2.1 Leibnizian Passage I

Toward the end of the letter, Leibniz turns to Toland’s claim that mathematicians are not successful as philosophers. After a bit of ad hominem, Leibniz gets down to the business of refuting the claim. His strategy is to draw a line between

1. (1) philosophy, concerned with the ‘nature des choses’, i.e., rerum natura; and

2. (2) mathematics, concerned with applying entities, both ideal and fictional, in geometry and physics.

Toland accused Leibniz of viewing the extension (i.e., the continuum) as made up of mathematical points (the punctiform view).Footnote ⁹ Leibniz first responds to this accusation, and then comments on the relation between the calculus and the nature des choses:

Passage I draws a line between, on the one hand, the mathematician’s task of exploiting the well-founded fictions of the infinitesimal calculus, and on the other, the philosopher’s task of elucidating the natural phenomena (and perhaps the ultimately real monadic entities which underlie the phenomena) in the framework of an unequivocal rejection of infinite wholes.

In Sections 2.2 and 2.3 we will deal with the distinction Mathematics vs. rerum natura. The distinction infinite wholes vs. well-founded fictions will be analyzed in Section 4.

2.2 Leibnizian Passage II

Unlike the choses whose nature Leibniz seeks to explore in the 1716 letter, mathematical entities exploited in the infinitesimal calculus are only useful fictions (mentis fictiones; see Section 5.1):

Leibniz’s comment “however, that is not how I claim to account for the nature of things” is a direct response to Toland’s allegation that Leibniz seeks to account for the nature des choses by means of his calculus (see Section 1). Garber quotes Passage II and notes:

Garber points out a significant difference between the positions of Leibniz and the Cartesians:

Thus in Garber’s view, in Passage II Leibniz (disagreeing with the Cartesians) insists on the separation of rerum natura and its mathematical representation.

2.3 Leibnizian evolution on mathematics and rerum natura

The distinction between the mathematical realm and the rerum natura is a crucial feature of Leibniz’s mature philosophy. Whereas he started with a belief that physics could be reduced to mechanics,Footnote ¹⁰ and hence to mathematics, over the years mathematics ceased to be perceived by Leibniz as the foundation of physics and turned into a mere representation thereof.

For the young Leibniz, extension (corpus mathematicum) is a component of the matter of choses. As Leibniz explains to Thomasius, a physical body is the compound of matter—which Leibniz identifies with extension and impenetrability—and form, which he identifies with shape:

During this phase of Leibniz’s development, physical bodies are seen as continuous, exactly as extension is. Namely, they are potentially infinitely divisible:

By contrast, in his mature system, Leibniz distinguishes between mathematical extension, which is potentially infinitely divisible, and the matter of physical bodies, which is actually infinitely divided:

Similarly in a March 11, 1706 letter to des Bosses, Leibniz writes:

The last passage is analyzed by Antognazza, who emphasizes the distinction in Leibnizian thought between the mathematical realm and the rerum natura:

To avoid confusion between continuous extension, which is an ideal entity, and the actual structure of physical matter, Leibniz employs for the latter the adjective contiguous:

Levey similarly emphasizes the difference between the actual subdivisions of the real world and the potential ones of the ideal mathematical world:

Views similar to that of Antognazza were expressed by Bosinelli [Reference Bosinelli16, p. 168] and Breger [Reference Breger and Li17, p. 124], as acknowledged by Arthur in [Reference Arthur, Nachtomy and Winegar5, p. 156]. But especially, they were expressed by Leibniz himself, who specifically warned his readers against the misunderstandings arising from the conflation of the two realms:

A detailed study of the issue appears in [Reference Ugaglia, Ademollo, Amerini and De Risi77].

Just as the Leibnizian Passage I in Section 2.1, Passage II in Section 2.2 draws a line between the fictional entities (mentis fictiones) of the infinitesimal calculus—well-founded fictions, or useful fictions, as Leibniz also calls them—and the entities of rerum natura. The conflation of the two realms is behind some of the purported evidence in favor of the so-called syncategorematic reading, analyzed in Section 3.

