of betweenness centrality can also further nuance this analysis.
On a general level, careful consideration is necessary in regard to the interpretation of the results, since the quantitative methods are not specifically attuned to historical contexts (De Valeriola, 2021; Düring, 2016). This means we can expect difficulties using these measures as simple indicators for social centrality as it is commonly understood. It is more intelligible to view these measures not as proof, but as
In terms of capturing the spread of Cartesianism, Slice 1 is the most limited, with only 36 authors. Measurements are less likely to be significant or even legitimate because of the small sample size and are not, therefore, taken into account for the Slice 1 subsample. The slices for this period do, however, provide a starting point of sorts, allowing us to see how natural philosophers were already connected in several spheres. The network graph visualizations
All visualizations are made in Gephi version 0.10.0 (Bastian et al., 2009), using the
In my treatment of the results, Layers 1 and 2 are taken together as “affiliation layers,” and Layers 3 and 4 as “publisher layers.” Dividing them in this manner enables a consolidated discussion of the results, as Layer 1 relates to Layer 2, with both covering a dimension of an author’s social embeddedness through their affiliations. The same applies to Layers 3 and 4 via their links with publishers. See Appendix A and B for detailed tables with network descriptions and measurements, including,
In the first slices of Layers 1 and 2, there are distinctive clusters of authors coming from circles in Paris and Leiden. Since this is the “starting slice,” there are not yet any Cartesians (except Descartes himself). About half of the authors in the first slices are considered Aristotelian, the other half either eclectic or not specified. Within these categories, eclectic authors are mostly found among the French.
Compared to the first slice, Slice 2 represents a great expansion of authors in the field, with the network now including 160 authors, spanning the years 1586–1687. As expected, there are some high-density clusters, making it possible to discern groups that were active in similar environments, be they universities or cities. In Slice 2, there are 31 Cartesians and only 3 authors who are labeled “Newtonian” (apart from Newton, these are John Wallis (1616–1703) and Robert Hooke (1635–1703)). Newton himself is central in Layer 2, Slice 2 (high betweenness), but the other two Newtonians are not. Here, Newton is positioned well in these knowledge circles due to his ties to other authors with diverse backgrounds, including those of the Royal Society and the University of Cambridge, such as Pierre Du Moulin (1568–1658, scholastic) and Kenelm Digby (1603–1665, scholastic), who is in turn associated with the Mersenne Circle (more about Mersenne below). Zooming in to the center of Layer 2, slice 2, Figure 3 shows clearly that there are groups of authors with stronger ties between them (thicker lines) within the clusters. We see these stronger connections especially in the Dutch (orange) and British (green) clusters, but less in the French (blue), suggesting that French authors had fewer locations in common with each other. This could mean that the French were either less mobile (e.g., gravitating toward Paris) or more diverse (e.g., visiting entirely different cities to their colleagues).
The third slice is slightly larger, now including all the authors up to the turn of the century. It includes 175 authors from 1586 to 1700 and thus can be said to capture the entire field of natural philosophy in the 17th century in the Netherlands, Britain, and France. The small number of additional authors introduces a shift in both central authors and their diversity. There are now 36 Cartesians but no additional Newtonians. The Dutch become more prominent, now with Herman Boerhaave (1668–1738, eclectic), Nicolaus Hartsoeker (1656–1725, Cartesian), and Christiaan Huygens (1629–1695, eclectic) high on the lists. Bernard Connor (1666–1698, tradition n.a.) is the only central British (or rather Irish) author, a position resulting from his education in central locations in France (the universities of Paris, Montpellier and Reims) and subsequent affiliations with the universities of Oxford and Cambridge, as well as the Royal Society and Royal College of Physicians. While Connor’s position, stemming from his noble birth and connections to prominent affiliations, was excellent, his contributions were less in the field of natural philosophy and more related to historical and medical research (Stone, 2004). For instance, he published a work explaining miracles using the principles of medical knowledge (
Homophily scores for “tradition” are positive overall, although they are just above 0 (between 0.02 and 0.04), and strongest in the first layer, indicating that the networks tend to be
The topology is similar to Slice 3 in Layer 2 (co-affiliation city), only with denser (more populous) clusters. The visualization reflects the numbers; that is, clusters are not entirely dominated by authors of a particular tradition, but there is some particular grouping. What the visualization adds is insight into how they are spread throughout the network. Some traditions are more prevalent in certain groups than others. For example, Cartesians (red) are mostly found in the prominent Dutch and the French environments, and the three Newtonians (blue) are found in the one cluster of authors mostly connected by their co-affiliation with the University of Oxford and the Royal Society. Scholastic (yellow) authors pervade the entire network, as do eclectic authors or those with no specific allegiance (both gray).
