2.1.1 Participants.

We preregistered a sample of 48 participants (link to preregistration: https://doi.org/10.17605/OSF.IO/MX3DW). Because we scheduled more participants than needed in order to account for cancellations and eliminations, the final sample included 51 typically-developing 4- and 5-year-olds (48–71 months, M_age = 61 months; 25 boys and 26 girls). Participants were recruited via an in-lab participant database between June 30, 2016 to July 4, 2019. Children were predominately White (nine reported mixed ethnicity, two Black and one South Asian; 12 did not report race/ethnicity) and came in majority from families of average to above-average income (four did not report family income). All children spoke English, the language of the study. Data from six additional participants were excluded due technical difficulties (1), failure to answer one or more test trials (2), having participated twice (1), poor language comprehension (1) and falling outside the target age range (1).

2.1.2 Materials and procedure.

Before participating in the study with their child, parents provided their written consent by completing a consent form. Children’s verbal assent was also obtained before starting the testing sessions. Children were tested individually in a quiet room on a university campus. Each child sat in front of a laptop or tablet computer screen with the experimenter sitting beside them. When parents were present in the room, they were asked not to interact with the participant during the study. Experimental sessions were video recorded with a camera placed in a way that allowed for an unobstructed view of the experimental setting. The recorded videos were later used to verify the participants’ answers. This study was part of a larger experiment including additional conditions not reported or described here.

Introduction phase. Children were introduced to a game where they were told they would have to name objects pictured on cards that were placed in front of them. Children were told they would be rewarded with stickers every time they named an object correctly. To familiarize children with the fact that they would see unknown objects, we presented both highly familiar pictures (e.g., an apple) and unfamiliar ones (e.g., a coffee roaster) and asked them to name the pictures, providing feedback each time. Subsequently, children were introduced to a puppet who they were told would decide on the administration of stickers for subsequent trials. They were informed that the puppet was very nice and would reward them with stickers regardless of their answers.

History phase. Children were told that, for subsequent trials, they could receive help from two adult female informants presented on video (hereafter labelled B and S). They watched two brief videos introducing each informant waving, and then watched a series of videos in which B and S named five familiar objects (e.g., dress, shoes, desk) while holding pictures that weren’t visible to the child (so that the child could not tell whether the informants were accurate or not). One informant was confident (e.g., saying: “Oh I know, that’s a dress!” with a declarative tone, while holding a picture not visible to the child, raising the index finger and having a satisfied facial expression) and the other was hesitant (e.g., saying: “I… guess that’s a dress?” with an upward inflection, while also holding a picture not visible to the child, shrugging shoulders and having a puzzled facial expression). The informants were always presented in the same order, B then S, but which informant served as the confident informant was counterbalanced to account for order effects.

Test phase. After watching the history videos, five endorse test trials were conducted. In each trial, a picture of an unfamiliar object was placed in front of the participants. The experimenter then played a video of each informant proposing a different made-up label for the same novel object, one confidently, the other hesitantly. Confidence and hesitance were expressed using the same cues portrayed during the history phase. For instance, B would refer to an object saying “Oh I know, that’s a heem!”, whereas S would say “I… guess that’s a bloof?”. Subsequently, the experimenter asked children to label the unfamiliar object using one of the novel labels provided by the informants. The same procedure was repeated in all five trials.

The experiment had a between-subjects design and participants were randomly assigned to one of two conditions: consistent confidence or inconsistent confidence. In the consistent confidence condition, the informant who was confident during the history phase remained confident during the test phase and so forth with the hesitant informant. In the second condition, inconsistent confidence, the informant who was confident during the history phase became hesitant during the test phase and vice-versa.

3.1.1 Participants.

We preregistered a sample size of 64 participants for Part 1. We scheduled more participants than required to account for cancellations and eliminations in both Parts 1 and 2; thus, the final sample consisted of 82 typically-developing 2- and 3-year-olds (31–39 months, M = 35 months, 38 boys and 44 girls), recruited from an in-lab participant database and local daycares between November 14, 2016 and July 4, 2019. Note that demographic information was only collected of in-lab participants. Children were predominately White (seven reported mixed ethnicity, three Asian, one Black and one Indigenous; 25 did not report race/ethnicity) and came in majority from families of average to above-average income (15 did not report family income). The study was either conducted in English (65 children) or in French (17 children). Of the 82 participants, 15 were excluded from Part 1 because of failure to answer one or more trials (12), experimental error (1), or poor language comprehension (2), and 10 were excluded from Part 2 because of camera malfunction (6), experimental error (3), or parental interference (1). Eight additional children were tested but were excluded from both parts for a combination of the reasons above. The final sample sizes were therefore N = 67 and N = 72 for Parts 1 and 2 respectively.