3.1 Small magnitudes vs. Ishiguro’s alternating quantifiers

In 1990, Ishiguro formulated the following hypothesis concerning Leibnizian infinitesimals:

To explain in what sense Leibniz allegedly did not found the calculus on a special kind of small magnitude, she elaborates as follows:

Accordingly, when Leibniz asserted that his inassignable $dx$ , or alternatively $\epsilon $ , was smaller than every assignable quantity Q, he really meant that for each given $Q>0$ there exists an ‘ordinary’ $\epsilon>0$ such that $\epsilon <Q$ .

Ishiguro interprets Leibniz’s uses of the term ‘infinite quantity’ by a similar paraphrase involving embedded quantifiers. Such an approach has been described as a syncategorematic treatment of statements involving ‘infinite’ and its cognates. Ishiguro goes on to compare the theories of Leibniz and Russell and concludes:

Taking her cue from Russell, Ishiguro reads Leibnizian ‘useful fictions’ as logical fictions.Footnote ¹⁸ In the same vein, Levey writes:

By a similar quantifier sleight-of-hand, RA declare Leibniz’s uses of the term ‘infinitesimal’ to be “fully-in-accord/in-keeping with the Archimedean axiom” (see further in Section 3.3).

3.2 Rabouin on syncategorematic entities

In 2013, Rabouin toys with “the idea that the entities being studied are relational or in Leibniz’s parlance ‘syncategorematic’” [Reference Rabouin67, p. 120] and adds: “This is the reason why Leibniz calls them fictitia (they are terms not referring to individual beings, but to some relational properties)” (ad loc., note 40).

On the other hand, in 2015, Rabouin seeks to distance himself from attributing hidden quantifiers to Leibniz, in the following terms:

Yet in note 25 on the same page Rabouin appears to endorse Ishiguro’s reading: “It is, in Leibniz’ terminology, a ‘syncategorematic’ entityFootnote ¹⁹ see Ishiguro (1990) …” (ibid.). Rabouin goes on to claim the following:

What are we to make of Rabouin’s claimed detection of contradiction? While it is true that there is no such thing as a nonzero quantity smaller than any other quantity, Leibniz requires his inassignable infinitesimals to be smaller, not than every quantity, but rather than every assignable quantity; for an illustration in terms of hornangles see Section 4.5. This accords with a glossary entry in (Rabouin’s 2020 coauthor) Arthur’s volume of translations. Here an infinitesimal is defined as

Thus a particular infinitesimal $\epsilon>0$ will satisfy

(3.1) $$ \begin{align} \epsilon<\frac12,\; \epsilon<\frac13,\; \epsilon<\frac14,\; \text{etc.}, \end{align} $$

so long as the denominator is assignable. Due to what appears to be a mathematical misunderstanding, Rabouin is led to a conclusion that a bona fide infinitesimal would be contradictory and hence ‘fictional’.

Once one realizes that the contradiction is not there to begin with, there is no compelling reason to interpret Leibnizian fictionalism as the counterpart of an allegedly contradictory nature of infinitesimals, as Rabouin does in 2015. A geometric illustration of (3.1) in terms of hornangles appears in Section 4.5.

3.3 Letter to Masson and RA’s quantifiers

In Section 3.2, we examined Rabouin’s 2015 attempt to declare Leibnizian infinitesimals contradictory. Five years later in 2020, one finds a related attempt to declare Leibnizian infinitesimals contradictory by Rabouin and Arthur (RA) in [Reference Rabouin and Arthur71] (see also Section 4.2). Infinitesimals do contradict the Archimedean axiom, but if this is what RA mean by their contradictory claim, then their argument (in support of the contention that Leibnizian allegedly syncategorematic infinitesimals are ‘in keeping with the Archimedean axiom’) would be circular: the positing of the Archimedean axiom predetermines the conclusion that non-Archimedean infinitesimals are contradictory.Footnote ²¹

In search of evidence in support of an Ishiguroan interpretation, RA turn to the 1716 letter to Masson where Leibniz employs the quantifier clause

Via the quantifier clause, RA seek to establish a connection between useful fictions and logical fictions, ‘in keeping with the Archimedean axiom’.