As the graph shows, the Newtonians are certainly not isolated, but their clique does not include any Cartesians. The eclectic Huygens and Boerhaave, who score highest betweenness values in Layers 1 and 2, bridge the Newtonians to the Dutch knowledge spheres with their membership to the Royal Society and to one or more Dutch universities, while also having ties to authors affiliated with the Parisian Académie des Sciences. The ties that the Newtonians share with authors whose reach extends beyond their clique (such as Huygens and Boerhaave) are commonly based on the affiliation of an “outsider” author to British institutions, often the Royal Society. In this sense it seems that, at least in the late 17th century, the few Newtonians “kept to themselves” and were in contact with outside thinkers only insofar as the others were coming to them. As for Cartesians, they found themselves in a scholastic environment, where they would have been competing for hegemony—a situation in which eclectic authors might have played a key role as mediators between the two more divided views. The religious backdrop was Protestant Reformation in the Dutch Republic and Catholicism in France, which makes it understandable that the main playground for Descartes and his views was first in the Netherlands. Teaching at all universities was traditionally based on the authority of Aristotelian philosophy, but it would have been more natural for the French than the Dutch to insist on Catholic philosopher-theologists such as Thomas Aquinas and Duns Scotus.
All the while, Descartes insisted on being Catholic, even though his work was condemned by the Catholic church, with his works being placed on the
Already involved in religious reformation, the Dutch would also have been more welcoming and their universities being friendlier environments for scientific reformations. An example of this is the success of the work of Franck Pieterszoon Burgersdijk (1590–1635, scholastic), who is said to have “contributed with the rapid acceptance of Cartesianism in the Dutch Republic” with his comprehensive manuals on philosophy for universities that covered the entire field, but treated it independently from theology and philology. His pupil, Adriaan Heereboord (1613–1661, Eclectic) further developed along those lines and was an avowed sympathizer of Descartes (Van Bunge et al., 2014, pp. 61–72). Burgersdijk and Heereboord are both well connected in the Dutch cluster, but not beyond. The high density of the Dutch-networked environment (as opposed to the more diffused French and British ones) could have greatly accelerated, or at least facilitated, any momentum in knowledge development.
High betweenness points to authors who were in a better position to synthesize ideas from several, otherwise less well-connected, environments. Looking at authors who are both high in betweenness
Du Moulin is conspicuous in the network for being the only French author with high degree centrality. He also has a high betweenness score as he is a bridge between the Dutch and French and British authors (being schooled first in Sedan, then Leiden and Cambridge, and at the end of his life serving as a church minister in Paris). Leslie Gordon Tait mentions in a 1955 thesis that “[i]t is surprising that there is no complete account of the life of Pierre Du Moulin,” and it is remarkable that there has been little more than passing attention given to this “important French Huguenot” (Tait, 1955, p. i). Tait recognized Du Moulin’s central position in the mid-20th century, and since then it seems to have been acknowledged more widely. Armstrong and Larminie (2008) mention how his noble ancestry helped him to develop contacts and friendships with high-placed officials, and they praise his “astonishing literary output” which was not devoid of controversy, making him a well-known person among the British social and clerical élite. These factors would have placed him in an advantageous position, both as an initiator of new ideas and as a conduit for the spread of knowledge. Based on the biographies and his position in the network of natural philosophers, it is clear that Du Moulin was at the center of a spider’s web, tying together important knowledge spheres in his time. Examining his personal profile as a case study, it would seem that his philosophical endeavors were primarily aimed at, and relevant to, the field of theology and the development of French Protestantism rather than natural philosophy. Still, if we think of religious backgrounds as fostering a certain direction in the field, as I highlighted earlier, we may contend that religious and scientific change stimulated each other. Thus, the fact that Du Moulin was spreading Protestant ideas in France could have paved the way for philosophers to be more open to the novel ideas of Cartesian physics as well.
