Participants

We recruited 89 participants from two L1 backgrounds: English and Thai.Footnote ² The L1 Thai-L2 English users were recruited to guard against any transfer effect, as it is generally argued that there is no equivalent construction for the two variants in Thai (Chainarongdejagul, Reference Chainarongdejagul2018). Both groups were graduate students pursuing a master’s or doctoral degree in the United States at the time of data collection. Five participants were subsequently excluded for the following reasons: currently not pursuing a degree (n = 1), not following the instructions (n = 2), and not pursuing a graduate degree in the United States (n = 2). Thus, 84 participants remained. The L2 group consisted of 40 L1 Thai-L2 English speakers (21 PhDs and 19 master’s degrees; 23 female, 16 male, and 1 nonspecified). The L2 participants’ average TOEFL iBT score was 102 out of 120 (SD = 10.3, range: 78–117). The L2 group started learning English at approximately 6.1 years of age (SD = 3.37). Despite having an early start, all but two participants reported not having studied or lived in an English immersion environment before the age of 10. Their stay in an English-speaking country ranged from 8 months to 8 years (M = 3.21 years, SD = 2.02). The other two participants indicated having been exposed to English in a more immersive environment (i.e., living in a family or studying in a school where English was spoken) at an age earlier than 10.Footnote ³ In addition to the L1 Thai-L2 English group, 44 native English-speaking participants were recruited (23 PhDs and 21 master’s degrees; 25 female and 19 male).

Experiment

Stimuli

To construct target items, each of the two introductory-it variants was paired with two linking verbs, is and seem (e.g., it is [blank] that … and it seems [blank] that …). These two verbs were chosen to represent verbs appearing in the construction (Francis et al., Reference Francis, Hunston and Manning1998). Doing so yielded a total of four target items. Filler items were constructed from two types: “It is a/an [blank] noun” and “It seems like a/an [blank] noun” such that they resembled the target items. Fillers, however, required attributive rather than predicative adjectives. Our decision to elicit adjectives even with fillers was informed by responses collected during our piloting with a different sample of 23 participants. It was found that with fillers eliciting verbs (e.g., It [blank] across), nonadjective answers in the target items accounted for approximately 45% of the total responses; we obtained far fewer nonadjective responses in the target items with the current set of fillers, as will be shown below. To construct fillers, we selected nouns from the Academic Word List (Coxhead, Reference Coxhead2000) and, for each one, performed searches on an academic section of COCA. We ensured that the first 50 frequency-sorted attributive adjectives of each noun were not among the top 25 adjectives strongly cued by either variant. This was done to guard against any spillover effect from filler to target items. There were nine fillers in total.

Writing experience

Participants completed an 18-item academic writing experience questionnaire (AWE-Q), developed by the first author of the present study and validated with item response theory models in a previous unpublished study (Suethanapornkul & McKay, Reference Suethanapornkul and McKay2018). Designed to gauge writers’ experience with academic writing, the questionnaire asked participants to rate, on a scale from 1 (very rarely) to 5 (very often), how frequently they performed each of the 18 writing tasks commonly found in academic settings (e.g., submitting an abstract for a conference presentation, submitting a grant proposal, and writing a part of the thesis or dissertation). Participants checked “Does not apply” if certain tasks were not applicable. The experimental stimuli and questionnaire can be found in the Online Supplementary Materials.

For each participant, we dropped items with no responses and calculated average scores, which served as an indirect measure of constructional use in both L1 English and L1 Thai-L2 English participants. The L1 English group engaged in academic writing somewhat frequently (M = 3.43, SD = 0.88, range: 1.78–5); academic-related emails (M = 4.57, SD = 0.76) and course papers (M = 4.40, SD = 0.96) were the two most common tasks the group performed. The average scores of the L2 English group were similar (M = 3.60, SD = 0.96, range: 1.56–5), with academic-related emails (M = 4.75, SD = 0.67) and academic presentations (M = 4.24, SD = 0.89) being the two most common tasks.

Procedure

The full experiment was delivered via Qualtrics. Participants were informed that they would complete an academic English vocabulary test by typing in as many academic English words that were appropriate for a given item in 1 min. After signing an electronic consent form, participants took three practice trials (e.g., as a/an [blank] of …). For each one, after participants completed their answers, the experiment presented three commonly used words in academic writing (e.g., the three words for the frame as a/an [blank] of … were example, percentage, and result).