However, in his 1716 letter Leibniz is not referring to mathematical entities, whether fictional or ideal, when he employs the quantifier clause above. Rather, he is referring to natural phenomena and the monads which underlie them (see Section 2). Neither natural phenomena nor the monads are useful fictions, unlike infinitesimals. The quantifier clause in the 1716 letter therefore does not refer to mathematical entities such as infinitesimals and infinite quantities. Rather, it merely reasserts Leibniz’s opposition to infinite wholes as contradictory. RA claim the following similarity:

Here RA’s note 26 contains the following text:

We can agree with RA’s comments on Leibniz’s understanding of actual subdivision of bodies. However, RA also claim a similarity in reference to the following Leibnizian texts:

1. (1) his Actu infinitae sunt creaturae (1678–81);

2. (2) letter to Varignon (1702);

3. (3) letter to Masson (1716).

The alleged similarity is apparently based on Leibniz’s calling into question certain notions of infinity in these texts. We analyze their claim in Section 3.4.

3.4 Comparison of letters to Varignon and Masson

In connection with the comparison of the letters, we note the following three points.

1. Notwithstanding the fact that Leibniz briefly mentions the infinitesimal calculus in the 1716 passage, the substance of the sentence is not concerned with infinitesimal calculus, but rather is a reflection on the philosophy of nature that Leibniz deliberately contrasted with the calculus. What is put into question in the 1716 letter is the concept of an infinite taken as a whole (deemed contradictory by Leibniz), in the context of a metaphysical analysis of body and substance.

Meanwhile, the 1702 comment addressed to Varignon deals, not with metaphysics, but with mathematical fictions (the relevant passage from the letter to Varignon appears in Section 5.2 at note 53). Notice that, unlike the 1716 passage, the 1702 passage does not even mention ‘number’, but speaks rather of geometric objects, such as infinitely large lines (i.e., line segments), which are instances of Leibnizian bounded infinity contrasted with unbounded infinite wholes (see Sections 4.3 and 4.4). The 1702 passage reasserts the Leibnizian position that infinitesimal lines need not idealize anything in nature to be useful, and in this sense can be taken to be fictional; see Section 4. Therefore RA’s claimed similarity has no basis.

2. A similar conflation affects RA’s use of the Leibnizian phrase

part of which is quoted in the passage from RA appearing in Section 3.3. The phrase concerns bodies (in rerum natura) and not infinitesimals. The distinction was emphasized by both Antognazza and Levey (see Section 2.2).

3. Referring to possible connections between mathematics and philosophy in Leibniz and the interpretation that puts differential calculus at the core of Leibniz’ philosophy, Rabouin solo writes:

Rabouin goes on to quote Passage II from the 1716 letter (see Section 2.2) as evidence (for a reluctance on the part of Leibniz to make certain connections between mathematics and philosophy). Rabouin’s interpretation of Passage II, insisting on a segregation of mathematics and philosophy, is compatible with our view, but not with the approach pursued by Rabouin and Arthur in [Reference Rabouin and Arthur71, p. 412] that seeks to enlist the 1716 letter as evidence in favor of a syncategorematic reading of the Leibnizian calculus. In Sections 4 and 5, we develop an interpretation of Leibnizian infinitesimals that is more faithful to the Leibnizian texts.

4.1 Part–whole principle

Leibniz held that infinite wholes would contradict the part–whole principle. Already in 1672 Leibniz wrote:

Thus already in 1672, Leibniz held that the infinity of all numbers—that we may today refer to as an infinite cardinalityFootnote ²² —contradicts the part–whole principle.Footnote ²³ To explain Leibniz’ rejection of infinite wholes in modern terms, one could perhaps surmise that Leibniz would have rejected as incoherent the modern notion of infinite cardinality or cardinal number (a point painstakingly argued in [Reference Arthur and De Risi6]).

While Leibniz himself of course does not distinguish between infinite number and infinite cardinality, he does mention a related distinction between infinite magnitude and infinite multitude in a letter to des Bosses [Reference Leibniz53, p. 31]. The correspondence between Leibniz and Bernoulli indicates that Leibniz was clearly aware of the difference between infinite multitude and infinite number.Footnote ²⁴ The distinction is important because Leibniz’s rejection of an infinite multitude, or collection, does not entail a rejection of infinite magnitude, or quantity, or number, provided they are not considered as a whole. What leads to contradiction is not infinity in itself but an infinity taken as a whole. Regrettably, the notions of infinite whole and infinite quantity have been conflated in recent literature. In particular, such a conflation is at the root of the Ishiguro-syncategorematic interpretation of infinitesimals, analyzed in Section 3.

