2. Theoretical anomalies for Standard Model effective field theory

In order to discuss the two major theoretical anomalies facing the SMEFT, I begin this section with a brief discussion of the essential features of the EFT framework, including scaling behavior as determined by the renormalization group equations. For reasons of space this will necessarily be a brief summary with a focus on the conceptual details necessary for what follows. For a more detailed treatment aimed at philosophers, see Koberinski and Fraser (Reference Koberinski and Fraser2023), Wallace (Reference Wallace, Knox and Wilson2021), and Williams (Reference Williams, Knox and Wilson2021). For more detailed discussions aimed at physicists, see Burgess (Reference Burgess2004), Donoghue (Reference Donoghue2012), Manohar (Reference Manohar2020), and Peskin and Schroeder (Reference Peskin and Schroeder1995).

The key insight from the development of renormalization group methods that led to the EFT framework for QFTs was that many of the nonrenormalizable interaction terms that one could include in a theory are heavily suppressed as one flows down to lower energies. The requirement that theories contain only renormalizable interactions was initially thought necessary to ensure that a theory was properly predictive; nonrenormalizable terms lead to divergences in predictions of physical quantities when regulators are removed from the theory. On the formal side, the renormalization group analysis provided a means of keeping a regulator in the theory, therefore eliminating the divergences from nonrenormalizable terms.

As Butterfield and Bouatta (Reference Butterfield, Bouatta, Bigaj and Wüthrich2015) have argued, one major accomplishment of the renormalization group was to provide a physical motivation for renormalization, and to further justify the presence of a high-energy regulator in formulating EFTs. To illustrate this point, suppose we start with a fully renormalized QFT without a cutoff regulator. If we write the set of fields as $\left\{ {{\phi _i}} \right\} = \left\{ {{\phi _1},{\phi _2}, \ldots, {\phi _n}} \right\}$ , such a theory can be formulated in terms of a generating functional $Z\left[ {{\phi _i}} \right]$ as follows:

(1) $$Z\left[ {{\phi _i}} \right] = \smallint {\scr D}{\phi _i}{\rm{\;\;}}{e^{iS\left[ {{\phi _i}} \right]}},$$

with $S\left[ {{\phi _i}} \right]$ the classical action for the theory and $\smallint {\scr D}{\phi _i}{\rm{\;}}$ the path integral over all field configurations. One way of implementing the renormalization group transformation is to impose a momentum cutoff in the integrals of the generating functional. Separate out the high-momentum field modes $\phi _i^{\rm{h}}$ from the low momentum modes $\phi _i^{\rm{l}}$ by the cutoff ${\rm{\Lambda }}$ —i.e., $\phi _i^{\rm{h}}:{p^2} + {m^2} {{\rm{\Lambda }}^2}$ and $\phi _i^{\rm{l}}:{p^2} + {m^2} \lt {{\rm{\Lambda }}^2}$ . Then, one can perform the path integral over $\phi _i^{\rm{h}}$ to create a new effective theory whose degrees of freedom include only the $\phi _i^{\rm{l}}$ . There will also generically be an additional dependence on ${\rm{\Lambda }}$ in the new generating functional:

(2) $$Z\left[ {\phi _i^{\rm{l}},{\rm{\Lambda }}} \right] = \smallint {\scr D}\phi _i^{\rm{l}}\smallint {\scr D}\phi _i^{\rm{h}}{\rm{\;\;}}{e^{iS\left[ {\phi _i^{\rm{l}},\phi _i^{\rm{h}}} \right]}}$$

(3) $$ = \smallint {\scr D}\phi _i^{\rm{l}}{\rm{\;\;}}{e^{iS\left[ {\phi _i^{\rm{l}},{\rm{\Lambda }}} \right]}}.$$

The new effective theory will in general contain new interaction terms between the $\phi _i^{\rm{l}}$ , some of which may be nonrenormalizable now. But the cutoff scale ${\rm{\Lambda }}$ ensures that these terms do not diverge, and the cutoff here is given a clear physical interpretation. The new EFT only describes degrees of freedom with energy up to ${\rm{\Lambda }}$ . This process can be repeated, shifting infinitesimally from ${\rm{\Lambda }} \to {\rm{\Lambda }} - \delta {\rm{\Lambda }}$ , and allows one to define a renormalization group flow for a set of EFTs from high to low energy. The construction also suggests a recipe for constructing EFTs from the bottom up, without reference to a successor theory.