3.1.2 Materials and procedure.

Part 1: Word learning. This study was conducted in person and, as in Experiment 1, before participating in the study with their child, parents provided their written consent by completing a consent form. The child’s verbal assent was obtained before starting the testing session. The word learning task was also closely modelled on Experiment 1, with a few minor modifications. Specifically, the introduction was shortened to include only two highly familiar pictures in order to encourage children to label objects verbally, and the experimenter placed a picture of each informant on the table to help participants remember the informants’ identities and allow them to point to one informant if they were too shy to answer the questions verbally. Additionally, no puppet was presented, and no stickers were mentioned or given.

Part 2: Imitation. For the second part of the study, we created a task that aimed to test the same hypothesis as Part 1 but with reduced verbal demands on young children and a between-subjects design. The task consisted of a Familiar Objects phase and a Novel Objects phase.

In the Familiar Objects phase, the experimenter first showed participants a tray covered by a cloth. The cloth was then removed to reveal six familiar toys (see Fig 1 for pictures of the tray and the six familiar objects). The experimenter then put the cloth back over the tray and introduced an adult male informant on video (hereafter called “A”). Children watched three videos of A playing with three of the familiar toys presented on the tray (the car, the hairbrush, and the bowl/spoon combination). In all three videos, A was portrayed as being either consistently hesitant or confident (between subjects) while playing with the toys. Confidence and hesitance cues were similar to the nonverbal cues used in the first part of the experiment: confidence cues included exclamations “aha!” and “uh-huh!”, a raised index finger, a satisfied facial expression, and nodding; hesitance cues included the sounds “hmmm…” and “huh?”, shrugging of shoulders, and a puzzled facial expression. Afterwards, the experimenter put the tray in front of the participant, removed the cloth, and told the participant they could play with the toys as much as they wanted, as long as they stayed on the table (where a video camera could keep track of the child’s actions). The experimenter then started a stopwatch and pretended to be doing work on the laptop to give the child a chance to play freely with the toys. After two minutes had elapsed, children were asked to place the toys back on the tray so that they could take a look at the toys on another tray.

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Fig 1. Experiment 2, Part 2.

Pictures of the trays with familiar (left) and unfamiliar objects (right).

https://doi.org/10.1371/journal.pone.0298183.g001

In the Novel Objects phase, the same procedure was repeated but with a tray containing eight unfamiliar toys. The participant first watched videos of A playing with some of the unfamiliar toys (the twisted jump rope, ketchup bottle, gears, and easy button; see Fig 1) again with confidence or with hesitance as in the Familiar Objects phase. Confidence/hesitance during the Familiar and Novel Objects phases were fully crossed, so that approximately a quarter of the children saw A as consistently confident, a quarter consistently hesitant, a quarter confident then hesitant, and a quarter hesitant then confident. Participants were once again given two minutes to play freely with the toys.

Part 1: Word learning.

Analyses reported in this section, except in the last paragraph, are preregistered. The main dependent variable was the number of times (out of 5 trials) that children selected the same word as the individual who was confident at test. We also computed, as a secondary dependent variable, the Confidence Difference score; i.e., the difference between performance on the last two trials and the first two trials, in order to see if the confidence at test has an increasing influence with more test trials. First, we calculated nondirectional independent samples t-tests on both these indices in order to test whether the language of study (English or French) affected performance. Neither was significant (both ps>.800).

A directional one-sample t-test on the main dependent variable revealed that, contrary to our expectations and to past research, children did not overall prefer to learn from the confident compared to the hesitant individual (M = 2.73, SD = 1.79; t(66) = 1.059, p = .147, one-tailed, ns). We computed a directional independent samples t-test comparing performance between the consistent and inconsistent conditions, expecting that, if confidence was treated as a person-specific indicator, we would find a greater tendency to trust an individual who was consistently confident over one who is currently confident but was previously hesitant. The mean pattern was actually in the opposite direction: consistent M = 2.48, SD = 1.75; inconsistent M = 2.97, SD = 1.82; t(65) = -1.11, p = .865, one-tailed, ns. Finally, it was expected that children in the inconsistent condition would be more likely to switch their trust over to the currently confident individual in the last two test trials compared to the first two test trials, and as a result, the mean Confidence Difference Score would be significantly greater than zero. This was not the case: the mean score was in the opposite direction from what was expected, M = -.26, SD = .79; t(33) = -1.95, p = .970, one-tailed, ns.