4.2 Infinite wholes and infinite numbers

Both Arthur [Reference Arthur7] and Rabouin and Arthur [Reference Rabouin and Arthur71] seek to connect the Leibnizian rejection of infinite wholes and his description of infinitesimals as fictional, and to document Leibnizian rejection of infinite number. Thereby they seek to assimilate infinitesimals to infinite wholes.Footnote ²⁵ RA claim the following:

While no such conditions are ever identified by RA, in their Conclusion they speak of using infinitesimals ‘under certain specified conditions’ [Reference Rabouin and Arthur71, p. 441], again unspecified.Footnote ²⁶ The key issue, however, is what is meant exactly by “such entities” mentioned by RA. While Leibniz rejected as contradictory an infinite multitude taken as a whole (see Section 2), RA provide no evidence that Leibniz viewed infinitesimal and infinite quantities as contradictory (and not merely as well-founded fictions).Footnote ²⁷

A similar conflation appears in Rabouin solo, who claims that

The contradictory nature of infinite wholes is ‘inherited’ not by infinitesimals but by minima, i.e., points viewed as the simplest constituents of the continuum.Footnote ²⁸

Arthur similarly conflates infinite collections and infinite number when he claims the following:

Arthur’s final ‘therefore’ is a non-sequitur if the expression ‘infinite number’ is meant to include infinite quantity (in addition to infinite wholes).

The related issue of nominal definitions is discussed in Section 5.3.

4.3 Bounded and unbounded infinity

A Leibnizian distinction of long standing—at least since his De Quadratura Arithmetica (DQA), Propositio XI and the Scholium following it—is between bounded infinity and unbounded infinity; see, e.g., [Reference Knobloch33, p. 42], [Reference Knobloch, Gavroglu, Christianidis and Nicolaidis34, pp. 266–267]. In this text of fundamental importance for the foundations of the calculus, Leibniz contrasts bounded infinity and unbounded infinity in the following terms:

It is worth noting that bounded/unbounded infinity is not the same distinction as potential/actual infinity. While actual infinity (understood distributively) is possible in the material realm (see Section 2.3), unbounded infinity (understood collectively, i.e., as a whole) is a contradictory concept to Leibniz. Bounded infinity is a term Leibniz reserves mainly to discuss the well-founded fictions used in his infinitesimal calculus, namely the infinitely large and (its reciprocal) infinitely small. In one of his early articles, Knobloch observes:

An unbounded infinity, which Leibniz viewed as a contradictory concept, can be exemplified by the multitude of natural numbers (which seen as a whole would contradict the part–whole principle; see Section 4.1). A bounded infinity can be exemplified by an inassignable (see below) natural number, say $\mu $ , or the multitude of all natural numbers up to $\mu $ (and thus bounded by $\mu $ ).

Leibniz defines an infinitesimal as a “fraction infiniment petite, ou dont le denominateur soit un nombre infini” [Reference Leibniz49, p. 93], such as $\frac 1\mu $ . Such infinitesimals are routinely used in computing, e.g., the differential ratio $\frac {dy}{dx}$ , as in the passage from Cum Prodiisset [Reference Leibniz48] (circ. 1701), where Leibniz also mentions the assignable/inassignable dichotomy:

A similar passage appears in Historia et Origo calculi differentialis a G. G. Leibnitzio conscripta.Footnote ³² The assignable/inassignable dichotomy was analyzed in the seminal study by Bos [Reference Bos15].Footnote ³³ See [Reference Bair, Błaszczyk, Ely, Katz and Kuhlemann9, sec. 4] for a formalization of the dichotomy in modern mathematics.

4.4 Instances of infinita terminata

In a February 1676 text, Leibniz provided a colorful example of a bounded infinity as follows:

In a text Numeri infiniti dated April 10, 1676, Leibniz envisioned the possibility that such numbers—examples of bounded infinities—may be prime:

The dating of Numeri infiniti is significant since Arthur commits himself to a tight timeframe for an alleged switch in Leibniz’s thinking about infinitesimals.Footnote ³⁵

RA mention the term terminata (bounded) three times in their article [Reference Rabouin and Arthur71] and specifically in the context of Propositio XI and its Scholium in DQA, but do not pay sufficient attention to the dichotomy of bounded versus unbounded infinity and fail to appreciate its significance.