For the main part of the experiment, each participant saw two target items, one from each variant, interspersed with three fillers, selected randomly from the nine items. The order of the presentation of these two target items was counterbalanced across participants. For methodological comparability, we followed the procedure in Ellis et al. (Reference Ellis, O’Donnell and Römer2014) and Römer et al. (Reference Römer, Skalicky and Ellis2020). Participants completed each of the five trials by typing their answers in the boxes provided, and their responses remained on the screen until the end of each trial (= 1 min). Once the elicitation task was completed, the participants took the AWE-Q and completed a language background questionnaire, also on Qualtrics.

Adjective–variant association strength

To establish adjective–variant association strength in the input of academic English to which language users were potentially exposed, we computed a directional cue-outcome contingency measure, ΔP (Gries & Ellis, Reference Gries and Ellis2015). The measure expresses the likelihood of an outcome occurring when a cue is present as opposed to when it is absent. There are two versions of ΔP; the two differ with respect to what linguistic element is the cue and what the outcome is (Gries, Reference Gries2013). In the context of the present study, the cue can be an adjective and the outcome a variant or vice versa. Because in the experiment participants were given the two introductory-it variants and prompted to complete an empty slot with adjectives, we calculated a version of ΔP where the presence or absence of a variant was the cue and the choice of adjective was the outcome and represented such contingency as ΔP _{(variant → adjective)}. For each adjective–variant pair, a ΔP score thus indicates how strongly the variant cues the adjective.

To obtain the ΔP _{(variant → adjective)} scores, we first retrieved from an academic section of COCA through the CQPweb interface (Hardie, Reference Hardie2012) instances of the two introductory-it variants. Our search terms combined part-of-speech tags for verbs with a length requirement, from one to three words, to retrieve different verb tenses and modal verbs (e.g., is, seemed, might be, and could have been). The terms also allowed for intervening adverbial and prepositional phrases before or after an adjective (e.g., it is important for researchers to understand the process). Last, the queries included the to-infinitive and that-clause; thus, only instances where that was explicitly mentioned were retrieved (see Hyland & Jiang, Reference Hyland and Jiang2018, for a similar approach). We retrieved 44,120 hits in total (16,339 Adj-that and 27,781 Adj-to). The search terms, along with example sentences retrieved, are included in the Online Supplementary Materials.

A concordance file was generated such that the two variants were the node with surrounding contexts (+10 words on each side). We then manually removed instances where it had anaphoric reference (e.g., it was able to perform …) or the to-infinitive or that-clause was preceded by other elements but adjectives (e.g., it was good proof that …). We independently coded the first 10% of the file and calculated an interrater agreement, which was 96%. We resolved any discrepancy in our coding through discussion before further coding. After manual editing, we retained 15,862 and 23,627 instances of Adj-that and Adj-to, respectively. Our final preprocessing step included extracting adjectives from the nodes and coding the variant with which each adjective was attested. We additionally lemmatized comparative and superlative adjectives (e.g., good for best and better) and made the spelling consistent (e.g., okay for o.k. and ok). Table 1 presents descriptive information for the two variants. In total, there were 585 types: 262 types appeared with Adj-that and 495 with Adj-to. Of the 262 types, 90 were attested only with Adj-that (49 hapaxes). Likewise, of the 495 types, 323 types appeared solely with Adj-to (152 hapaxes). The two variants shared 172 types. Table 2 presents the top 15 most frequent adjectives of each variant, along with co-occurrence frequencies with each of the constructions.

Table 1. Descriptive information of the two target variants

Note. H_norm = normalized entropy.