Moreover, although not preregistered, nondirectional trial-by-trial analyses were conducted in order to examine whether there were any other underlying effects. When combining both conditions, participants significantly favored the currently confident informant on the first trial (69%, p = .003), but not on any other trial (Trial 2: 55%, p = .464; Trial 3: 51%, p = 1.000; Trial 4: 46%, p = .625; Trial 5: 52%, p = .807). When examining each condition separately, similar results were found, though Trial 1 was only significantly above chance for the Inconsistent condition (Consistent condition: Trial 1: 64%, p = .163; Trial 2: 48%, p = 1.000; Trial 3: 48%, p = 1.000; Trial 4: 39%, p = .296; Trial 5: 48%, p = 1.00, Inconsistent condition: Trial 1: 74%, p = .009; Trial 2: 62%, p = .229; Trial 3: 53%, p = .864; Trial 4: 53%, p = .864; Trial 5: 56%, p = .608).

Part 2: Imitation.

Analyses for Part 2 were not preregistered and should therefore all be considered exploratory. Videos were coded to measure six variables: the number of actions performed by A imitated by the child for familiar (out of 3) and novel objects (out of 4); the amount of time within each two-minute free play phase spent playing with any of the three demonstrated familiar objects or any of the four demonstrated novel objects; and the amount of time spent playing with non-demonstrated familiar and novel objects. For the purpose of coding, any contact with an object was coded as “playing”. Note that, because children could spend time playing either with multiple toys at once or not at all, playing times could add up to values greater or smaller than 120 seconds within each phase. Videos from 10 participants were double-coded to verify interrater reliability. Agreement was excellent for the two imitation variables, with 97% agreement for familiar toys and 95% agreement for novel toys. The mean absolute difference between coders in the total playing times with each object category varied between 2.2 and 4.9 seconds.

In the Familiar Objects phase, we first computed a 2x2 mixed ANOVA comparing the amount of time played with toys that were demonstrated or not by the model as a function of the confidence of the model in that phase. We expected that children would prefer to play with the toys used by the model, but that this effect would be moderated by the model’s confidence in that phase. We found a significant preference for playing with toys used by the model over the distractor toys, F(1,70) = 33.38, p < .001. Mean playing time was slightly longer when A was confident than hesitant, but this main effect was not significant, and neither was the interaction effect (see Fig 2). We also compared the number of familiar actions imitated as a function of the model’s confidence with an independent-samples t-test: In both conditions, children imitated an average of 1.64 actions out of 3 (ns).

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Fig 2. Experiment 2, Part 2.

Time spent playing with familiar objects (top) and novel objects (bottom) as a function of the type of object (shown toys vs. distractors) and model confidence. Error bars represent standard errors.

https://doi.org/10.1371/journal.pone.0298183.g002

In the Novel Objects phase, we computed a 2x2x2 mixed ANOVA on children’s playing time with type of toy (demonstrated or not) as a within-subjects variable and current and past confidence as between-subjects variables. Once again, the only significant effect was that children played longer with toys that were demonstrated in videos than with distractors, F(1,68) = 44.07, p < .001. There were no other significant main or interaction effects (see Fig 2). We also conducted a 2x2 ANOVA on children’s imitation of the four novel actions as a function of current and past confidence. The only significant effect, unexpectedly, was a greater tendency to imitate when the model was previously hesitant (M = 2.36, SD = 1.42) than confident (M = 1.61, SD = 1.02, F(1,68) = 6.46, p = .013). We do not have a clear explanation for this counterintuitive effect, and, given the number of exploratory analyses presented here, it should be interpreted with caution. Although the means for current confidence were in the predicted direction (currently confident: M = 2.16, SD = 1.17; currently hesitant: M = 1.80, SD = 1.39; d = .28, 95% CI [-.19, .75]), this difference was not significant.

These effects seem to suggest that children were influenced by the model’s demonstrations, as in both phases they showed more interest in the toys demonstrated by the model than in the distractors. However, playing and imitation did not significantly vary based on the confidence of the model, thus making it unclear whether children were noticing confidence cues at all, let alone formulating any sort of interpretation.

