2.1.1. Frequency counts for preemption and entrenchment measures

In order to operationalise the predictions of the entrenchment and preemption hypotheses, verb frequency counts were taken from the British National Corpus (BNC, 2007). Although this corpus is not representative of speech to children, it is much larger (100 million words) than available corpora of child-directed speech. In the studies reviewed in Ambridge et al. (Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018), frequency counts from this and other adult corpora were better predictors of children’s performance than counts obtained from corpora of child-directed speech, due to the fact that the latter are considerably smaller (with many stimulus verbs not appearing at all) and hence potentially noisier. Thus, we consider the BNC an appropriate corpus to use here. A custom script (written by the fifth author) was used to obtain counts of overall uses of the relevant lexical item tagged as VERB, and to extract candidate transitives (NP VERB NP), intransitives (NP VERB), passives (NP BE VERBed/en), and periphrastic causatives (NP MAKE NP VERB). Because this process yields a large number of false positives, for each verb a randomly selected sample, from all uses extracted from the corpus for that construction, of 100 transitive, 100 intransitive, 100 passive, and 100 periphrastic causative uses (or if < 100, all uses) was hand-coded (by the first author). This allowed us to estimate the proportion of false positives in the sample as a whole. The full sample was then pro-rated accordingly to yield the final estimate.

Following Stefanowitsch (Reference Stefanowitsch2008; see also Stefanowitsch & Gries, Reference Stefanowitsch and Gries2003, and Gries & Stefanowitsch, Reference Gries and Stefanowitsch2004) and Ambridge et al. (Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018), we then used these corpus counts to create (log transformed) chi-square predictors (note that we use the chi-square values themselves, not the associated p values) that operationalise preemption and entrenchment in terms of each verb’s relative bias towards each target construction and away from (preemption) the closest competing construction and (entrenchment) all constructions (though excluding uses already counted towards preemption). In each case, the sign of the predictor is set to positive if, relative to the other verbs in our verb set, the verb is biased towards the target construction, and to negative if it is biased away from the target construction.

The entrenchment hypothesis (e.g., Braine & Brooks, Reference Braine, Brooks, Tomasello and Merriman1995) posits an inference-from-absence mechanism to explain children’s retreat from overgeneralisation errors: the more a verb is heard in the input, without being heard in the ungrammatical construction, the stronger the inference that that verb–construction pairing must not be possible. Thus, the entrenchment hypothesis predicts that the more a verb has been heard regardless of the construction, the less acceptable it will be in ungrammatical sentences, and the less likely children will be to produce an error with that verb. In most of the previous studies reviewed above, entrenchment has therefore been operationalised simply as overall verb frequency, and calculated only for so-called ‘non-alternating’ verbs (here, intransitive-only or transitive-only verbs). However, as Ambridge et al. (Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018) note, this operationalisation is problematic, because the stipulation ‘without being heard in the ungrammatical construction’ draws an arbitrary line in the sand, ignoring the reality that grammatical acceptability is graded: few verbs are entirely unattested in a particular ‘ungrammatical’ construction, and many verbs that are described as ‘alternating’ between two constructions often show a bias for one over the other that is very similar to that shown by ‘non-alternating’ verbs. Here, we therefore follow Stefanowitsch (Reference Stefanowitsch2008) and Ambridge et al. (Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018) in operationalising entrenchment using the chi-square statistic as a measure of relative bias, as explained in more detail below.

