2.1.3.1. Stroop stimuli

Based on Aïte et al. (Reference Aïte, Cassotti, Linzarini, Osmont, Houdé and Borst2016), 16 color-word stimuli were created by combining 4 different color names (‘red’, ‘green’, ‘blue’, and ‘yellow’) with 4 corresponding ink colors (RGB color codes 255;0;0, 0;255;0, 0;0;255 and 255;255;0). We used these stimuli to create 64 congruent and 64 incongruent Stroop experimental trials. Before the main experiment , participants were presented with a set of practice trials (Section 2.1.4.2). For the color practice, 4 circle stimuli were created each filled with either red, green, blue, or yellow ink (RGB color codes 255;0;0, 0;255;0, 0;0;255 and 255;255;0).

All stimuli were presented in the center of the screen on a gray background (RGB code 135; 135; 135) in randomized order. Participants were instructed to press the key ‘d’ if the word was presented in the color red, the key ‘f’ if it was presented in blue, the key ‘j’ if it was presented in green, and the key ‘k’ if it was presented in yellow (we chose these 4 response keys as they have the same position in the 3 most common keyboard layouts: QWERTY, QWERTZ, and AZERTY). The response times were measured from the stimulus onset until the button press.

Congruent trials allowed us to test for a guessing confound and are reported in this context. Our main results concern the critical incongruent trials unless otherwise stated.

2.1.3.2. Load task

In the two-response version of the Stroop task (Section 2.1.4.2), we used a secondary digit memorization task (Lavie, Reference Lavie2005; Lavie et al., Reference Lavie, Hirst, de Fockert and Viding2004), as this type of task has been shown to burden cognitive control in Stroop-like tasks (i.e., it has been found that this task increases the Stroop interference effect, e.g., de Fockert et al., Reference de Fockert, Rees, Frith and Lavie2001; Lavie and De Fockert, Reference Lavie and De Fockert2005; Lavie et al., Reference Lavie, Hirst, de Fockert and Viding2004; but also Gao et al., Reference Gao, Chen and Russell2007). On each trial, participants saw a sequence of 6 (black) digits (i.e., the memory set). All digits were randomly selected from 1 to 9 without replacement on a given trial. The memory probe consisted of a single black digit, a question mark, and a message reminding participants of the keyboard response buttons. Participants were asked to indicate whether the probe had appeared in the memory set on that trial. They were instructed to press ‘d’ for probe-present and ‘k’ for probe-absent responses. For half of the trials, the correct answer was ‘probe present’.

2.1.4.1. One-response (deliberative-only) pre-test

In order to obtain a baseline Stroop performance, we conducted a pre-test where participants performed a traditional one-response color-word Stroop task, without a digit memorization load or a deadline. We recruited 25 participants (52% female; mean age = 35.4 years, SD = 17.3) online on Prolific Academic (www.prolific.ac). Only native English speakers from Canada, Australia, New Zealand, the United States of America, or the United Kingdom were allowed to take part in the study. Participants were paid £1.00 for their participation. A total of 40% of the participants reported a high-school degree as their highest education level, while 56% reported a bachelor’s degree and 4% a Master’s degree.

The idea was to base the response deadline of the initial response stage in our two-response design on the average response time in the one-response pretest (e.g., Bago and De Neys, Reference Bago and De Neys2017, Reference Bago and De Neys2020). Thus, in the one-response pretest participants were presented with the same amount of trials and the same stimuli as in the main two-response study. The only difference from the main study was that participants were asked to provide a single response and they only received standard Stroop task instructions to respond ‘as fast and as accurate as possible’. The average response time for the congruent trials was 755 ms (SD = 134 ms) and for the incongruent trials, it was 893 ms (SD = 197 ms).Footnote ¹ Based on these values we decided to set the maximum response deadline for the initial response to 750 ms (i.e., approximately the mean of congruent trials which do not require controlled processing to answer correctly).