Thus, in an analysis of Propositio XI involving the evaluation of a (finite) area of a region extending to infinity, Leibniz introduces

RA go on to explain this infinity “in the sense that it can be made greater than any given quantity (major qualibet assignabili), yet will be bounded (terminata)” (ibid.; emphasis added). However, there is no source in Leibniz for the clause “it can be made greater than any given quantity.” Rather, Leibniz wrote “it is greater than any given quantity”; RA added the clause “can be made greater, etc.” to help Leibniz conform to the Ishiguro-syncategorematic interpretation (see Section 3). RA’s addition distorts Leibniz’ intended meaning.

Leibniz concludes the discussion of bounded infinities in the Scholium following Propositio XI with the following comment:

Here Leibniz observes that, though bounded infinities may not be found in rerum natura, their usefulness to the geometer is independent of the metaphysician’s task of elucidating their relation to natural phenomena.Footnote ³⁷ To be useful, they needn’t be found in nature:

The reference is to a discussion on the previous page of a circle as a fictional polygon with an infinite number of sides:

4.5 Hornangles and inassignables

Leibnizian hornangles exhibit non-Archimedean behavior (when compared to ordinary angles) not easily paraphrasable in Archimedean terms, and shed light on Leibniz’s attitude toward infinitesimals in general. We provide a geometric illustration of the phenomenon of magnitudes smaller than all assignables (see equation (3.1) in Section 3.2), in terms of the hornangle (also known as angle of contact or angle of contingence), much discussed in thirteenth to seventeenth century literature. Thus, Campanus of Novara (1220–1296) wrote that “any rectilinear angle is greater than an infinite number of angles of contingence” [Reference Murdoch, Kretzmann, Kenny, Pinborg and Stump66, pp. 580–581].

The hornangle is the “angle,” or crevice, between an arc of a circle (or a more general curve) at a point P, and its tangent ray r at P. According to Leibniz, such a hornangle is smaller than every ordinary rectilinear angle formed by the ray r and a secant ray at P.Footnote ³⁹ Meanwhile, the hornangle is certainly not smaller than all other hornangles (including itself).

In a 1686 article, Leibniz considered a more general notion of hornangle, or angle of contact, between a pair of curves with a common tangent at P.Footnote ⁴⁰ Leibniz defined the osculating circle of a curve at P as the circle forming the least angle of contact with the curve:

Choosing the least one among the angles of contact, as Leibniz does here, presupposes that such “angles” are nonzero. A few lines later, Leibniz renames such entities “angle of osculation” to distinguish them from angles of contact in the classical sense (crevice between curve and tangent ray).

Leibniz explicitly compares angles of contact to inassignables in the 1671 text Theoria motus abstracti (TMA). In this early text, Leibniz still composes the continuum of indivisible infinitesimals which he refers to as “points.” Speaking of the space filled by an infinitesimal motion of a body, Leibniz writes:

In his mature period, Leibniz’s view of the continuum changes (see Section 2.3), but the non-Archimedean behavior of hornangles in comparison with ordinary rectilinear/assignable angles remains. There are at least three indications that Leibniz viewed hornangles as being nonzero.

1. Choosing the smallest one of the angles of contact as Leibniz does in 1686 presupposes that they are nonzero.

2. In a 1696 letter, Leibniz makes it clear that angles of contact are nonzero:

Here Leibniz uses the term incomparable in the technical sense (akin to inassignable) used in his formulation of the violation of the Archimedean property in a 1695 letter to L’Hôpital.Footnote ⁴² Of course, they can still be compared to rectilinear angles.Footnote ⁴³

3. A careful analysis of the two passages in [Reference Leibniz42] where Leibniz asserts that they are “nothing” reveal that his intention is to say that they are negligible vis-à-vis incomparably larger quantities: first, angles of contact are negligible vis-à-vis rectilinear angles, and second, angles of osculation are negligible vis-à-vis angles of contact.