The preemption hypothesis (e.g., Goldberg, Reference Goldberg1995), while related to the entrenchment hypothesis, adds a semantic element: the more a verb is heard in constructions with a roughly equivalent meaning to the ungrammatical construction, the stronger the inference that the ungrammatical verb–construction pairing must not be possible. Thus, the preemption hypothesis predicts that the more a verb is heard in a competing construction with similar meaning, the less acceptable it will be in the relevant target construction, and the less likely children will be to produce this type of error with that verb. To test this account, for intransitive utterances (e.g., *The ball kicked), we followed Brooks and Tomasello (Reference Brooks and Tomasello1999) and designated the passive (e.g., The ball was kicked [by X], including both full and truncated passives) as the competing construction: like the intransitive construction, the passive construction puts the discourse focus on the patient by placing it first in the sentence (e.g., The plate broke; The plate was broken [by Homer]). The truncated passive also allows the sentence to exclude the agent altogether, as in the intransitive. In our corpus data, the majority of passive sentences were truncated (92.15%). Thus, the passive uses of these verbs were very similar to intransitive uses. For transitive utterances (e.g., *The man laughed the girl), again following Brooks and Tomasello (Reference Brooks and Tomasello1999), we designated the periphrastic causative (e.g., The man made the girl laugh) as the competing construction, since this construction expresses a similar meaning to the transitive, and overtly expresses both agent and patient.

As with entrenchment, the majority of previous studies reviewed above operationalised preemption using a raw-frequency measure (i.e., frequency in the grammatical construction of the pair) and ignored so-called alternating verbs. But, again, this draws an arbitrary line in the sand between dispreferred uses that are ‘ungrammatical’, though sometimes attested, and those that are ‘grammatical’, though attested relatively rarely. We therefore follow Stefanowitsch (Reference Stefanowitsch2008) and Ambridge et al. (Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018) in operationalising both preemption and entrenchment using the chi-square statistic as a measure of relative bias.

For preemption, the chi-square statistic reflects the extent to which the bias of a particular verb (e.g., laugh) with respect to two competing constructions (e.g., the transitive vs. the periphrastic causative: e.g.,*The man laughed the girl vs. The man made the girl laugh) is similar to the bias shown by other verbs (here, the other verbs in our stimulus setFootnote ¹) with respect to these two constructions. Unlike a version based on raw-frequency, this operationalisation of preemption allows us to calculate this measure for all verbs – ‘alternating’ and ‘non-alternating’ alike – while taking into account the frequency of a particular verb in both the preferred and dispreferred construction of the pair. Unlike a raw frequency measure, it also factors in the base-rate of the two constructions. For example, given that the transitive is, for verbs in general, approximately 800 times more frequent than the periphrastic causative (at least in the present corpus counts), a verb like boil that is ‘only’ 52 times more frequent in the transitive than periphrastic causative in fact shows a relatively strong bias towards the periphrastic causative. Conversely, a verb like destroy, that occurs over 4,000 times in the transitive causative but never the periphrastic causative, shows a strong bias for the former.

For each verb, two preemption predictors were calculated, reflecting each verb’s bias (relative to all other verbs in our verb set) for (a) the transitive versus periphrastic causative construction (e.g., *The man laughed the girl vs. The man made the girl laugh; Someone destroyed the city vs. *Someone made the city destroy), and (b) the intransitive versus passive construction (e.g., *The city destroyed vs. The city was destroyed; The girl laughed vs. *The girl was laughed). Tables 1 and 2 illustrate the calculation of transitive-vs.-periphrastic preemption predictor for laugh, and the intransitive-vs.-passive preemption predictor for destroy. The Pearson chi-squared statistic (without Yates’ correction) was calculated according to the standard formula below.

$$ \frac{{\left(A\ast D-B\ast C\right)}^2\ast \left(A+B+C+D\right)}{\left(A+C\right)\ast \left(B+D\right)\ast \left(A+B\right)\ast \left(C+D\right)} $$

Because

table 1. Calculation of the transitive-vs.-periphrastic preemption measure for the verb laugh

(31*483-101*477905)² * (31+101+477905+483)= 61713.26

(31+477905)*(101+483)*(31+101)*(477905+483)

Natural log (1+61713.26) = 11.03

Preemption predictor value = –11.03 (bias away from transitive and towards periphrastic)

table 2. Calculation of the intransitive-vs.-passive preemption measure for the verb destroy

(9*6176-239*667300)² * (9+239+667300+6176) = 24012.45

(9+667300)*(239+6176)*(9+239)*(667300+6176)