Table 2. The 15 most frequent adjectives of each variant in COCA

In addition to the two target variants, we identified and extracted from COCA five other instantiations of the introductory-it construction, as documented in Francis et al. (Reference Francis, Hunston and Manning1998) and Larsson (Reference Larsson2016). In each of these patterns, a finite or nonfinite subordinate clause is preceded by a matrix predicate with an adjective as the predicate lemma (that is, an element that contributes most to the meaning of the predicate; see Larsson, Reference Larsson2016). Schematic examples of these patterns are it V ADJ wh- (e.g., it is not clear whether the test was reliable) and it V N as ADJ that (e.g., it strikes me as rather odd that nothing was accomplished). Including frequencies of adjectives in these five patterns into a total count enabled us to compute two ΔP _{(variant → adjective)} scores for every adjective, one for each variant, such as ΔP _{(Adj-that → possible)} and ΔP _{(Adj-to→ possible)}. In total, we identified 2,300 instances of the five patterns; examples of each pattern can be found in the Supplementary Materials.

A ΔP _{(variant → adjective)} score for each adjective–variant combination was calculated from frequency counts in a 2 × 2 contingency table as differences of proportions (Gries & Ellis, Reference Gries and Ellis2015, p. 240), and its values range from −1 to +1. Positive ΔP values indicate that the presence of the cue increases the likelihood of the outcome, whereas negative values indicate the opposite. To illustrate, we can establish how strongly Adj-that cues clear by obtaining frequencies when the adjective appears with the variant (n = 2,826) as opposed to when it occurs with Adj-to and other instantiations (n = 523) and summing frequencies of all other adjectives that are attested with Adj-that and with the rest of the patterns but Adj-that (see Table 3). Here, an observed value of ΔP _{(Adj-that → clear)} is 0.16 (that is, from $ \frac{\mathrm{2,826}}{\left(\mathrm{2,826}+\mathrm{13,036}\right)}-\frac{523}{\left(523+\mathrm{25,404}\right)} $ ). Similarly, we can assess how strongly Adj-to attracts clear by obtaining co-occurrence frequencies between the two elements (n = 2), along with other frequency counts, and constructing a 2 × 2 contingency table, similar to Table 3. Inputting the raw frequencies into a formula, we obtain a ΔP _{(Adj-to → clear)} score of −0.18. We can therefore see that Adj-that attracts clear but Adj-to repels it. We calculated observed ΔP _{(variant → adjective)} scores for all of the 585 types identified from the corpus analysis.

Table 3. The 2 × 2 co-occurrence frequencies of clear

The ΔP scores capture adjective–variant contingencies that are present in the input of academic English to which language users are exposed. To ensure that the ΔP scores we included in our statistical analysis (see below) solely reflected such associations, we completed additional steps, as discussed in Gries (Reference Gries2022) and recommended by one of the reviewers. First, we computed two theoretically possible ΔP scores for each adjective–variant combination. For example, Table 4 presents one scenario, in which all instances of clear occur with Adj-that. In this case, a ΔP score would indicate the strongest possible attraction between Adj-that and clear. As all counts of clear are now in the upper-left cell (that is, 2,826 + 523 = 3,349), the frequency counts in the other cells are adjusted so that they sum to actual frequencies of adjectives and variants in the column and row totals, respectively. Note that the actual frequencies are kept unchanged from Tables 3 to 4; this ensures that the effect of frequency is controlled for (see Gries, Reference Gries2022, p. 24). We obtain a ΔP _{(Adj-that → clear)} score of 0.21 from Table 4. For the other scenario, none of the instances of clear are in Adj-that (that is, the value of 3,349 is moved to the lower-left cell), so a ΔP score would indicate the strongest possible repulsion between Adj-that and clear. In this scenario, we obtain a ΔP score of −0.13 (that is, from $ \frac{0}{\left(0+\mathrm{15,862}\right)}-\frac{\mathrm{3,349}}{\left(\mathrm{3,349}+\mathrm{22,578}\right)} $ ). Second, we determined where observed ΔP scores were with respect to the two theoretically possible ΔP scores on either end of the repulsion–attraction continuum. To illustrate, for the association of Adj-that and clear, we determine where the observed value of 0.16 falls within a theoretically possible range of −0.13 and 0.21. A value of 0.85 is observed—that is, from $ \frac{0.16-\left(-0.13\right)}{0.21-\left(-0.13\right)} $ . With this transformation, the ΔP scores are between 0 and 1, and the higher the score, the more strongly attracted an adjective is to a particular variant. Table 5 presents the top 15 adjectives of each variant ranked by observed ΔP scores, along with transformed ΔP scores. In the next section, we discuss the statistical analysis we conducted to test the contribution of this item-level predictor, in addition to other predictors, to responses from the elicitation task.

