2.1. Bouncing models in loop quantum cosmology

The vanishing of the Big Bang singularity in loop quantum cosmology (LQC) provides a case study of singularity resolution. Loop quantum gravity (LQG) carries out a canonical quantization of relativistic spacetime to get to a quantum spacetime. In order to do this, GR is reformulated as a Hamiltonian system with constraints. While the kinematical structure of the theory is well established, there is no consensus on how to deal with the dynamics. LQC does so by restricting the space of admitted models. More precisely, LQC is a symmetry-reduced version of LQG that covers the cosmological sector of the full theory by studying simplified models.^{Footnote 3,Footnote 4}

In LQC, cosmological singularities are solved thanks to the fundamental discreteness of the quantum geometry.Footnote ⁵ Because of the underlying quantum geometry, the relevant physical observables are normally represented by bounded operators, whose expectation values remain finite even in the regime in which they classically diverge and become singular. The classical equations are modified accordingly. The resulting quantum evolution predicts an effective repulsive force when density and curvature approach the Planck scale. Unlike the classical situation, in which density and curvature go to infinity and result in the Big Bang singularity, this effective repulsive force overcomes the gravitational attraction and makes the universe expand again. The initial singularity is thus replaced by a bounce. In this way, LQC provides a nonsingular description of the early universe.

This generic example of singularity resolution exhibits some interesting characteristics. First, the modified classical equations are such that they allow for an effective spacetime description; that is, the relevant GR solutions are recovered in the appropriate classical limit (Ashtekar et al. Reference Ashtekar, Corichi and Singh2008; Ashtekar and Singh Reference Ashtekar and Singh2011; Singh Reference Singh2014). This shows that GR is a good approximation of the more fundamental theory at low energies and curvature. Secondly, it is possible to rigorously compute—also through the use of computer simulations (Ashtekar et al. Reference Ashtekar, Pawlowski and Singh2006)—the quantum evolution at the bounce. In particular, it has been shown that the bounce occurs when energy density reaches a maximum value ${\rho _{{\rm{max}}}} \approx 0.41{\rho _{Pl}}$ . Finally, the quantum evolution remains well defined throughout the bounce, whereas the classical description breaks down. As a consequence, the quantum geometry acts as a “quantum bridge” joining the pre-bounce and post-bounce structures in the Planck regime. Although these two structures have a spatiotemporal interpretation as classical universes,Footnote ⁶ no spatiotemporal interpretation is available for the region in the deep quantum regime (Huggett and Wüthrich Reference Huggett and Wüthrich2018; Brahma Reference Brahma, Huggett, Matsubara and Wüthrich2020).

2.2. A simple argument against singularities

The naive reasoning on how the debate on the status of singularities changes in light of singularity resolution goes as follows. In GR, although the prevailing view is that singularities are just mathematical pathologies, singularity theorems show that spacetime singularities are unavoidable under physically reasonable conditions. However, this hurdle is overcome in QG: Spacetime singularities disappear. Then, singularity resolution seems to vindicate the prevailing view that spacetime singularities are only mathematical pathologies of GR.

Let me try to structure this reasoning into a rigorous argument:

1. 1. Spacetime singularities are avoided in QG.

2. 2. If spacetime singularities are avoided in QG, then spacetime singularities do not exist fundamentally.

3. 3. Spacetime singularities do not exist fundamentally.

4. 4. If spacetime singularities do not exist fundamentally, then they are mathematical pathologies of GR.

5. 5. Spacetime singularities are mathematical pathologies of GR.

Is the argument sound? The first premise is the main assumption of this work. The third one is obtained by modus ponens from the first and the second. Thus, my main focus is on (2) and (4). The justification for (2) is the following:

1. (i) If a more fundamental theory avoids the singularities present in a less fundamental theory, then those singularities do not exist fundamentally.

2. (ii) The (yet-to-come) definite theory of QG is more fundamental than GR.

2. If spacetime singularities are avoided in QG, then spacetime singularities do not exist fundamentally.

Both (i) and (ii) are commonly accepted claims. Claim (i) is based on the idea that what exists fundamentally is determined by our fundamental physical theories. Claim (ii) is a basic condition for theories of QG.

The fourth premise of the main argument is the most problematic. Why should the conclusion that singularities are just mathematical artifacts follow from the fact that they do not exist fundamentally? To make the argument work, additional strong metaphysical assumptions are necessary. Without them, there seems to be a way out of the argument: Spacetime singularities may be emergent.