Start creating an EFT by writing the appropriate field degrees of freedom, and imposing the relevant symmetries on the theory. Then, since the renormalization group transformation will generically change the values of couplings for some terms while introducing new terms, one writes the most general possible Lagrangian containing these fields and respecting these symmetries. This will include an infinite number of terms, each of which has a classical mass dimension. Since a Lagrangian must have a mass dimension of four (in four spacetime dimensions), and each field carries its own mass dimension, coupling strengths $\left\{ {{g_i}} \right\}$ must also have a mass dimension to ensure that the product of fields with that coupling results in a mass dimension of four. We can then define dimensionless coupling constants ${\alpha _i}$ using the cutoff as the only dimensionful quantity in the theory: ${g_i} = {\alpha _i}/{{\rm{\Lambda }}^n}$ , with $n$ some integer needed to cancel out the mass dimension of ${g_i}$ , and with ${g_i}$ the actual coupling term in the Lagrangian. If we specify the fields and symmetries, then we can parameterize a theory space by the set of couplings $\left\{ {{g_i}} \right\}$ ordered from smallest to largest mass dimension. At a given probe energy, an EFT is specified in principle by listing the value of all of the $\left\{ {{g_i}} \right\}$ , corresponding to a point in theory space.

It turns out that, under renormalization group flow from higher to lower energies, the couplings behave in one of three ways. Relevant couplings become larger as one flows to lower energies, while irrelevant couplings become smaller. The former have scaling corrections including positive powers of ${\rm{\Lambda }}$ , while the latter are suppressed by powers of ${\rm{\Lambda }}$ . Marginal couplings neither grow nor shrink.Footnote ⁴ Running the renormalization group flow in the opposite direction gives the opposite behavior: terms that are relevant under flow to the infrared (IR; low energies) are irrelevant under flow to the ultraviolet (high energies), and vice versa. The scaling behavior of the couplings is given by the beta function,

(4) $$\beta \left( {{g_i}} \right) = {{\partial {g_i}} \over {\partial\ {\rm{ln}}\ \mu }},$$

where $\mu $ is the reference energy scale, usually interpreted as the energy scale at which one is probing the system. Thus, the IR-relevant terms have a negative beta function and IR-irrelevant terms a positive beta function. For an EFT, the only dimensionful parameter available to implement scaling changes is ${\rm{\Lambda }}$ . What makes the EFT framework powerful is that, for QFTs in four-dimensional Minkowski spacetime, terms in the Lagrangian with mass dimension greater than four are all IR irrelevant, while mass dimension four terms are marginal, and less than four are relevant. Since the fields themselves have positive mass dimension, the vast majority of possible terms in the EFT are heavily suppressed at energies $\mu \ll {\rm{\Lambda }}$ , leaving only the marginal and relevant terms. Renormalizable theories are theories with only marginal and IR-relevant terms.

A fully general EFT will flow down to its renormalizable sector as the renormalization group scaling is taken down to energies well below the cutoff scale. For energies $\mu \ll {\rm{\Lambda }}$ , irrelevant couplings quickly approach zero, while only the marginal and relevant couplings remain.Footnote ⁵ This means that many different theories in the theory space—specified by the values of all couplings at a given energy—will flow down to a smaller subsurface in the space, parameterized by only a small set of coupling parameters. Though in principle an EFT requires an infinite set of empirically determined couplings to be fully specified, if one restricts its domain to energies $\mu \ll {\rm{\Lambda }}$ then only a small number of couplings are required for any desired degree of precision. If one additionally assumes that the values of the couplings in an unknown successor theory are natural (i.e., the dimensionless parameters $\left\{ {{\alpha _i}} \right\}$ are not $ \gg $ or $ \ll 1$ ), then the magnitude of nonrenormalizable terms places bounds on the scale ${\rm{\Lambda }}$ , presumed to be the scale at which new physics occurs. Precision testing of an EFT can reveal the small effects of otherwise hidden nonrenormalizable terms, allowing for an indirect discovery of the breakdown scale for that EFT. Thus, the EFT framework provides a mechanism for placing bounds on the applicability of a given EFT, whether we know its successor or not.