To verify that participants were indeed under time pressure during the initial stage, we compared the response times for the critical incongruent trials between the one-response pre-test and the initial responses in the main two-response study. For this comparison, we excluded all trials with missed load memorization or missed deadlines in the initial stage of the two-response study. The results showed that participants responded much faster in the initial response stage of the main study (incongruent trials: 580.8 ms, SD = 55.4 ms), compared to that of the one-response study (incongruent trials: 893.3 ms, SD = 196.5 ms; i.e., responses were on average more than 1.5 SDs faster than in the one-response study). A Welch Two Sample t-test indicated that this difference was significant (t(26.47) = 7.76, p < .001).

In addition, the one-response pre-test allowed us to check for a potential consistency confound in our main two-response study. More specifically, since the study requires two consecutive responses, participants might provide the same response in the initial and the final stage, merely driven by the desire to appear consistent (Thompson et al., Reference Thompson, Turner and Pennycook2011). In this case, the correction rate from the initial to the final response would be underestimated. Previous two-response work in other fields has argued against the presence of this confound (Bago and De Neys, Reference Bago and De Neys2017, Reference Bago and De Neys2019a, Reference Bago and De Neys2020; Thompson et al., Reference Thompson, Turner and Pennycook2011). Here we tested for it by contrasting the proportion of correct responses in the incongruent Stroop trials of the one-response pretest and those of the final stage of the main two-response study. A consistency confound would result in a clear discrepancy between these accuracies. However, our results showed that the percentage of correct responses in the critical incongruent trials of the one-response pretest (M = 93.2%, SD = 18.2%), was very similar to this of the incongruent final responses of the two-response study (M = 92.5%, SD = 18.6%). A Welch Two Sample t-test indicated that this difference was not significant (t(52.32) = 0.14, p = 0.890).

2.1.4.2. Two-response Stroop task

The experiment was run online on Gorilla Experiment Builder (gorilla.sc). Participants were informed that the study would take 30 minutes to complete and that it demanded their full attention. They were told that they would be presented with words and that they needed to respond to the color that each word was presented in using their keyboard (for literal instructions, see Supplementary Material Section A). Then they were given instructions about the correct response key mapping.

To familiarize themselves with the color-key pairs, participants first practiced only with the colors (without the words). They were presented with 32 color stimuli (red, blue, green, or yellow) and they were instructed to respond as fast and as accurately as possible. They were given feedback after each response and, in case of an incorrect response, they were shown a picture of a keyboard with the correct color-key pairs. Figure 1A illustrates the time course of this practice round.

Figure 1 Time course of the practice trials and experimental trial. (A) The time course of a color-only practice trial. (B) The time course of a deadline-only two-response practice trial. (C) The time course of a load-only practice trial. (D) The time course of an experimental trial.

Then, participants were presented with a second practice round, which was identical to the first one, with the difference that now the stimuli were 12 congruent color-word pairs. Participants were told that they needed to respond to the color that each word was presented in.

After the second practice round, participants were introduced to the incongruent trials. They were informed that sometimes the ink color in which the word appears would not match with the word, and they were asked to always respond to the color of the word. This practice round was identical to the above 2, with the difference that now the stimuli were 8 incongruent color-word pairs.

At the end of this practice round, participants were introduced to the two-response paradigm. They were told that we were interested in their initial, intuitive response to the color of each word and wanted them to answer as fast as possible with the first response that popped up in mind. They were also informed that after the first response, they would have more time to reflect on the color of the word and provide their final answer. Participants were introduced to the deadline of the initial response and were shown an example of an initial trial. Then, they were presented with 12 two-response color-word trials. The time course of this practice round can be seen in Figure 1B.

Following the two-response practice round, participants were presented with the load task. They were told that they also had to memorize a set of 6 numbers while responding to the color-word pairs. Participants were informed that after the memory probe was shown, they would have to press ‘d’ if the probe was part of the memory set, or ‘k’ if the probe was not part of the memory set. At this point, they were presented with 5 load memorization practice trials. Figure 1C illustrates the time course of this practice round.