Table 4. A contingency table demonstrating the strongest possible attraction between Adj-that and clear

Table 5. The top 15 adjectives of each variant ranked by observed ΔP scores

Statistical analysis of the elicitation data

We completed the following steps prior to statistical analysis. First, we dropped 42 partial, misspelled, or nonadjective responses (e.g., typic, possile, and surprisingly) from the elicitation data, which altogether constituted approximately 4% of the total observations (n = 1,057). Second, we removed past-participle responses (e.g., argued and understood), which accounted for 10.72% (n = 62 out of 578) and 11.89% (52/437) of the responses in L1 English and L1 Thai-L2 English participants, respectively. Finally, we lemmatized answers that were comparative or superlative adjectives (i.e., good for better and best) and retained 901 responses from 84 participants (L1 English: 516; L1 Thai-L2 English: 385). As can be seen in Table 6, summing over the two variants, important was the most common answer (n = 53), followed by necessary (29), obvious (26), likely (25), and possible (24).

Table 6. The 15 most frequent adjectives of each variant in the experiment (L1 and L2 groups combined)

To address our first research question, we ran a mixed-effects logistic regression model that related adjective–variant contingencies in the input and participants’ engagement with academic English writing—among other things—to their responses in the elicitation task. We began by creating a binary outcome variable that indicated whether each of the 901 responses generated by the participants “fit” a particular variant. Take, for instance, four hypothetical answers—clear, likely, difficult, and important—to the target item it is [blank] that. Based on the observed ΔP _{(variant → adjective)} scores, clear and likely were attracted to Adj-that, whereas difficult and important were cued by Adj-to (see Table 5). In fact, difficult and important were repelled by Adj-that (i.e., ΔP _{(Adj-that → difficult)} = −0.10, and ΔP _{(Adj-that → important)} = −0.12). Therefore, given the Adj-that variant in the target item, we would code clear and likely each as a cued response (cued = 1) but not difficult and important (noncued = 0). With this outcome variable, we were thus able to capture one critical aspect of language users’ constructional knowledge—that is, the knowledge of the adjective–variant associations in the two introductory-it variants.

Of the total 901 responses, 116 were unattested with either variant in our corpus analysis (e.g., able, reliable, and excellent) and thus were dropped, leaving 785 observations in the data set (L1 English: 458; L1 Thai-L2 English: 327).Footnote ⁴ Altogether, there were 183 types, 63 of which were hapax legomena. On average, the L1 English group supplied 5.34 (SD = 2.86, range: 1–13) responses for Adj-that and 5.19 (SD = 2.11, range: 1–10) answers for Adj-to, whereas the L2 group attempted 4.29 (SD = 2.42, range: 1–11) and 4.54 (SD = 2.23, range: 1–14) responses for Adj-that and Adj-to, respectively. A linear mixed-effects model with participants as random intercepts showed that L1, variant, and the interaction between the two predictors did not predict the number of responses (all ps > .05).

We conducted a mixed-effects logistic regression analysis on the 785 observations, predicting the binary outcome—cued responses—in the elicitation task, from the following set of predictors:

1. (1) Introductory-it variants: a categorical variable for the variant of a target item for which participants supplied their answers, either Adj-that (e.g., It is [blank] that) or Adj-to (e.g., It is [blank] to). We chose this predictor primarily because the two variants differed in the number of attested types (see Table 1; see also Larsson, Reference Larsson2016) and because usage-based studies have shown that high type frequency is critical to constructional generalization (Azazil, Reference Azazil2020).

2. (2) ΔP _{(variant → adjective)} scores: a continuous variable for the adjective–variant associations. Given the design of the elicitation task, we entered as a predictor transformed ΔP _{(variant → adjective)} scores, which ranged from 0.01 to 1 in the data set. We used transformed ΔP rather than observed ΔP to control for the effect of frequencies (see Gries, Reference Gries2022). We used ΔP scores of adjectives in the variant to which they were attracted regardless of the variant of a target item. For instance, a response clear to the items it is [blank] that and it is [blank] to was given the same ΔP score of 0.84 for the word’s attraction to Adj-that.