Du Moulin also offers an example of how network centrality must be evaluated closely; while he was highly central in Layers 1 and 2, he died in 1648, when Newton was 6. He was thus not in a position to discuss ideas with Newton, despite their shared Cambridge environment. However, their connection can still be considered relevant because of this social proximity. The fact that they were active in the same environments increases the chance that the later Newton was familiar with the work of Du Moulin.
In fact, we have insight into Newton’s library as it has been catalogued, although not exhaustively (Iliffe and Mandelbrote, s.d.). Pierre Du Moulin’s work does not appear on this list, but there is a work by his son, Peter Du Moulin (
The other three highly central authors were more directly involved in the development of Cartesianism. The French Marin Mersenne, to start with, is a well-known figure and already widely acknowledged for his “bridging” position. His socially rich activities are well documented and preserved in his prolific correspondence with many intellectuals of his time, notably Descartes (for whom he managed all French correspondence and maintained a lifelong friendship [Hotson and Lewis, s.d.]). In the networks of Layers 1 and 2, Mersenne has high centrality scores in all slices, although more so in betweenness than in degree or eigenvector.
This results from his affiliation with eight different institutions, including some collèges and convents, as well as his own Mersenne Circle, also known as the “Academia Parisiensis”
Another French philosopher of interest is J.-B. Du Hamel. He does not have a high degree score, but he is found between knowledge spheres, with high betweenness centrality in the first layer. He is well embedded in the French environment with six different affiliations, including schools in Caen and Paris, and he was a founding member of the Académie des Sciences in Paris. This “highly cultivated priest” functioned as a bridge between the scientific and theological communities: “Du Hamel enlarged the circle of his Parisian acquaintances, acquiring powerful associates and protectors capable of advancing somebody whose intellectual gifts they greatly admired” (Sturdy, 1995, p. 84). While Sturdy mostly emphasizes Du Hamel’s relations with powerful patrons and acquaintances, he played the same role for others as well. From Augustin Vialard’s 1884 thesis on Du Hamel, we learn how the philosopher’s respect for Descartes, which he shared with his two friends Picard and Malebranche, did not prevent him from acknowledging the value of Pierre Gassendi (1592–1655), an eclectic but anti-Cartesian
In his work, Du Hamel notably integrated Cartesian mechanical principles within an Aristotelico-scholastic framework instead of the opposite, which was usual for the time. In his aptly titled book,
Gassendi, on the other hand, was a member of the Mersenne Circle, and through Mersenne connected to Descartes. It is known that they corresponded and Gassendi provided a set of objections to Descartes’
In the Dutch environment, Martinus Schoock (1614–1669, eclectic) and Henricus Regius (or Hendrik de Roy) are the highest in eigenvector centrality and they are deeply embedded in the Dutch cluster, often with strong ties (weighting 2 or 3 due to their co-affiliation with two or three Dutch universities). Both of their roles in the history of philosophy are usually framed as associated with the heated discussions on Cartesianism in Utrecht, notably involving Descartes and the scholastic theologian Gisbertus Voetius (1589–1676). Upon the request of Voetius, Schoock, then professor at the University of Groningen, wrote “a fierce treatise” with the mocking title cf. Descartes in his conversations to Burman (Descartes 1976 [1648], 38).