Natural log (1+24012.45) = 10.09

Preemption predictor value = –10.09 (bias away from intransitive and towards passive)

the chi-square test is non-directional, it was necessary (as in Stefanowitsch, Reference Stefanowitsch2008; Ambridge et al., Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018) to set the sign of each predictor to positive (/negative) if, relative to other verbs in the set, the verb in question was biased towards (/ away from) (a) the transitive (vs. periphrastic) construction and (b) the intransitive (vs. passive) construction. As is standard practice for frequency-based measures, the chi-square statistic was natural log (N+1) transformed before its sign was assigned.

The entrenchment predictor was calculated in a similar way, though, for each verb, two different calculations were necessary: (a) entrenchment towards (+) / away from (–) the transitive construction (for use as the entrenchment predictor for trials in which this construction was rated or elicited), and (b) entrenchment towards (+) / away from (–) the intransitive construction (for trials in which this construction was rated or elicited). The major difference is that non-target uses (i.e., the two rightmost cells of the chi-square) were defined not as uses in a specific competing construction (as was the case for the preemption predictor), but rather as all other uses, except those already counted towards the preemption predictor. For example, when calculating (a) entrenchment towards (+) / away from (–) the transitive construction for laugh (see Table 3), we excluded the 101 periphrastic causative uses already counted towards the preemption predictor. Table 4 illustrates (b) entrenchment towards (+) / away from (–) the intransitive construction for laugh.

table 3. Calculation of the transitive-sentence-target entrenchment measure for the verb laugh (+ = bias towards transitive, – = bias away from transitive)

(31*1121630-8115*466905)² * (31+8115+466905+1121630) = 3296.20

(31+466905)*(8115+1121630)*(31+8115)*(466905+1121630)

Natural log (1+3296.20) = 8.10

Entrenchment predictor value = –8.10 (bias away from transitive and towards non-transitive)

table 4. Calculation of the intransitive-sentence-target entrenchment measure for the verb laugh (+ = bias towards intransitive, – = bias away from intransitive)

(7173*922468-1074*660135) ² * (7173+1074+660135+922468) = 6903.39

(7173+660135)*(1074+922468)*(7173+1074)*(660135+922468)

Natural log (1+6903.39) = 8.84

Entrenchment predictor value = 8.84 (bias towards intransitive and away from non-intransitive)

This decision was taken in order to ensure parity with the studies analysed in Ambridge et al. (Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018), which is important for meta-analysis, and (as in this previous study) to minimise the correlation between the preemption and entrenchment measures (though in practice they remain highly correlated, presumably because verbs that are (in/)frequent in a given construction tend to be (in/)frequent across the board). However, as a result, this predictor represents a departure from a pure entrenchment predictor (which would require calculating the predictor on the basis of all uses). Rather, it tests a specific prediction of the entrenchment hypothesis: that attested occurrences of a particular verb will contribute to the perceived ungrammaticality of attested uses, even when the two are not in competition for the same message (i.e., even when potentially preempting uses are excluded from the calculation). That said, for the present study, the departure from a pure entrenchment predictor is negligible, since the excluded constructions (periphrastic causative and passive) are extremely infrequent relative to other uses (e.g., transitive, intransitive, single-word fragment).

2.1.2. Semantic ratings

Under the semantics hypothesis, verb semantics determine the permissible constructions for a particular verb, including the transitive and intransitive. The greater the overlap between the semantics of a particular verb and the semantics of the construction itself, the greater the acceptability of the resulting utterance (e.g., Pinker, Reference Pinker1989; Ambridge et al., Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018). Children’s errors therefore reflect, at least in part, a failure to master the semantics of the verb and/or the construction, and disappear as this knowledge is refined. The approach taken by older semantics-based accounts (e.g., Pinker, Reference Pinker1989; Levin, Reference Levin1993) was to identify discrete semantic classes of verbs that are semantically consistent with particular constructions. In line with more recent work (e.g., the studies summarised in Ambridge et al., Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018), we treated construction-consistent verb semantics as a continuum and created an objective measure of verb semantics by conducting a semantic rating task.