In many applications of the EFT framework, we know the successor theory already. In these cases, we can check that the scale at which the EFT breaks down corresponds to the scales at which some new physics is expected to occur, by lights of the successor theory. A classic example of this is the Fermi theory of weak interactions, an EFT describing four fermion interactions at energies low compared to the mass of the weak gauge bosons. The four-fermion coupling is nonrenormalizable, and the coupling strength for the interaction diverges on the order of 100 GeV. This is also the energy scale at which the W and Z bosons become important to describing weak physics; their masses are roughly 80 GeV and 92 GeV, respectively. Here, the scaling behavior of the EFT gives a close estimate to the energy scales at which to expect new physics. Similar results hold in condensed matter physics, where, e.g., phonon interactions as elementary excitations of the crystalline structure of solids can be given an EFT treatment.

When there are relevant parameters in the EFT, one should not even need sensitivity to nonrenormalizable terms to determine where the theory is expected to break down. Since relevant parameters scale with positive powers of ${\rm{\Lambda }}$ , they should provide low-energy evidence for the scale at which new physics comes in. Provided that naturalness holds, relevant parameters should have their low-energy values proportional to some positive power of ${\rm{\Lambda }}$ , ${g_{{\rm{rel}}}} = {\alpha _{{\rm{rel}}}}{{\rm{\Lambda }}^n}$ . In the SMEFT, there are two important relevant terms: the Higgs boson mass and the vacuum energy density. But both of these terms have a far smaller magnitude than would be suggested by even the most conservative estimates for ${\rm{\Lambda }}$ . The failure of naturalness and scaling for the Higgs mass and vacuum energy density are the two major theoretical anomalies for the EFT framework. As I will argue below, these failures highlight important deficiencies in our understanding of intertheoretic relations using EFTs, and suggest that theoretical progress will likely require a conscious rejection of some of the assumptions required for the EFT framework.

3. Beyond EFTs and scale separation

Physicists have long been aware of these potential anomalies in the Standard Model. The cosmological constant problem has been widely known in the particle physics and quantum gravity communities since the early 1980s, and while the hierarchy problem has taken different forms, physicists have been positing beyond Standard Model physics to address it since the 1970s. What is new about these problems is their stubborn resistance to the most commonly expected solutions that retain naturalness and the EFT framework. The failure to find new physics near the Higgs mass scale at the LHC heavily disfavored nearly all of these solutions. Though it is still possible that, e.g., supersymmetry is a symmetry of nature, the lower bound on the symmetry-breaking scale is now too high to help with either of the two problems.

The resistance of these anomalies to “standard” solution strategies within the EFT framework poses a major obstacle to the claim that EFTs provide a quantitative, prospective structure for intertheoretic relationships. As I detailed in the previous section, the problem arises for understanding scaling of empirically meaningful relevant parameters in the Standard Model. There are four possible ways to overcome this hurdle, in increasing order of conceptual departure from the EFT framework:

1. (1) Retain renormalization group scaling and find a restoration of naturalness. This has been the dominant approach for the last few decades, and includes supersymmetry, composite Higgs, technicolor, etc. One could argue that the failure to find a solution is not a problem with the framework, but instead a failure of imagination to construct the right sort of model within the framework.

2. (2) Reject naturalness, maintain EFT framework and renormalization group for intertheoretic relations. This implies that our indirect access to physics beyond the Standard Model is even harder to obtain than initially thought, since couplings may be unnaturally small to suppress new physics effects in the SMEFT. While this is a plausible empirically minded attitude to take, it leads to a severe form of pessimism for the prospects of successful detection of new physics.

3. (3) Maintain EFT framework, reject its characterization of intertheoretic relations. Similar to option 2, but instead of rejecting naturalness, reject the characterization of intertheoretic relations. This means that one treats the SMEFT as a standalone theory, giving no insight into a successor. Requires a reinterpretation of renormalization group methods as underwriting scaling for a single theory, and a reinterpretation of “bare” parameters in a Lagrangian.

4. (4) Reject the EFT framework for intertheoretic relations between the Standard Model and whatever comes next. This response suggests that major conceptual shifts will be needed to resolve the anomalies in SMEFT, and that the EFT framework is inherently limited. Conceptual shifts might come in the form of reformulations of the Standard Model, and they might point the way to further conceptual shifts needed to understand the relationships between the Standard Model and a successor theory like quantum gravity.