To recapitulate, we can gather that Descartes was well connected to important figures such as Mersenne in France, but his ideas still encountered more resistance there than in the Netherlands. Because of the religious–political backdrop, the French do not seem to have needed an alternative to the traditional scholastic approach in the way that the Dutch did, but the Cartesian developments were still closely followed and engaged with by influential authors in France, even when they did not subscribe to them—as we have seen with Du Hamel and Gassendi. Philosophers who were deemed “eclectic” were often authors who did not mind combining the new mechanical practices with the old Aristotelian systems of knowledge. In this sense, they would not have been too averse to Descartes, even if they disagreed on key issues.
Such leniency would already have had an impact on their approach to science, placing scholastic philosophy under increasing pressure to make way for The phrase
In the network of the first slice of Layer 3, only five authors have a connection. There is a triad of authors who co-published with Elzevier (Amsterdam) and a dyad that published with Patij (Leiden). In the subsequent slices, the most prominent authors are those who co-published with Elzevier, the well-known and celebrated printing and publishing family business tied to the University of Leiden (Goldsmid & Willems, 1885).
There are no specific publishers in the book trade other than Elzevier that stand out for working with natural philosophers at the beginning of the century (see Slice 1). In Slice 2 of Layer 3, we see a handful of unconnected network components.
The orange and purple cliques both include authors co-publishing with Elzevier, differentiated because they had branches in Amsterdam (orange, component size 14) and Leiden (purple, component size 6). This, of course, tells us something about the publishers as well. No one seemed to be “specialised” in natural philosophy or directing their efforts toward works in this field.
If any authors could be considered central here, it would be Descartes and Robert Boyle (eclectic), who have the highest degree and betweenness values. Descartes also has a high eigenvector score. In Layer 3, Slice 3, Descartes’ position (central in the orange cluster) shows that he co-published with some Dutch and French authors of heterogeneous traditional allegiance. There are no other authors in the corpus who published with Jan Maire of Leiden, the publisher of the first edition of the
The Newtonian authors co-published with several printers that worked exclusively for London’s Royal Society (Rivington, 1984), such as William Godbid and Moses Pitt (tying Boyle to Wallis), Samuel Smith (tying Newton to Boyle), the Crooke family (tying Boyle, White, and Hobbes) or John Martyn (publisher of authors in the blue clique seen in Figure 5, Layer 3). Apart from the Newtonians, these knowledge spheres are dominantly eclectic, with the exception of Antoine le Grand (1629–1699), who played an important role in propagating Cartesianism in Britain in the late 17th century (Easton, 2018).
Throughout the components of Layer 3, there are no homophilous patterns with regard to tradition in terms of assortativity measures. In fact, this layer is the only one with negative assortativity values, in Slices 2 and 3 (-0.2), although it should be noted that these are still close to neutral.
Layer 4 is completely different to the co-publisher layer. It is more similar to the affiliation layers; as with those layers, the slices of Layer 4 show a slight, but near-neutral similarity pattern for traditional allegiance, with scores at 0.02. Furthermore, the layer is highly connected as it is the densest overall and the authors have the highest degrees in the multiplex.
This is already visible in the first slice, where we find a large cluster of authors mostly co-publishing in Paris (Figure 5, blue cluster). The orange cluster groups authors with co-publishing places in Leiden, London, and Genève. Descartes fills a structural hole between the two, publishing in Leiden, Amsterdam, and Paris, and he is found at the top of all centrality lists in Layer 4. Authors by and large were co-publishing in France, particularly in Paris, with those publishing in Lyon being rather separate (light blue cluster). The clusters in Layer 4 are more sharply defined with some very obvious bridge-authors. Apart from Descartes, Thomas White (1593–1676, scholastic) is very central here. He bridges the French (Paris, Lyon) and British (London) spheres, by actively publishing on natural philosophy in the mid-17th century. In contrast to Layers 1 and 2, London is a common shared space for author activity (green cluster). The slices hereby reveal a specific dimension of the authors in the British knowledge environments, in that most of the structurally best connected authors are found publishing in London.