Overall, contrary to previous findings and those obtained with older children, these results suggest that 2- and 3-year-olds did not prefer to learn from the confident informant even when this informant was consistently confident. In fact, in Part 1, participants did not consistently side with either informant (confident or hesitant) except on the very first trial, where children performed in the same direction as those of Experiment 1, i.e., sided with the currently confident informant even when that informant was previously hesitant. It could be that the manipulation was simply too complex for children this young. Therefore, it remains unclear whether younger preschoolers interpret confidence as an indicator of situational or individual knowledge.

4.1.1 Participants.

We preregistered a sample size of 40 participants (link to preregistration: https://osf.io/9s63d?view_only=ede9c18920604ac68aa8ad697bcda67c), but as in Experiments 1 and 2, additional children were tested to account for exclusions. Our final sample comprised 41 typically-developing 4- and 5-year-olds (48–71 months, M_age = 59 months; 21 girls and 20 boys), recruited from an in-lab participant database between December 8, 2019 to March 25, 2022. Children were predominately White (11 reported mixed ethnicity, two Asian, and one Black; four did not report race/ethnicity) and came in majority from families of average to above-average income (two reported below average income and three did not report family income). The study was either conducted in English (28 children) or in French (13 children). There were four additional children that were excluded from our final sample due to failure to answer one or more trial.

4.1.2 Materials and procedure.

The current study employed a similar procedure as Experiment 1 but with several important modifications. First, the study began just as the COVID-19 pandemic resulted in a shutdown of in-person research for an extended period; therefore, three participants were tested in-lab and the remaining participants were tested virtually via a videoconferencing app. Second, to broaden our recruitment options, we recruited both English- and French-speaking participants (both languages are widely spoken in the city where the study took place). A French adaptation of the study was thus created (i.e., the script was translated in French and videos of two French-speaking adult female informants were used). Moreover, in Experiment 3, no puppet was presented, and no stickers were mentioned or given, as these were not relevant to our manipulation. Finally, and most importantly for the purpose of the study, the history phase was closely modelled on Experiment 1 but the test phase was modified and extended as described below.

History phase. As in Experiment 1, this history phase serves to establish the informants’ history of confidence. The same procedures as in Experiment 1 were followed except that there were no introduction videos of the informants; instead, the experimenter introduced each informant via pictures shown on the screen. Participants then watched the same videos as in Experiment 1 of the informants labeling different pictures.

Test phase–Part 1: Word learning. In each of five endorse test trials, a picture of an unfamiliar object was shown to participants. However, rather than seeing the informants label these objects, children were told that the two informants wrote down (conflicting) labels that the experimenter then read to the children. Children were asked for each picture which of the two answers they believed was the correct label.

Test phase–Part 2: Attributions. For the attributions, children were told the experimenter “had a few questions about B and S.” They saw pictures of both and were asked to explicitly choose which one possessed each of six attributes. The first two were knowledge attributes (i.e., “Who knows the names for a lot of bugs?” and “Who knows a lot about stars and planets?”); the next three were about prosocial behaviours (i.e., “Who always says thank you?” and "Who shares her things with her friends and family?”), and affiliations (i.e., “With whom would you like to play?”); the last trial was about a neutral attribution (i.e., “Who doesn’t like spaghetti?”), to serve as a distractor.

Test phase—Memory check. The last part of the study was a memory check to ensure children were able to recognize the confidence cues and remember them throughout the experiment. Children were asked which of the two informants was previously confident (“Now, remember earlier in the videos, one of them said « Oh, I know! » when she named pictures. Which one said that? B or S?”) and which was previously hesitant (“And one of them said “Hmm, I guess?” in the videos. Which one said that? B or S?”). The order of the two memory questions was counterbalanced.

Part 1: Word learning.

To determine whether participants relied on the past confidence cues when learning semantic information, we calculated how many times, in 5 trials, children sided with the informant who was confident in the history phase. We then compared the mean to chance (2.5) with a directional one-sample t-test, which revealed that children overall did not prefer to learn from the previously confident informant over the previously hesitant one, M = 2.51, SD = 1.23; t(40) = .06, p = .475, d = 0.01, 95% CI [-.30, .32]. Additionally, we conducted trial-by-trial analyses (not preregistered) and results from nondirectional binomial tests reveal that children did not significantly perform above chance on any trials (Trial 1: 56%, p = .533; Trial 2: 54%, p = .755; Trial 3: 59%, p = .349; Trial 4: 37%, p = .117; Trial 5: 46%, p = .755).