This raises the question of how to characterise the semantics of the English intransitive and transitive constructions. A difficulty here is that both of these constructions are highly semantically heterogeneous. However, a general consensus (e.g., Hopper & Thompson, Reference Hopper and Thompson1980; Næss, Reference Næss2007) is that the intransitive construction is prototypically associated with a single participant undergoing an internally caused action (e.g., The girl laughed), while the transitive construction is prototypically associated with an event in which an agent deliberately causes an affected patient to undergo some kind of change (e.g., The girl killed the fly). We operationalised this notion of intransitive- versus transitive-consistent verb semantics by asking participants to rate verbs along Shibatani and Pardeshi’s (Reference Shibatani and Pardeshi2002) causative continuum. Applying this account to English, the main difference between semantically intransitive and semantically transitive verbs is the manner in which the relevant action can be caused:

We therefore obtained ratings for verbs on this event-merge measure. It is important to bear in mind that this measure does not capture the full range of intransitive- versus transitive-consistent semantics in English, given the existence of, for example, transitive utterances that suggest but do not entail causation (e.g., The man kicked the ball), and those that do not denote causation at all (e.g., Food costs money). At the same time, given the general agreement regarding the prototypical semantics of these constructions, we anticipated that this event-merge measure would serve as a reasonable approximation of intransitive- and transitive-consistent verb semantics (and, indeed, the present findings bear this out).

3.1.1. Participants

The participants were 96 children aged 5–6 years old (5;3–6;5, M=5;10), 96 children aged 9–10 years old (9;4–10;6, M=9;11), and 24 adults aged 18–25 years old. Four times as many children as adults were required (in each age group) as each child completed only ¼ of the total number of adult trials. The children were recruited from primary schools in the North West of England. The adults were all undergraduate students at the University of Liverpool, and received course credit for their participation. All participants were monolingual speakers of English, and had no known language impairments.

3.1.2. Test items

For each of the 120 verbs, transitive and intransitive sentences were created as follows:

The arguments of the intransitive and transitive sentence for each verb were always matched in this way. The transitive and intransitive sentences for each verb were recorded by the final author, a native speaker of British English. Identical animations (the same as those used for the semantic rating task) were used for the transitive and intransitive versions of each sentence. The use of animations aimed to ensure that the veracity of the sentences would not be in doubt, and therefore that participants’ judgments would be more likely to be based on the grammaticality of the sentences only, something that we have previously found to be important when testing young children (e.g., Ambridge et al., Reference Ambridge, Pine, Rowland and Young2008).

3.1.3. Procedure

Test sentences and their accompanying animations were presented to participants using VLC Media Player. Grammaticality judgments were given on a 5-point smiley-face judgment scale (see, e.g., Ambridge et al., Reference Ambridge, Pine, Rowland and Young2008), shown in Figure 1.

Fig. 1 The smiley face scale used by adult and child participants to rate sentences for grammatical acceptability. Reprinted from Cognition, 106(1), Ambridge, B., Pine, J. M., Rowland, C. F. & Young, C. R. (Reference Ambridge, Pine, Rowland and Young2008) The effect of verb semantic class and verb frequency (entrenchment) on children’s and adults’ graded judgements of argument-structure overgeneralisation errors, 87–129, Copyright (2008), with permission from Elsevier.

Adults watched the full set of animations, in a pseudo-random order such that no two sentences containing the same verb were presented consecutively, in small groups of up to 10 participants. Adults marked their responses (individually) on an answer sheet containing one smiley-face scale for each sentence. Due to constraints on attention span, children were tested individually on one quarter of the sentences each (60 in total), split over two days. Each child was tested on transitive and intransitive versions of sentences containing 10 each of transitive-only, intransitive-only, and alternating verbs. Sentences were again presented in a pseudo-random order. Children gave their responses by placing a green or red counter (indicating broadly grammatical or broadly ungrammatical, respectively) onto a single, larger smiley-face scale. They were instructed to choose the green counter if the sentence ‘sounded good’ and the red one if it ‘sounded silly’. They then placed the counter on the scale to indicate how ‘good’ or ‘silly’ it sounded. The experimenter noted down responses by hand.