Because a few cities are so central in this last layer, it can be helpful to return to the bipartite network to look at both node sets in more detail. Figure 6 shows a piece of the bipartite network graph of Layer 4, Slice 3, zoomed in on the largest clusters. Paris and London are quite obviously the most popular places for natural philosophers to have published their work. The authors co-publishing in the Netherlands are less tightly connected, showing a more diverse landscape with regard to a shared publication place. Overall, this is surprising because Amsterdam is seen as the center f book production in the 17th century due to its relatively low level of censorship. On the other hand, publishing in France is known to have been heavily concentrated in Paris due to the authority exercised by the monarchy after the religious wars around 1600, with a private press and the 1618 establishment of the
The cities where many publishers were situated are those where the options for printing were omnipresent and, thus, where knowledge was easily copied and distributed. Descartes, and by extension his work, can be found in several such primary locations. These locations would have been stimulating and favorable environments for philosophical activities and, significantly, would also have provided philosophers with access to other works that were being printed there. Many of these hubs were cities with universities, but we do see a difference in cities that were popular from the university perspective as opposed to the publisher perspective. For instance, the Dutch environment was much more pronounced as a binding knowledge sphere in the affiliation layers than the publisher layers. There were several universities spread over the country, and many scholars taught or were educated at more than one of them. For the purposes of publishing their work on natural science, however, scholars were more inclined toward a single city, or maybe two. London is significantly more common as a co-publishing location than as a co-affiliation place, whereas France has a much more distributed pattern for author affiliations. Nevertheless, printing activity was predominantly centered in Paris.
In Figure 7, it is clear that the British clique (shown in the top right, with the Newtonian authors as blue nodes) is not as strikingly devoid of Cartesians as the co-affiliation place layer. There are no Cartesians in the British cluster around the three Newtonians in Layer 2, while here we find two: the aforementioned Antoine Le Grand who, here, is a bridge between the British and Dutch spheres and Gilbert Clerke (1626–1697), a mathematician who “apparently claimed credit for introducing the teaching of mathematics and of the new (Cartesian) philosophy at Cambridge” and was among the first to correspond with Newton about his Cambridge is also the place where we find Henry More (1614–1687), an early supporter and correspondent of Descartes, supposedly the one who coined the term “Cartesianism” (Hutton, 2015). While More worked with the Cartesian mechanical philosophy, he is not included in the corpus as he was an author of theological or literary works, rather than natural philosophy. In Hutton (2019), they are both mentioned, albeit separately, as Cartesians in Britain. Individual biographies, such as the ones in the
It can be concluded that while groups of authors with co-publishing patterns did exist, the publisher as an individual was not a relevant or prominent factor for linking authors in the field. It was expected that either more star-networks, such as that of Boyle, or more clusters would have appeared in these networks, based on traditional studies which emphasize the importance of particular publishers, or the symbolic status of publishers due to their printing of other notable authors’ works (Pettegree & Der Weduwen, 2019, p. 180). However, the sparse and largely unconnected networks do not support the existing literature at all, which focuses on some printing houses—such as the Elzevier publishers who were “dominating the north”—as the most important and definitive for the trade (Unwin et al., 2020). While such publishers certainly stand out, they can hardly be said to dominate the field of natural philosophy. The results are different for
At the individual publisher level, the networks fail to capture any kind of determinant agency for the spread of Cartesianism. The significance of the publishers is likely to be found in their dynamics at other levels, such as their links to each other or their individual links to institutions and cities.
For computational history, Valleriani et al. (2022) show an interesting example with their study on “awareness relationships” among printers and publishers.