After the load practice, round participants were reminded that they had to memorize the set of numbers while responding to the color-word pairs. They were instructed to first focus on the memorization task, and then on the color-word task. They were then presented with 24 two-response practice trials (with load and deadline). Critically, the first 12 practice trials had a looser initial response deadline (1 second instead of 750 ms). This was done to familiarize participants with the two-response format. For the last 12 practice trials the actual 750 ms deadline was applied. The time course of this practice round was identical to that of the experimental trials and is illustrated in detail in Figure 1D.

After this practice session, participants started the experimental trials. The main task was composed of 128 trials which were grouped into 3 blocks. Participants were told that after each block they could take a short break. Before each new block started, they were shown a picture of a keyboard with the correct color-key pairs to remind them of the response key mapping. At the end of the experiment, participants completed standard demographic questions and were presented with a debriefing message.

3.1.3.1. Flanker stimuli

The stimuli consisted of a row of 5 arrows. This row included a central arrow flanked by 2 surrounding arrows on each side, all with arrowheads pointing either to the left or to the right. In congruent stimuli, the surrounding arrows pointed in the same direction as the central arrow (←←←←← or →→→→→). In incongruent stimuli, the surrounding arrows pointed in the opposite direction to the central arrow (←←→→←← or →→←→→).

A total of 128 experimental trials, consisting of 64 congruent and 64 incongruent trials, were presented to the participants in a randomized order. The stimuli were presented in the center of the screen on a white background. Participants were instructed to press the ‘f’ key if the central arrow pointed left and the ‘j’ key if it pointed right. Response times were measured from the onset of the stimulus until the button press. Our main results concern the critical incongruent trials unless otherwise stated.

As we noted, since the Flanker task is a binary-response task, it also allows us to sidestep a potential difficulty of the specific Stroop task response format we adopted in Study 1, namely that participants may have found it challenging to apply the 4-option color-response key mapping in the initial stage. However, in theory, the version of the Flanker task that we used may present its own limitations. For example, one may note that in the congruent trials, it is not necessary to focus attention on the central arrow, since all items are identical, but in the incongruent trials participants need to focus their attention on the central arrow to produce a correct response. This may invite an alternative strategy that people can use: they can first determine whether all items are the same and, if they are not, they can focus their attention on the central target only. Since focusing takes time this strategy could generate longer reaction times in the incongruent, compared to the congruent trials. In this sense, the Flanker task would not necessarily evoke response conflict like the Stroop. However, the evidence in the cognitive control literature with the specific version of the Flanker task (with a 1-to-1 response mapping) we adopted suggests that this alternative account is insufficient to explain the entirety of the flanker effect (e.g., Hübner et al., Reference Hübner, Steinhauser and Lehle2010) and may not even play a significant role in contributing to it (Servant and Logan, Reference Servant and Logan2019). That is because participants focus attention on the central arrow in a similar way in congruent and incongruent trials (Servant and Logan, Reference Servant and Logan2019). This supports the original interpretation of the Flanker, which emphasizes response competition as a key factor in the task (Eriksen and Eriksen, Reference Eriksen and Eriksen1974; Eriksen and Hoffman, Reference Eriksen and Hoffman1973). Nevertheless, it remains the case that the Stroop and Flanker tasks may tap different aspects of cognitive control (e.g., Friedman and Miyake, Reference Friedman and Miyake2004; Rey-Mermet et al., Reference Rey-Mermet, Gade and Oberauer2018; Section 5).

3.1.3.2. Load task

In the two-response version of the Flanker task, we used the same secondary digit memorization task as in the Stroop task of Study 1 (Lavie, Reference Lavie2005; Lavie et al., Reference Lavie, Hirst, de Fockert and Viding2004), since it has been shown to burden cognitive control in classic control tasks (Lavie et al., Reference Lavie, Hirst, de Fockert and Viding2004).