We note the unavailability of the option of representing a hornangle by rectilinear angles—either arranged in a sequence or assorted with logical quantifiers. The non-Archimedean behavior of Leibnizian hornangles is not easily paraphrasable in Archimedean terms, suggesting similar behavior of Leibnizian inassignable infinitesimals. A similar situation exists with respect to comparison of infinitesimals and imaginary roots.Footnote ⁴⁴

Infinitesimals, hornangles, and imaginaries are well-founded fictions that facilitate the art of discovery. Leibnizian well-founded fictions are at most accidentally impossible (they are not contradictory; see Section 5.3). Meanwhile, there are entities that Leibniz sometimes refers to as fictions, such as infinite wholes, which are absolutely impossible (contradictory).Footnote ⁴⁵ This crucial distinction is not sufficiently taken into account by advocates of the Ishiguro-syncategorematic interpretation.

5.1 Instantiation in rerum natura ?

On a number of occasions, Leibniz spoke of infinitesimals as not necessarily found in nature. Thus, in the Specimen Dynamicum of 1695, he concluded his analysis of infinite degrees of impetus as follows:

Over a decade later, des Bosses questioned Leibniz concerning the above passage from Specimen Dynamicum. Leibniz responded as follows concerning the fictionality of infinitesimals:

Arthur quotes this passage in [Reference Arthur, Nachtomy and Winegar5, p. 176] and concludes: “This is the syncategorematic infinitesimal described above” (ibid.).Footnote ⁴⁷ Is it indeed? First, in this passage Leibniz refers to both infinitesimals and imaginary roots as compendia (abbreviations), undermining an Ishiguro-syncategorematic reading (see Section 3) since it is unavailable for imaginary roots.Footnote ⁴⁸ Furthermore, des Bosses, in formulating his question on March 2, 1706, specifically raised the possibility of the syncategorematic infinite:

In his answer 9 days later, on March 11, 1706, Leibniz says not a word about the syncategorematic infinite, and rather speaks of fictions of the mind as quoted above.

Levey reproduces a longer passage from the March 11, 1706 letter containing the one we quoted, and claims that it supports the syncategorematic reading [Reference Levey, Shapiro and Hellman64, p. 146]. However, such a claim overlooks the fact that Leibniz specifically ignored des Bosses’ question about the syncategorematic infinite, as noted above. Levey concludes his Section 2.1 on infinitesimals as follows:

As Levey appears to acknowledge in his concluding sentence, it is in nature that there may be no infinitesimals; Leibniz viewed them as mentis fictiones. Levey’s stated conclusion is mainly in accord with our reading of Leibnizian infinitesimals. Meanwhile, the Ishiguro-syncategorematic hypothesis pursued elsewhere in Levey’s Section 2.1 remains unsupported.

5.2 Well-founded fictions in relation to rerum natura

The fictional nature of infinitesimals is a constant theme in Leibnizian thought. Thus, in a April 14, 1702 letter to Varignon, Leibniz wrote:

In this passage, Leibniz asserts that interpreting the infinite and infinitely small as useful fictions would cause no harm to ‘our calculus’.Footnote ⁵⁰ In a June 20, 1702 letter to Varignon, Leibniz wrote:

In this case Leibniz adds a qualification: infinitesimals are well-founded fictions (‘fictions bien fondées’). It is difficult to see how fictions that are, according to Leibniz, well-founded could also be, as per RA, contradictory.Footnote ⁵² On the contrary, for Leibniz consistency is a requirement for a well-founded fiction and thus for mathematical existence. In this respect Leibniz is closer than many mathematicians of subsequent generations to Hilbert’s formalism (where existence depends on consistency alone). By ascribing to Leibniz the use of contradictory concepts, RA rule out an interpretation whereby Leibniz, like Hilbert, views conception of mathematical existence as consistency; see [Reference Katz and Sherry32] for details.

Leibniz expressed similar sentiments concerning ideal notions in a February 2, 1702 letter to Varignon:Footnote ⁵³

The idea of imagining infinitesimals also appears in a March 30, 1699 letter to Wallis, where Leibniz rejects Wallis’ position that infinitesimals are nothings:

In the same letter, Leibniz makes a revealing comment concerning the status of inassignables:

Here Leibniz refuses to commit himself to either a realist or a fictionalist position. Beeley offers the following intriguing speculation:

Our main arguments in the present text are independent of resolving Beeley’s ‘get-out clause’ hypothesis. On many occasions, Leibniz did reject infinitesimal creatures. Thus, in a June 20, 1702 letter to Varignon, Leibniz wrote:

In the same vein, in a March 11, 1706 letter to des Bosses, Leibniz wrote:

5.3 Theory of knowledge: two types of impossibility

The terms “contradictory” and “impossible” have different meanings for Leibniz. In Leibnizian theory of knowledge, the fact that something is (1) not possible does not mean that it is (2) absolutely impossible or contradictory.