These options do not exist solely as responses to scaling issues and intertheoretic relations for the Standard Model; in general they are avenues for constructing candidate theories of physics beyond the Standard Model and may have many independent motivations. Option 1 has been the dominant strategy for constructing models of physics beyond the Standard Model for about 50 years. Before the LHC was operational, it seemed most reasonable to expect that naturalness would continue to be a good guide for constructing EFTs. Models of grand unified theories, supersymmetry, and composite Higgs models were proposed as successors to the SMEFT. But the failure to find empirical evidence to support any of these models at sufficiently low energies to help solve one or both of the problems has made this avenue of response much less attractive. While it is possible that some new model might be thought up that fits the EFT framework with naturalness, the prospects seem dim, since all internal indicators from within the SMEFT suggest that the scale of new physics should be accessible now. Many of the proposed natural extensions of the Standard Model no longer solve these theoretical anomalies, and are postulated due to fits with string theory.

Option 2 is the most common response of theorists and experimentalists since the LHC has been operational. According to this response, we should retain trust in the EFT framework, but give up on naturalness as a criterion for dimensionless couplings. This is a strongly empirical approach; if the framework is still able to account for the phenomena, then there is nothing to worry about. The problem, as discussed above, is that the Standard Model is far more empirically adequate than we have any theoretical reason to expect. So the most conservative option is to reject only the minimal assumptions leading to this theoretical expectation. However, there is still substantial content that we lose by giving up naturalness as a guide to intertheoretic relations. Giudice (Reference Giudice, Kane and Pierce2008; Reference Giudice2017), the head of the theoretical physics division at CERN and a former proponent of naturalness, has since argued that particle physics has entered the post-naturalness era, and that this is something of a Kuhnian crisis period for the discipline. Wallace (Reference Wallace2019) has similarly argued that giving up on naturalness principles generally would lead to problems for thinking about how physical theories relate to each other even outside the scope of particle physics. Indeed, naturalness principles might seem indispensable to the success of reasoning in physics. But nevertheless, at least the narrow form of naturalness employed in EFTs seems to be in jeopardy. By giving up on it, we eliminate the problems as a conflict between theory and experiment. Perhaps the “bare” parameters set by a successor theory, and applicable at energies near the cutoff scale, are simply unnaturally small.

While this response has the advantage of being conservative of the EFT framework, it faces a few problems. First, the formulation of naturalness that one can give up on while retaining the EFT framework is controversial. Naturalness is not something with an uncontested definition. The form that one can reject in this way depends on taking the bare parameters in an EFT Lagrangian—the couplings defined at the cutoff scale ${\rm{\Lambda }}$ —as physically privileged, which is usually justified by assuming the successor theory will have some mechanism to set those parameter values. Then the renormalization group scaling simply reparameterizes those physically privileged values at lower energy scales. By giving up this form of naturalness, the bare parameters lose their meaning as coming from a more fundamental theory via the renormalization group, one might then slide into option 3, which is to reject the EFT characterization of intertheoretic relations altogether. Manohar (Reference Manohar2020) endorses this departure, as do Rosaler and Harlander (Reference Rosaler and Harlander2019). Manohar, in particular, claims that “the only version of the hierarchy problem which does not depend on how experimental observables are calculated … is simply the statement that two masses, [the Higgs and the scale for new physics] are very different” (84). This problem, if it is indeed a problem at all, is not affected by whether or not we retain naturalness as a criterion for relating parameters between EFTs. Williams (Reference Williams2015) also argues that the most justified form of naturalness principle is tightly tied to the assumption of scale separation, essential for the applicability of the EFT framework and its constituent scaling relations. On William’s view of naturalness, one cannot give it up without also rejecting a central pillar in the EFT framework. Without scale separation, one cannot form a principled separation of energy scales within the domain of an EFT and those outside its domain. Without this form of naturalness, one retains a phenomenologically successful SMEFT, but without any of the underlying theoretical support justifying the use of the EFT framework as a whole. Then, the ability to accommodate new discrepancies by including low-order nonrenormalizable terms would appear to be little more than adding new free parameters to a model and tuning to fit new data.