4.1. The argument from eliminativism

The hope of recovering the singular structure together with spacetime in QG relies on the assumption that spacetime emerges from an underlying non-spatiotemporal structure. However, according to spacetime eliminativism, the lesson from QG is not only that spacetime does not exist fundamentally but also that it does not exist at all: Spacetime does not emerge (Baron Reference Baron2019, Reference Baron2021a). Under this view, the idea that the singular structure enjoys the same ontological status as spacetime in QG goes against the hope of (re)instating singularities. According to spacetime eliminativism, spacetime does not exist, so neither does its singular structure.

It could look like the claim that spacetime does not exist clashes with the idea that QG must recover relativistic spacetime in the domains in which GR is successful. However, a distinction needs to be made between spacetime as a mathematical entity (ME), that is, a model of GR, and spacetime as a physical entity (PE), that is, the four-dimensional entity we refer to when we say, for example, that spacetime is relational rather than absolute.Footnote ¹² This distinction helps to clarify the content of spacetime eliminativism: This view maintains that spacetime (PE) does not exist, without denying the possibility of a formal, mathematical derivation of GR from QG. Some spacetimes (ME) are expected to be recovered as limit cases of QG, independently of whether or not spacetime (PE) is said to emerge. Henceforth, spacetime emergence always refers to spacetime as a PE. If one believes that spacetime eliminativism is the correct approach to the question of spacetime emergence, then the hope of restoring singularities quickly sinks.

4.2. The argument from composition

The general notion of emergence used in the philosophy of QG involves at least novelty and dependence (Butterfield and Isham Reference Butterfield, Isham, Callender and Huggett2000; Butterfield Reference Butterfield2011a; Crowther Reference Crowther2016), and it is usually compatible with reduction (Butterfield, Reference Butterfield2011a, Reference Butterfield2011b; Crowther, Reference Crowther2016; Huggett and Wüthrich, Reference Huggett and Wüthrich2025). The dependence condition establishes asymmetry between the basis and the emergent phenomenon. The novelty condition ensures that the relation captures some important qualitative differences, for example, a novel behavior or property that is not exhibited by the basis.Footnote ¹³ The case of spacetime arising from theories of QG seems to satisfy both conditions. The spacetime structure emerges from the more fundamental degrees of freedom, on which it depends, by manifesting strikingly novel features in the domains in which GR works (i.e., low-energy regimes). But how can the emergence of spacetime be understood more specifically?

Recent articles (Le Bihan Reference Le Bihan2018; Baron and Bihan Reference Baron and Le Bihan2022a, Reference Baron and Le Bihan2022b) analyze it in terms of composition. Drawing on the proposal in Paul (Reference Paul2002, Reference Paul2012), the mereological approach to spacetime emergence appeals to a notion of logical composition. According to this notion, the relation of composition can apply inter-categories and is topic neutral. On this basis, it is argued that spacetime and spatiotemporal relations are composed of non-spatiotemporal parts. The only requirement for the topic-neutral parthood relation is to satisfy the basic mereological axioms and definitions.

The mereological approach maintains that non-spatiotemporal entities of QG compose spacetime. However, the fundamental degrees of freedom do not always give rise to spacetime. Theories of QG contain models without any emergent spacetime and other models with domains without an emergent spacetime (Wüthrich Reference Wüthrich, Campo and Gozzano2021). “Only when the structure is of the right type, where that means that it is governed by the right laws, will spacetime emerge” (Baron and Bihan Reference Baron and Le Bihan2023, 23). This means that composition does not always occur. “Composition occurs when, and only when, we may map an entity from the spatial structure onto a plurality of entities that are parts of the non-spatial structure” (Le Bihan Reference Le Bihan2018, 13). There is no precise answer to the question of when exactly the non-spatiotemporal building blocks compose spacetime. Further developments in physics are necessary to advance an answer because a satisfying explanation requires an established theory of QG and depends on how the details of its relation with GR are worked out.Footnote ¹⁴ However, it seems possible to identify a minimal condition for spacetime composition: Spacetime is composed only in the domains in which GR applies, that is to say, in which GR is a good approximation of the fundamental theory.

So, why should we expect the property of being singular to emerge? As shown by works on singularity resolution, GR and theories of QG have radically different predictions concerning singular behavior.Footnote ¹⁵ Take, for instance, LQC and the early universe. In section 2.1, we have seen that a quantum bounce replaces the classical singularity in models of LQC. The quantum geometry bridging the two effective spatiotemporal phases at the bounce does not have a spatiotemporal interpretation. So, spacetime composition does not occur at the bounce. In other words, given that composition occurs only in the domains in which GR applies and singularity resolution indicates one of the domains in which GR does not apply, the singular structure does not emerge by composition.