3.1.4.1. One-response (deliberative-only) pre-test

To obtain a baseline Flanker performance, we ran a pre-test where participants performed a traditional one-response arrow Flanker task, without a digit memorization load or a deadline. As in Study 1, we recruited 25 participants (48% female; mean age = 36.4 years, SD = 11.0) online on Prolific Academic (www.prolific.ac). Only native English speakers from Canada, Australia, New Zealand, the United States of America, or the United Kingdom were allowed to take part in the study. Participants were paid £0.70 for their participation. A total of 40% of the participants reported a bachelor’s degree as their highest education level, while 28% reported a Master’s degree and 28% a high school degree.

The deadline of the initial response stage in our two-response design was based on the average response time of the one-response pretest (e.g., Bago and De Neys, Reference Bago and De Neys2017, Reference Bago and De Neys2020). Thus, the one-response pretest was similar to the main study in terms of stimuli and amount of trials, but participants were instructed to provide a single response on each trial and to answer ‘as fast and as accurate as possible’. The average response time for the congruent trials was 428 ms (SD = 52.2 ms) and for the incongruent trials, it was 458 ms (SD = 47.2 ms).Footnote ⁴ Based on these values we decided to set the maximum response deadline for the initial response to 420 ms (i.e., approximately the mean of congruent trials which do not require controlled processing to answer correctly).

To confirm that participants were under time pressure in the initial stage, we compared response times for critical incongruent trials between the one-response pre-test and the initial responses in the main two-response study. We first excluded all trials with missed load memorization or missed deadlines in the initial stage of the two-response study. The results showed that participants responded much faster in the initial response stage of the main study (incongruent trials: 314.6 ms, SD = 43.7 ms), compared to that of the one-response study (incongruent trials: 457.6 ms, SD = 47.2 ms; i.e., responses were on average more than 2.5 SDs faster than in the one-response study). A Welch Two Sample t-test indicated that this difference was significant (t(3222.88) = 55.80, p < .001).

The one-response pre-test also allowed us to check for a potential consistency confound in our main two-response study, which could potentially underestimate the correction rate from initial to final responses. To test for this confound, we compared the accuracy of incongruent trials between the final two-response stage of our main study (M = 92.7%, SD = 20.6%) and the pretest (M = 97.5%, SD = 2.5%). Although a Welch Two Sample t-test revealed a significant difference (t(2792.13) = 5.77, p < .001), this difference was small. Even if we factor in a possible 5% extra correction trials (i.e., ‘01’ trials) in our results, the non-correction rate conclusions remain unaffected (i.e., 65.5% with the extra correction trials vs. 69% without). Therefore, a potential consistency confound cannot explain the low correction rates.

3.1.4.2. Two-response Flanker task

The experiment was run online on Gorilla Experiment Builder (gorilla.sc). Participants were informed that the study would take 20 minutes and that it required their full attention. They were told that they would be presented with an arrow at the center of the screen and that they had to press the button that matched the arrow’s direction. Specific instructions about the key mapping were provided. Participants were then told that the central arrow would always appear along with 4 other arrows and that their task was to identify the direction of the central arrow (for literal instructions, see Supplementary Material Section A).

To familiarize themselves with the key mappings, participants first practiced with 6 trials (3 congruent and 3 incongruent). They were given feedback after each response and in case of an incorrect answer they were reminded of the correct key pairs.

At the end of this practice round, participants were introduced to the two-response paradigm. They were told that we were first interested in their initial, intuitive response to the direction of the central arrow and wanted them to answer as fast as possible with the first response that came to mind. They were told that after this first response, they would have more time to reflect before providing their final answer. Participants were introduced to the deadline of the initial response and were shown an example of an initial trial. Then, they were presented with 6 two-response trials.

Following the two-response practice round, participants were presented with the load task, with the same instructions as in Study 1. They were then presented with 5 load memorization practice trials.