This is where option 3 comes in. If one revises their view of the EFT framework along the lines outlined by Manohar (Reference Manohar2020) and Rosaler and Harlander (Reference Rosaler and Harlander2019), then one can keep naturalness as scale separation, and simply reject the idea that the EFT framework can tell us anything about a Standard Model successor. Franklin (Reference Franklin2020) makes a case against naturalness as explaining the success of EFTs on precisely these grounds. Instead, he takes renormalizability to be the key feature, which is a property of a theory independent of its relation to a successor. Though this view is more principled, it comes with the major cost of undermining the EFT view of intertheoretic relations more generally. For both options 2 and 3, an additional cost of these modifications is the loss of explanatory power regarding the relationship between different EFTs. In particular, prospective realism for the SMEFT based on renormalization group arguments, as in Fraser (Reference Fraser, French and Saatsi2020) and Williams (Reference Williams2019), is undercut. This form of realism depends on the insensitivity of low-energy physics to the values of high-energy parameters. For option 2, rejecting naturalness gives no principled reason why the effects from a high-energy successor are guaranteed to have small impacts on low-energy physics. Option 3 rejects the idea of relating the SMEFT to a successor via the renormalization group altogether, so the stability analysis cannot get off the ground.

Second, the rejection of naturalness (option 2) or intertheoretic links (option 3) leads to more questions than answers. Why does naturalness seem to fail here, when it succeeds nearly everywhere else within the EFT framework? Why does the renormalization group work for relating other EFTs, but fail for the SMEFT? What is it about physics beyond the Standard Model that leads to this unnaturalness? Giving up these principles for the EFT framework as a whole due to their failure for the SMEFT seems too drastic a move, despite its apparent conservatism. Much of the foundational work on the philosophical significance of EFTs makes crucial reference to naturalness or intertheoretic relations; wholesale changes to our understanding of the framework undermine the conclusions of such work elsewhere in particle and condensed matter physics. On the theoretical side, it is too permissive to allow the construction of models of new physics that fit within the EFT framework but reject naturalness. Parameters for new models can simply be tuned to avoid falsification, and there is no guiding principle for when this tuning should be allowed and when it shouldn’t. On the experimental side, a rejection of naturalness causes less concern, but it might lead to pessimism regarding the prospects of finding new physics. Since the way out of the cosmological constant and hierarchy problems is to set bare parameters to unnaturally small values, we are essentially stating that new physics is far more heavily suppressed than we should expect on naturalness grounds. Since we have no reasonable expectation of the degree of suppression, there are likewise no reasonable expectations regarding energy scales at which we should expect to see new physics. Again, option 3 has the resources to respond to this concern: it is not that we have allowed unnatural fine-tuning, but only that we have given undue significance to the high-energy parameters in a given Lagrangian. However, similar issues arise when we take option 3 as a starting point for going beyond the SMEFT. The framework no longer provides connections to anything beyond the Standard Model. Essentially, in the search for new physics, option 3 becomes indistinguishable from option 4.

Option 4 is the most conceptually radical, but strikes me as the most promising way forward for constructing new theories beyond the Standard Model. The lesson from the cosmological constant and hierarchy problems is that the EFT framework fails to get the scales for new physics correct, and that the problem lies in the relevant parameters in the SMEFT. The failure of model-building approaches under option 1 should suggest that this is a persistent problem with our understanding of the relationship between the Standard Model and its successor theory. Since the EFT framework works elsewhere for intertheoretic relationships between EFTs, the failure here suggests that the successor theory does not fit within the EFT framework. One advantage of this approach is that it does not force a revision to our understanding of other successful applications of EFTs and naturalness. This means that one can retain the understanding of EFT-based intertheoretic relations at energy scales below the SMEFT. In this sense, option 4 is conservative of the current interpretation of the EFT framework; the claim is that despite its successes, it breaks down beyond the Standard Model. Another advantage is that it fits with the expectations that quantum gravity will require moving beyond the EFT framework (Bianchi and Rovelli Reference Bianchi and Rovelli2010; Freidel et al. Reference Freidel and Minic2023; Koberinski and Smeenk Reference Koberinski and Smeenk2023). The EFT framework is a framework for local physics that depends on having sufficient spacetime symmetry structure, a well-defined notion of energy, and scale separation. Various proposed quantum gravity models violate one or more of these assumptions, such that the EFT framework will only be able to capture special limiting cases of the theory. However, the argument here is distinct from generic expectations that quantum gravity will fall outside the scope of EFT. For the latter, it is possible that there are several more successor EFTs between the energy scales relevant for the Standard Model and those for quantum gravity. The lesson I am arguing for here is that the anomalies with relevant parameters suggests that whatever theory immediately succeeds the Standard Model will not be an EFT.Footnote ¹²