Part 2: Attributions.

Analyses for the attributions were not preregistered and should therefore all be considered exploratory. Participants did not rely on past confidence cues to learn novel words. To examine whether participants attributed enduring traits to the informants based solely on their past confidence, we conducted binomial tests for each attribution trial. Two participants were not included in these analyses because they did not participate in this phase (although they had completed the word learning phase). Two participants who did not answer the last three attribution questions were only included for the first three questions. Participants did not attribute knowledge (knowledge of bugs: Nconfident = 23/39, p = .337; knowledge of stars and planets: Nconfident = 22/39, p = .522) nor social traits (saying thank you: Nconfident = 19/39, p = 1.000; sharing: Nconfident = 19/37, p = 1.000) to either of the previously confident and hesitant informants, but reported that they would prefer to play with the previously confident one (Nconfident = 25/37, p = .047). These results suggest that overall, participants performed at chance when making most attributions and thus don’t seem to generalize traits that they could have inferred from the past confidence cues to a situation in which no current confidence cues are present.

Memory check.

To examine whether participants were able to detect and remember past confidence cues, we then performed a binomial test (considering only success or failure at memorizing who was previously confident versus hesitant). We only included children who succeeded at both questions and used 0.5 as chance, although true chance would lead to 0.25, to be conservative and given that children’s responses to both questions are unlikely to be completely independent (i.e., pragmatically, if children answered B to the first question, they could feel compelled to answer S to the second question even if they did not remember anything about the History Phase). Results indicate that participants did succeed at the memory check above chance (.5), Nsuccess = 28 (68%), p = .014.

We repeated our analyses for the Word Learning trials looking only at participants who succeeded at the memory check (N = 28) to chance. Results revealed that they did not significantly rely on past confidence, M = 2.79, SD = 1.23; t(27) = 1.231, p = .115, d = .24, 95% CI [-.14, .61]. This suggests that the fact that participants did not rely on past confidence to learn semantic information is not merely because they could not remember the past confidence cues, which seems to support the idea that children perceive confidence cues a situational. Yet, given the direction of the mean, we cannot rule out that there is a small tendency, in children who best remember the History Phase, to treat confidence as person-specific, but that we did not have the statistical power to detect this difference.

For the attribution task, when looking at participants who succeeded at both memory questions, we obtained results that did not seem to significantly differ from chance, though statistical power was admittedly low (knowledge of bugs: Nconfident = 18/27, p = .122; knowledge of stars and planets: Nconfident = 19/27, p = .052; saying thank you: Nconfident = 11/27, p = .442; sharing: Nconfident = 13/26, p = 1.000; play with: Nconfident = 18/26, p = .076).

Taken together, these results indicate that four- to five-year-olds are able to pay attention and remember confidence cues. However, the findings suggest that, when they are learning novel words and making knowledge and social attributions, they don’t systematically favor informants who were more confident in prior situations. These results support the notion that children perceive confidence cues as situational cues to knowledge thus not transferring the inferred knowledgeability from past confidence cues to a current situation without any indicator of present confidence. Additionally, if confidence was interpreted as person-specific, we would have expected to see knowledge attributions made toward the previously confident informant even when no confidence cues were currently present since it would have been seen as a trait transferrable or generalizable across situation, but it was not the case. Of note, given the results found for one of the social attribution trials (i.e., participants would prefer to play with the previously confident informant), it is possible that children may be able to attribute some specific enduring traits (possibly social traits) to previously confident or hesitant informants. Importantly, this finding may also be a type I error given the usage of a p-value of .05 and 6 tests, and as such, should be interpreted with caution.

We also note that, when only selecting children who correctly answered both memory questions, many results were in the predicted direction for person-specific attributions though not significantly so. We therefore cannot rule out the possibility that there is, in fact, a small tendency to make person-specific attributions that we did not detect because of low power. It is worth noting that correct answers to memory questions can both result from genuinely remembering the History Phase as well as from a coincidental positive bias towards the confident informant (or negative bias towards the hesitant informant)–for instance, some children may just like the look of one informant more than the other. It is thus difficult to unambiguously interpret responses on one type of test trial that select for answers on a different test trial, given that similar irrelevant biases could drive answers on all trials.