After the load practice round, participants were reminded that they had to memorize the numbers while responding to the direction of the central arrow. They were instructed to first focus on the memorization task, and then on the arrow task. They were then presented with 12 two-response practice trials (with load and deadline). Critically, the first 6 practice trials had a looser initial response deadline (670 ms instead of 420 ms). This was done to familiarize participants with the two-response format. For the last 6 practice trials the actual 420 ms deadline was applied.

After this practice session, participants started the experimental trials. The main task was composed of 128 trials which were grouped into 3 blocks. Participants were told that after each block they could take a short break. Before each new block started, they were reminded of the response key mapping. At the end of the experiment, they completed standard demographic questions and were presented with a debriefing message.

4.1.3.1. Counterbalancing

Each of the 3 types of reasoning problems was composed of 8 incongruent and 8 congruent items. For every type of problem, we created 2 sets of items. In each set, the congruency status of the items was counterbalanced. More specifically, all the incongruent items of the first set appeared in their congruent version in the second set, and all the congruent items in the first set appeared in their incongruent version in the second set. Half of the participants were presented with the first set while the other half were presented with the second set. This way, the same item content was never presented more than once to a participant and, at the same time, everyone was exposed to the same items, which minimized the possibility that mere item differences influence the results (e.g., Bago and De Neys, Reference Bago and De Neys2017). The presentation order of the items within each task was randomized. Each participant was randomly allocated to one of 6 potential task orders. More specifically, each participant was first randomly allocated to task 1/3 (i.e., either bat-and-ball, base-rates, or syllogisms), and then they were randomly allocated to one of the 2 potential task order combinations for the second and third task (e.g., if a given participant had the bat-and-ball as their first task, they could continue with base-rates as their second task and syllogisms as their final task, or the inverse).

4.1.3.2. Bat-and-ball problems (BB)

Each participant was presented with 8 multiple-choice bat-and-ball items (4 incongruent and 4 congruent) taken from Bago and De Neys (Reference Bago and De Neys2019a). The prices and the names of the objects varied between items, but all the items shared the same structure with the classic bat-and-ball problem. Participants were always presented with 4 response options: the logical option (‘5 cents’ in the original bat-and-ball), which is considered correct, the heuristic option (‘10 cents’ in the original bat-and-ball), and 2 foil options. The 2 foil options were always the sum of the correct and heuristic answer (e.g., ‘15 cents’ in original bat-and-ball units) and their second greatest common divisor (e.g., ‘1 cent’ in the original). An example of the problems is presented below:

• ○ 5 cents

• ○ 1 cent

• ○ 10 cents

• ○ 15 cents

The congruent versions were constructed by removing the ‘more than’ statement from the incongruent versions (‘A pencil and an eraser cost $1.10 in total. The pencil costs $1. How much does the eraser cost?’). Each problem was presented serially. First, the first sentence, which always stated the 2 objects and their total cost (e.g., A pencil and an eraser cost $1.10 in total.) was presented for 2000 ms. Afterward, the second sentence along with the question and the answer options was added under the first sentence (which remained on screen). The problem remained on the screen until a response was given or until the deadline. As in Bago and De Neys (Reference Bago and De Neys2019a), the deadline for the initial response was 5000 ms.Footnote ⁵

4.1.3.3. Base-rate problems (BR)

Each participant was presented with 8 base-rate items (4 incongruent and 4 congruent) taken from Bago and De Neys (Reference Bago and De Neys2017). Each item consisted of a sentence describing the composition of a sample (e.g., ‘This study contains scientists and assistants’.), a sentence with a stereotypical description of a random person from the sample (e.g., ‘Person “C” is intelligent’.), and a sentence with the base-rate information (e.g., ‘There are 4 scientists and 996 assistants’.). Participants had to indicate to which group the random person most likely belonged to. The answer option that was considered correct was always the one that corresponded to the largest group in the sample. The presentation of all items was based on Pennycook et al.’s (Reference Pennycook, Cheyne, Barr, Koehler and Fugelsang2014) rapid-response paradigm. Each sentence was presented serially and the amount of text presented on the screen was minimized. An example of the problems is presented below:

• ○ A scientist

• ○ An assistant

The congruent versions were constructed by reversing the base rates of the incongruent versions. For example in its congruent version, the second sentence of the above problem would read ‘There are 996 scientists and 4 assistants’. Each problem was presented in 3 stages. First, the first sentence was presented for 2000 ms. Then, the second sentence was added under the first sentence (which remained on screen) for another 2000 ms. Finally, the critical base-rate information along with the question and the answer options were added until a response or until the deadline. As in Bago and De Neys (Reference Bago and De Neys2017), the deadline for the initial response was 3000 ms.

4.1.3.4. Syllogistic reasoning problems (SYL)

Each participant was presented with 8 syllogistic reasoning items (4 incongruent and 4 congruent), taken from Bago and De Neys (Reference Bago and De Neys2017). Each item consisted of a major premise (e.g., ‘All things made of wood can be used as fuel’.), a minor premise (e.g., ‘Trees can be used as fuel’.) and a conclusion (e.g., ‘Trees are made of wood’.). Participants were told to always consider the premises as true and were asked to say if the conclusion followed logically from the premises or not. A conclusion was considered logical only when it was valid. An example of the problems is presented below:

• ○ Yes

• ○ No

In the incongruent items, the believability and the validity of the conclusion conflicted. More specifically, the conclusion of the incongruent items was either valid-unbelievable or invalid-believable. For instance, in the above example of an incongruent problem the syllogism is believable, but invalid. For the congruent items, the validity of their conclusion was in accordance with their believability. Meaning that the conclusion was either valid-believable or invalid-unbelievable. For example, in its congruent version, with a valid-believable conclusion, the above problem would read: ‘All things made of wood can be used as fuel. Trees are made of wood. Trees can be used as fuel’. Each problem was presented in 3 stages. First, the first sentence of the problem was presented for 2000 ms. Then, the second sentence was added under the first sentence (which remained on screen) for 2000 ms. Finally, the conclusion along with the question and the answer options were added until a response was given or until the deadline. As in Bago and De Neys (Reference Bago and De Neys2017), the deadline for the initial response was 3000 ms.

4.1.3.5. Load task

For the Stroop task, we used the same digit memorization task (Lavie, Reference Lavie2005; Lavie et al., Reference Lavie, Hirst, de Fockert and Viding2004) as in Study 1. For the Reasoning task, the load memorization task that was used was a complex visual pattern (i.e., 4 crosses in a 3 × 3 grid, Bago and De Neys, Reference Bago and De Neys2017, Reference Bago and De Neys2019a; Raoelison and De Neys, Reference Raoelison and De Neys2019), which was briefly presented before each reasoning problem (Miyake et al., Reference Miyake, Friedman, Rettinger, Shah and Hegarty2001). After providing an initial response to the reasoning problem, participants were presented with 4 different load patterns (i.e., with different cross placings) and had to identify the one that they had been asked to memorize. Miyake et al. (Reference Miyake, Friedman, Rettinger, Shah and Hegarty2001) showed that this task burdens cognitive resources, and previous studies have shown that it hampers sound deliberating and decreases reasoning accuracy on the specific types of reasoning problems we adopted (e.g., De Neys, Reference De Neys2006; Franssens and De Neys, Reference Franssens and De Neys2009; Johnson et al., Reference Johnson, Tubau and De Neys2016).

4.1.3.6. Composite reasoning measure

For simplicity and to maximize power, our analyses focused on the composite incongruent accuracy across the 3 different reasoning problem types (i.e., bat-and-ball, base rates, syllogisms). To calculate the composite performance, we averaged for each participant the proportion of correct initial and final responses, separately for each problem type. Then we averaged across all problem types (separately for initial and final trials). For completeness, we calculated the composite performance also for congruent trials.