What about arguments for the essential role of naturalness in physics? Those arguing for its essential role for EFTs, such as Williams (Reference Williams2015), start within the EFT framework as given; insofar as one rejects the applicability of the EFT framework, such arguments no longer apply. However, there are more general arguments for naturalness that do not assume the EFT framework. Wallace (Reference Wallace2019), for instance, argues that some version of a naturalness criterion is ubiquitous and essential to the practice of physics. Wallace’s version of a naturalness criterion is the requirement that inputs to a theory not be extremely fine-tuned. At this level of generality, the criterion seems plausibly applicable to many domains outside of the EFT context. Presumably, if such a criterion is truly essential to physics, a version of it will be found to hold in whatever new formalism for beyond Standard Model physics we arrive at.

The biggest drawback to option 4 is that it is highly unconstrained. Rejection of the EFT framework for understanding new physics leaves open a very wide range of possibilities, with a nearly endless range of possible low-energy empirical signatures. One promising avenue forward is to consider reformulations of current QFTs into a different formalism from EFT. These alternative formulations might provide hints as to the way forward. For example, Hollands and Wald (Reference Hollands and Wald2023) take a position-space representation of QFT as their starting point, and build theories using the operator-product expansion near coincident points as a foundation. This is a more explicitly local formulation of QFT, not relying on Fourier transformations and the accompanying symmetries in the background spacetime. Working in position space, the energy-centric EFT framework does not straightforwardly apply. However, this is only one example; several other avenues could fruitfully be pursued. What will ultimately decide the best way forward is an approach that makes novel, successfuly empirical predictions. Thus, I argue that a two-pronged attack is needed to find the path forward. For constructing models of new physics, choose option 4; the current crisis in particle physics demands fresh new ideas. But in order to search for new physical effects, we need to take the current framework very seriously and hold onto option 2 or 3. The latter will provide a clear, structured framework within which to organize searches for new physical effects.

4. Closing the loop and conceptual shifts

While much of the focus on theory change in physics is centered on the conceptual and theoretical changes between an old and a new theory, the major driving force for these conceptual shifts has historically been anomalous empirical results. The interesting difference for the Standard Model anomalies is that they are in some sense purely theoretical; the Standard Model can successfully accommodate the supposedly anomalous results through the usual avenue of allowing couplings in an EFT to be fixed empirically. This means that theory construction is highly unconstrained, as no new empirical anomalies need to be accounted for.

Smith (Reference Smith2010; Reference Smith, Biener and Schliesser2014) makes a convincing case that discrepancies between theory and observation actually serve a stronger positive epistemic function than straightforward theory falsification. Discrepancies serve to highlight new physical effects that may have been omitted in the previous model of the system, and serve as signals that increased precision of measurement reveals sub-leading physical effects requiring more detailed models. The new physical effects are treated as real when they are found to contribute to otherwise independent observables in the theory, and this is one way the theory guides discovery of new entities, forces, or other physical dependencies. When these fit within the conceptual framework provided by the theory, we get a richer picture of the physics within this domain, and close the epistemic loop between theoretical modelling and precision measurement. Such highly constrained relationships between theoretical entities and observables are often stable under theory change as well, at least when qualified to hold to a certain degree of precision within the bounds where the old theory is a good approximation. When the discrepancies persist and cannot be accounted for within the current theoretical framework, this is a strong signal that new physics is required. But it is only by taking the current framework seriously, and exhausting all possibilities to close the loop, that we have true empirical anomalies and good evidence that a new framework is required. In order to construct a new framework, we must therefore push the current framework to its empirical breaking point.

It is this latter stage that is missing from the crisis facing the Standard Model. Despite the problems in our theoretical understanding of scaling, there are no major persistent empirical anomalies facing the Standard Model.Footnote ¹³ So what is the way forward? So far we have found breaking points only on the side of theory, and only when we try to apply the current framework to extrapolate relations between the Standard Model and some as-yet-unknown future physics. Direct detection of new particles seems unlikely given the current lack of evidence, so we must turn attention to different avenues of testing. In particular, (relatively) low-energy precision tests of the Standard Model offer a promising way forward and a complementary perspective to the rejection of the EFT framework suggested in section 3. This division of labor seems like the optimal path forward for constructing new theories in particle physics.