4.3. The argument from functionalism

According to the functionalist accounts of spacetime emergence (Lam and Wüthrich Reference Lam and Wüthrich2018, Reference Lam and Wüthrich2021), the functionally relevant features of relativistic spacetimes are recovered by having their roles fulfilled by entities belonging to the fundamental ontology. The functionalist approach does not claim that the full spacetime must be functionally recovered. Rather, only some spatiotemporal features emerge from underlying non-spatiotemporal states. How this can be achieved is spelled out in a two-step process (Lam and Wüthrich Reference Lam and Wüthrich2018). First, the functional roles of the relevant spatiotemporal properties must be specified. Secondly, the fundamental entities that can fill these functional roles are individuated, and an explanation of how they manage to do so is provided.

A preliminary argument against the emergence of the singular structure can be framed as follows. Being singular is a global property of spacetime, which means that it is a property of the whole spacetime taken together. As such, it applies to the entire spacetime. However, according to the functionalist account, relativistic spacetime does not fully emerge, but some of its features do. So, there is no entire spacetime that can instantiate this global property. Therefore, the status of singularities cannot even be that of an emergent global property.

A red flag immediately rises. Some undesired consequences seem to follow from a generalization of this argument. On the same ground on which the global property of being singular is ruled out, all the other global properties of spacetime should be ruled out as well. Thus, there could be no emergent global spacetime properties. This is problematic because we want to say that some global properties can emerge. However, this objection is not fatal for functionalism. In a functionalist fashion, one could argue that some global properties can emerge without applying to the full spacetime structure but simply by having their functional role fulfilled by the fundamental degrees of freedom. But then, another worry arises: Why cannot the property of being singular functionally emerge?

The answer is that the property of being singular does not have any physically salient spacetime role. Although there is no precise account of physical salience in QG, it should involve at least physical explanations and successful empirical predictions. In light of singularity resolution, neither of these applies to the property of being singular. The latter point about predictions is especially compelling given the disagreement with results from QG.

One could still try to argue that there is a way to assign a functionally relevant spacetime role to singularities, even in light of singularity resolution. The strategy consists of finding a functional role based on some observable phenomena. For example, one could try to characterize it by referring to gravitational and tidal forces, which are arguably physically significant phenomena. However, there is a serious mismatch between what is functionally characterized and its suggested functional characterization: One is a global property, whereas the other is based on local effects. Even more baffling, different observers in different states of motion can experience radically different tidal forces in the same region (Curiel Reference Curiel1999, 126–29). A functional characterization of this kind is inadequate because it cannot capture the global aspect of the property it is supposed to characterize. Therefore, even this strategy turns out not to be very promising for defenders of singularities.

Moreover, even supposing—for the sake of argument—that being singular can somehow be included among the relevant spacetime functions, the possibility of its functional emergence is doubtful. The avoidance of singularities in QG indicates that there is nothing in the fundamental theory that can fulfill the function of being singular; that is, the second step of the functionalist account cannot be completed. Consider the curvature blow-up in the example regarding the Big Bang singularity in LQC. The disappearance of the singularity arises from the properties of the operators, such that no blow-up occurs and the quantum evolution through the bounce is nonsingular. The physics at the Planck regime does not have any elements that can be functionally connected to curvature blow-up, that is, that can play such a role.

But how can this apply to the more general singular behavior exhibited by geodesic incompleteness?Footnote ¹⁶ Referring again to the example of LQC, several results (Ashtekar and Singh Reference Ashtekar and Singh2011; Singh and Vidotto Reference Singh and Vidotto2011; Singh Reference Singh2014) show that the solution of singularities provides us with modified classical equations such that the effective spacetime is geodesically complete.Footnote ¹⁷ So, we can hope that emergent spacetimes always turn out to be geodesically complete. Unfortunately, this is not so straightforward. In GR, generally, there can be spacetimes without blow-up but still with incomplete geodesics.Footnote ¹⁸ As specified earlier, not all singularities are solved by QG. However, if the claim is just that there can be geodesic incompleteness even once we achieve singularity resolution in QG, it does not compromise the conclusion that (at least) the singularities solved by QG do not give rise to an emergent singular structure.Footnote ¹⁹

A different objection is based on the claim that the emergent spacetime may be singular—even if nothing plays the role of a strong-curvature singularity and there are no other sources of singular behavior—simply because the singular structure might still be readable in some limit cases from the equations describing spacetime in low-energy approximations. However, in light of the previous discussion, such a feature would not be functionally emergent but merely mathematically derivable. In other words, the property of being singular may be assigned to some models of GR, but it does not emerge in QG. This suggests that it should be considered a property of spacetime as an ME (i.e., of models of GR) but not of the emergent spacetime.

Under a more permissive understanding of physicality, there is a weak sense in which such a property could be considered physical—namely, that of being a signal for something else, that is, pointing to fertile ground for new physics. Still, this position is compatible with the conclusion that singular spacetimes do not emerge according to the main views on spacetime emergence in QG.