The two main questions regarding the instrumentality of prominent authors in spreading and popularizing Cartesian ideas and the diversity of the network in terms of philosophical tradition have been answered using several network measures, complemented by a qualitative analysis of primary and secondary sources. On a general level, the results show that the overall field of natural philosophy as captured in these network layers has a striking similarity in clustering by geographical location, in the sense that authors are often grouped by one or two cities where they were actively working or publishing. While there remain some authors who do not connect on any level, the vast majority belong to a connected network, and we do not see any particular uncoupled subcommunities (based on tradition or other factors). These clusters and cliques within the projected networks were anticipated due to the transition from the original bipartite structures, but they additionally reveal the size and prominence of the actual, specific environments. Specifically, for the affiliation layers, France and the Netherlands have similar co-affiliation patterns among the authors, with Paris and Leiden as the main binding locations.
The Dutch environment is the most densely connected, with authors sharing several affiliations, while French affiliations are altogether more scattered with authors usually connecting in Parisian circles. For Britain, London is much more prominent as a co-publishing place than as a co-affiliation place. Because many (if not most) natural philosophers were active at these locations, either working or publishing, cities like Paris, Leiden, and London provided fertile ground for scholarly communities to thrive. Considered as a whole, the field of natural philosophy in early modern Western Europe was a highly connected and diverse environment.
Although the religious–political situation was not categorically included in the networks, it inevitably played a part in the overall analysis due to the religious transformations of the times. The Netherlands was already undergoing its religious turn toward Protestantism and, thus, it may have been more susceptible to scientific change as well, with less attachment to the Catholic philosopher–theologists who were popular with the scholastics.
The two publisher layers reveal an overarching picture of the publishing activities of this scholarly field. Not mapped explicitly in this way before, the network layers show that publishers by themselves did not create significantly accommodating environments for natural philosophers. On a larger scale, the systematic relationships between publishers and institutions or among themselves remain largely unexamined here. Such a study could prove fruitful for wider fields in the future, but seems to have limited value for the narrowly defined field of natural philosophy.
To answer this article’s first main question, the results corroborate the idea that the most central or prominent figures from a network point of view were key contributors to the spread and popularization of novel approaches. This is supported by the position and activity of authors such as Mersenne, Regius, Du Hamel, and Descartes himself. Their centrality would have made it easier for them, on the one hand, to be well acquainted with the latest research and, on the other hand, to readily spread their own. While they might not always have explicitly favored the Cartesian approach, their work and activities in the scientific community show engagement with a science that moved away from the traditional scholastic approach, in that they were mostly either Cartesian or eclectic in orientation. Du Hamel, one of the few central scholastics, was actually known for merging Cartesian thought with Aristotelian principles. Of course, the centrality scores of Descartes himself also prove that he was in an excellent position to reap the fruits of his own labor.
To answer the second main question, “the old” and “the new” certainly existed alongside each other, as indicated by the assortative mixing. This is true for both the affiliation and publication layers. Overall, assortativity measures indicate that there was
There are, of course, limitations in terms of what the measurements can or cannot show for my data corpus. In regard to centrality measures, I have emphasized
Another related reservation goes a little deeper into the epistemic limitations of network studies without the additional contextualization of the subjects and data. Uncertainty is something that is inherent to a historical data-driven project, but can be accounted for by contextualizing the data. In this regard, I approach the data as “situated knowledge”—a term from feminist theory (Haraway, 1988) that can help us acknowledge that “all data have important contexts of creation and organization, and situating them (or emphasising them as situated) includes critical examination of those contexts” (Lavin, 2021). The database and network design used here incorporate constraints through inclusion and exclusion criteria related to of the authors, their publications, and their relationships. When the criteria is determined differently, either more loosely or strictly, outcomes could be different. As a consequence, this means that treating these networks as all-encompassing, straightforward representations of social environments would be misleading. This stems from the way that the data was gathered using the
Despite the uncertainties, if we understand the production of knowledge as a socially embedded process, it is relations such as the ones formalized in these four network layers that provide pathways of possibility for concepts to evolve. This complex network has brought to light how the ideas of Descartes, whom we know so much about on the individual level, functioned in the broader context of the debate that was going on in the field of natural philosophy at large.