Luckily, such a strategy is already being pursued. Precision tests of the Standard Model have been going on since the birth of quantum electrodynamics (QED). Koberinski and Smeenk (Reference Koberinski and Smeenk2020) treat the precision testing of the anomalous magnetic moment of the electron in some detail, and argue that, at current levels of precision, “pure QED” alone is insufficient to capture all the relevant physics. Strong and weak virtual effects on the electron’s self-energy make a significant contribution to the anomalous magnetic moment, and without factoring these in, there would be a persistent empirical discrepancy between the predictions of QED and the measured value. Koberinski (Reference Koberinski2023) extends this line of reasoning to current searches for anomalies with the renormalizable sector of the Standard Model. The idea is that the EFT framework can be thought of as a generalization of the old QFT framework, which drops the requirement of renormalizability. This creates a well-defined theory space, parameterized by the values of each possible coupling constant for a given EFT; trajectories through this space describe a theory’s scaling behavior.

Even in cases where the intertheoretic relations seem to break down, the EFT framework can still be useful for organizing and parameterizing deviations from the renormalizable Standard Model. By adopting option 2 or 3 outlined above, we can reject the use of the EFT framework as providing reliable estimates of the domain of applicability of the SMEFT via the relevant parameters. Instead, we can focus on finding evidence for the effects of irrelevant parameters. The EFT expansion and ordering of new terms by mass dimension provides a systematic way to sort the relative importance of possible new terms, each of which impacts several observables in the theory. This structure of new terms does not depend directly on the implied relationship to the Standard Model’s successor, and can be treated as a standalone framework for an individual EFT.

The biggest hurdle to so treating the SMEFT is the enormous number of possible terms contributing at next-to-leading order. There are 2499 possible terms at first nonrenormalizable order for the SMEFT, making a systematic exploration for any small number of new terms prohibitively impractical (Bechtle et al. Reference Bechtle, Chall, King, Krämer, Mättig and Stöltzner2022). This number of free parameters is greatly reduced, however, when one considers the structural relations inherent in an EFT and imposes consistency constraints from experimentally known physics in the Standard Model. This allows one to reduce the number of free parameters, and to promote various experimental sectors as the most promising avenues for finding anomalies (de Blas et al. Reference de Blas, Du, Grojean, Gu, Miralles, Peskin, Tian, Vos and Vryonidou2022). In effect, one targets searches for new physics by focusing on areas where there is some tension between measured and predicted values of observables, but where that tension is within the current margins of experimental error. The SMEFT then provides additional theoretical reason to expect that some of these tensions might hold in new physics, in particular the ones with no global constraints forcing them to take a particular value. These sectors of the SMEFT can then be chosen as the target of future colliders, or of precision measurement design using smaller tabletop devices. Currently, the most promising avenues for precision collider experiments are to target the weak sector (notably precision measurements of W- and Z-boson phenomena), the Higgs, and top and bottom quark physics (de Blas et al. Reference de Blas, Du, Grojean, Gu, Miralles, Peskin, Tian, Vos and Vryonidou2022). In all these cases, there is some hint of tension between the current state-of-the-art predicted and measured parameter values, but the current lack of experimental precision makes these tensions statistically insignificant. Thus, designing more precise tests of these parameter values is a top priority. For low-energy precision tests, the anomalous magnetic moment of the muon has also been the focus of attention recently, though again the tension here has not reached the threshold of a new discovery, and subsequent work has started to dissolve the apparent tension (Koberinski Reference Koberinski2022).

This suggests a division of labor in attitudes towards the SMEFT and the EFT framework more generally. While those pursuing the project of theory construction beyond the Standard Model should reject the EFT framework in constructing new candidate theories, those looking for persistent empirical anomalies should take the framework as seriously as possible. Theorists pursuing this avenue should strive to make as detailed predictions as possible, while experimentalists should use the EFT framework to target sectors of the Standard Model. The role of precision measurement is to reveal which tensions are merely due to a lack of detail, and which are actually persistent anomalies that must be explained by new theories. Take, for example, the quantum revolution. There were persistent theoretical anomalies with classical physics, such as the stability of the atom and the electron’s self-interaction. But these theoretical anomalies were not enough on their own to suggest the way forward; anomalous experimental results flooded in, ushering in the quantum revolution. Despite the recognition of the breakdown of EFT methods for relevant parameters in the SMEFT, we do not yet have the accompanying empirical anomalies. The only way to generate them is to predicate precision tests on the truth of the very framework we know is flawed.