3.1.4. Statistical analysis

Following Ambridge et al. (Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018), we conducted three sets of analyses with dependent variables of (a) ratings for transitive sentences, (b) ratings for intransitive sentences, and (c) by-participant difference scores reflecting preference for intransitive over transitive uses (i.e., b minus a). Results were analysed in RStudio (version 1.3.959; R version 4.0.2; R Core Team, 2020). Mixed effects regression models were conducted using the lme4 package (version 1.1-23; Bates, Maechler, Bolker, & Walker, Reference Bates, Maechler, Bolker and Walker2015). The predictor variables were the continuous preemption, entrenchment, and verb-semantic measures, scaled into SD units and centred at zero, to allow for comparison with the previous datasets reanalysed in Ambridge et al. (Reference Ambridge, Barak, Wonnacott, Bannard and Sala2018). In terms of model structure, we follow Barr, Levy, Scheepers, and Tily (Reference Barr, Levy, Scheepers and Tily2013) in employing random intercepts for participant and item, and by-participant random slopes for the predictor variables, following a stepwise removal procedure in the event of convergence failure. We first report separate analyses by age group, and subsequently investigate developmental trends with a final set of models that include age group and its interactions with each of the predictor variables.

Technically, linear models require the dependent variable to be interval or ratio scaled, rather than ordinal scaled as in the present case. Nevertheless, the use of linear models with Likert-scale data is common because the intention – although we have no way of knowing whether this in fact the case – is that participants will indeed treat the rating scale as, in effect, interval scaled. In order to check that the present rating-scale data did not depart too far from this assumption, we used the R package ggResidpanel (version 0.3; Goode & Rey, Reference Goode and Rey2019) to create normal QQ plots, histograms, and scale-location plots to verify that the residuals for each model were indeed approximately normally distributed and did not show excessive homoscedasticity. These plots are not shown here, but can be recreated using the code available at <https://osf.io/xw934/>.

A high degree of collinearity between the preemption and entrenchment predictors was observed: r=0.71, r=0.74, and r=0.86 for the datasets containing ratings of transitive sentences, intransitive sentences, and difference scores, respectively. As in Ambridge et al. (Reference Ambridge, Pine, Rowland and Young2008), we address this collinearity in two ways. First, in addition to simultaneous mixed effects regression models, we also report single-predictor models. Second, we do not report final models (since the coefficients of individual predictors in simultaneous models are misleading under collinearity), but only the outcome of likelihood ratio tests comparing a full model to a model with the predictor of interest removed (Barr et al., Reference Barr, Levy, Scheepers and Tily2013), implemented using the drop1 command of the lme4 package. Since this test is non-directional, the direction of each effect is inferred from the single-predictor model (a changed direction between single-predictor and simultaneous models is not interpretable in the event of collinearity).

Together, these precautions ensure that the present analysis constitutes the best test of preemption and entrenchment that can be conducted with natural language data (in which the two measures are inevitably highly correlated). Nevertheless, given the very high correlation between the two, and the likelihood of residual confounding (see Westfall & Yarkoni, Reference Westfall and Yarkoni2016), any apparent effect of preemption beyond entrenchment, or vice versa, should be interpreted with extreme caution. Ultimately, to address the theoretical question of whether entrenchment, preemption, or both are used in children’s retreat from overgeneralisation errors will probably require artificial-language-learning studies in which the two mechanisms are systematically de-confounded (a project that we are currently undertaking; see also Boyd & Goldberg, Reference Boyd and Goldberg2011; Perek & Goldberg, Reference Perek and Goldberg2017).

All data and code are available at the following publicly accessible repository: <https://osf.io/xw934/>.