Leibniz introduces a related distinction on several occasions. Thus, in the Confessio Philosophi [Reference Leibniz38, p. 128], he refers to (1) as “impossible by accident” and contrasts it with (2) “absolute impossibility,” i.e., contradiction. He gives the examples of a species with an odd number of feet, and an immortal mindless creature, which are, according to him, harmoniae rerum adversa, i.e., “contrary to the harmony of things” (trans. Sleigh in [Reference Leibniz60, p. 57]), but not contradictory.

In his 1683 text Elementa nova matheseos universalis, Leibniz explains that some mathematical operations cannot be performed in actuality, but nonetheless one can exhibit “a construction in our characters” (in nostris characteribus [Reference Leibniz41, p. 520])—meaning that one can carry out a formal calculation, such as those with imaginary roots, regardless of whether the mathematical notions involved idealize anything in nature. Leibniz goes on to discuss in detail the cases of imaginary roots and infinitesimals. For convenience of reference, we labeled four passages [A], [B], [C], and [D]. Leibniz mentions infinitesimals in passage [C]:

Passages [B] and [C] indicate that (natural instantiations of) infinitesimals are only impossible by accident, or only apparently impossible. Therefore there are no grounds for attributing absolute impossibility or contradiction to them, or for lumping them with infinite wholes, as per RA (see Section 3.3). Infinite wholes are absolutely impossible because they are contrary to the part–whole principle (see Section 4.1), which is a necessary truth. Thus, in a 1678 letter to Elisabeth [Reference Leibniz40], Leibniz described the concept of “the number of all possible units”Footnote ⁶⁰ as impossible [Reference Leibniz58, p. 238]. In his Historia et Origo [Reference Gerhardt24], he presents a derivation of the part–whole principle from the principle of identities and the definitions of whole and part:

RA seek to undercut infinitesimals on the grounds that their definition, in terms of violation of Euclid’s Definition V.4,Footnote ⁶¹ is only nominal, and claim the following:

Does the concept of infinitesimal contain a contradiction as claimed by RA? In his 1686 comments that shed light on the Leibnizian theory of knowledge, Leibniz wrote merely that a nominal definition could harbor contradictions, not that it must do so:

With regard to both imaginaries and infinitesimals, Leibniz makes it clear in the 1683 passage cited above (paragraph [C]) that their natural instantiations are (at most) only conditionally or accidentally impossible, rather than contradictory. Esquisabel and Raffo Quintana examine the issue and reach the following conclusion:

If “the principle of non-contradiction [is] the principle of the minimal condition of intelligibility” [Reference Grosholz and Yakira28, p. 44] then one can easily perceive why infinitesimals, unlike infinite wholes, are ubiquitous in Leibniz’s mathematical oeuvre.

5.4 Infinitesimals, infinite wholes, and nominal definitions

To summarize, in a 1672/3 text Confessio Philosophi, Leibniz speaks of the distinction between accidental impossibility and absolute impossibility (equivalent to contradiction), and mentions two examples of accidental impossibility, specifying that they are contrary to the principle of the harmoniae rerum.

Furthermore, in a 1683 text Elementa nova matheseos universalis Leibniz mentions that imaginary roots do not exist in rerum natura, and contrasts imaginary quantities impossible by accident, on the one hand, and absolutely impossible entities involving a contradiction such as $3=4$ , on the other. Leibniz goes on to compare imaginary quantities (impossible by accident) to infinitely small quantities, and points out that people who are not sufficiently expert tend to confuse apparent impossibility with absurdity.

Finally, in a 1686 text Discours de Metaphysique Leibniz speaks of nominal definitions and warns that they might harbor contradictions (but not that they must necessarily do so). Even if the definition of an infinitesimal as violating Euclid’s Definition V.4 were nominal (as RA claim), it would follow at most that infinitesimals, possibly contrary to the principle of the harmoniae rerum, may not idealize anything in nature, a state of affairs that can be described as accidental impossibility. Meanwhile, infinite wholes are contrary to the part–whole principle (which Leibniz consistently takes to be a necessary truth), and therefore do involve an absurdity.