3. (3) Adjective frequencies: a continuous variable for the co-occurrence frequencies of adjectives with the variant to which they were attracted, as obtained from the academic section of COCA. Take, for example, two answers—clear and difficult—to the item it is [blank] that. We assigned the frequencies of 2,826 to clear for its co-occurrences with Adj-that and 4,615 to important for its co-occurrences with Adj-to.Footnote ⁵

4. (4) L1s: a categorical variable for participants’ L1, either English or Thai.

5. (5) Degrees: a categorical variable for a graduate degree participants were pursuing, either a master’s or PhD.

6. (6) AWE-Q scores: a continuous variable for participants’ average AWE-Q scores. We used this predictor as an indirect measure of participants’ active use of the two introductory-it variants, among many other constructions, in their academic studies.

In addition to the above predictors, we included two control variables as follows:

1. (7) Linking verbs: a categorical variable for the verb embedded inside a target item, either is (e.g., It is [blank] that) or seems (e.g., It seems [blank] to).

2. (8) Trials: a continuous variable for the order in which responses were supplied in each target item by the participants.

We applied the following transformation to the above predictors. Continuous variables were grand-mean centered and standardized, and adjective frequencies were log₂ transformed prior to centering and scaling, but transformed ΔP scores were not because doing so did not affect the shape of the distribution. Categorical predictors were sum-coded.

We took a bottom-up approach in building our mixed-effects models, as recommended by Hox et al. (Reference Hox, Moerbeek and van de Schoot2017). First, we added into the model item-level (i.e., variants, frequencies, ΔP scores, linking verbs, and trials) and participant-level predictors (i.e., L1s, degrees, and AWE-Q scores) as fixed effects and assessed whether they were correlated. We found that all variance inflation factors (VIFs) were close to 1. We then included intralevel interaction terms (e.g., the interaction between variants and ΔP scores) and checked the VIFs. Along with the fixed-effect structure, we placed random intercepts on participants and items. For item-specific random intercepts, we considered only adjectives with frequency ≥ 2 as individual factor values and coded all 63 hapax legomena as “other.” Thus, instead of 183, there were 121 factor values for items.

Second, we assessed whether random slopes were justified. Initially, our model consisted of by-participant random slopes for variants, adjective frequencies, and ΔP scores and by-item random slopes for L1s. As singular fit was reported, we ran a principal components analysis on the random-effect structure (see Gries, Reference Gries2021) and subsequently simplified the model by dropping random slopes for—in this exact order—L1s, ΔP scores, and adjective frequencies. Likelihood-ratio tests (LRTs) confirmed the removal (all ps > .75). In the end, the random-effect structure consisted of random intercepts for participants and items as well as by-participant random slopes for variants.

Last, we incorporated cross-level interaction terms into the model and tested whether any of the fixed-effect terms could be removed (see Gries, Reference Gries2021).Footnote ⁶ The final model from which we drew inferences was significantly different from the null model—χ ²(9) = 179.81, p < .001; AIC_{final model} = 825.52; and AIC_{null model} = 987.33—with all VIFs near 1. The value for R ²_marginal was .36, and R ²_conditional was .52. The model’s C score was 0.89, which was above the 0.80 threshold commonly used in linguistics.

To address the second research question vis-à-vis L2 users’ English proficiency and their performance on the elicitation task, we performed a mixed-effects logistic regression analysis with only data from the L2 English participants. Because four participants did not report their TOEFL scores, they were removed from further analysis. In total, there were 301 data points. Initially, we included the same set of predictors used to address the first research question, except L1s and related interactions. Subsequently, we simplified the random-effect structure of the model, retaining only the by-participant random intercepts and random slopes for variants, and tested which predictors could be dropped with LRTs (all ps > .25). At this stage, as the AWE-Q scores were nonsignificant, the predictor was dropped. The final model from which we drew inference was significantly different from the null model—χ ²(5) = 86.87, p < .001; AIC_{final model} = 299.16; AIC_{null model} = 376.03. All predictors had VIFs close to 1. The R ²_marginal was .42, and R ²_conditional was .60. The model’s C score was 0.91.