For the main correlational analysis between the Stroop and the Reasoning task, we first calculated the z-scores separately for each participant, each problem type, each response stage (i.e., initial, final), and each direction of change category (see further). Then, we averaged the z-scores across the 3 problem types, separately for each response stage and each direction of change category.

It is important to clarify that because of practical limitations, we did not have a composite cognitive control measure. Thus, we tested whether the composite reasoning measure correlated with performance at the Stroop task only.

4.1.5.1. Stroop task

Participants did not respond within the deadline on 18.1% of congruent initial trials (1690 out of 9344) and 29.2% of incongruent initial trials (2728 out of 9344). In addition, participants failed the load recall on 15.2% of congruent initial trials (1416 out of 9344) and 10.5% of incongruent initial trials (979 out of 9344). By rejecting the trials with a missed deadline and an incorrect load recall, we kept 63.5% of all trials (11875 out of 18688). On average, each participant contributed 81.3 trials (out of 128 trials, SD = 31.5).

4.1.5.2. Reasoning task

The trials in which participants failed the load and/or the deadline were excluded from subsequent analyses. Participants failed to answer before the deadline on 5.4% of incongruent initial trials (103 out of 1908) and 2.7% of congruent initial trials (52 out of 1908). In addition, participants failed the load recall on 12.5% of incongruent initial trials (239 out of 1908) and 14.7% of congruent initial trials (281 out of 1908). By rejecting the trials with a missed deadline and an incorrect load recall, we kept 82.3% of all trials (3141 out of 3816). On average, each participant contributed 19.8 trials (out of 24 trials, SD = 3.1).

Since the bat-and-ball problem has become very popular, some participants may have been previously exposed to the correct ‘5 cents’ answer. If this is the case, they would not need to override an initially incorrect, heuristic response in order to arrive at the correct answer when solving the problem, which could distort our results. Following Raoelison et al. (Reference Raoelison, Thompson and De Neys2020), we, therefore, asked participants whether they had seen/solved the bat-and-ball problem before or if they had read about it (Section 4.1.4). We also asked them to provide an answer to the problem (‘What do you think the correct response is? Please enter it below’.). The bat-and-ball trials were excluded for all participants that reported having seen the original bat-and-ball problem and that were able to provide the correct ‘5 cents’ response.Footnote ⁷ Their trials for the other tasks were included in the analysis. In total, we excluded from the analysis an additional 440 bat-and-ball trials (i.e., 5.8% of all trials) from 32 participants. Note that, 56 of the bat-and-ball trials of these participants were already excluded because of missed deadline or load.

4.2.2.1. Accuracy

Figure 4 gives an overview of the initial and final Reasoning task accuracies. Although we focus our analysis on the composite reasoning performance, individual task trends are reported in the graphs for completeness. The overall pattern is very similar to what was observed in previous two-response studies. First, people perform well on congruent trials both at the initial (M = 90.0%, SD = 7.2%) and the final stage (M = 92.6%, SD = 7.1%), while incongruent trials typically have low initial (M = 35.2%, SD = 20.5%) and final (M = 40.6%, SD = 22.6%) accuracies. This indicates that even after deliberation, the majority of reasoners remain biased (Bago and De Neys, Reference Bago and De Neys2017, Reference Bago and De Neys2019a; Raoelison et al., Reference Raoelison, Thompson and De Neys2020; Raoelison and De Neys, Reference Raoelison and De Neys2019). As it can be seen in Figure 4, these composite level trends were also observed for each individual task separately.

Figure 4 Response accuracy at incongruent and congruent trials of the Reasoning task in Study 3 for initial and final responses, separately for each problem type and for the mean across the 3 problem types. The error bars represent the Standard Error of the Mean. BB, bat-and-ball; BR, base-rates; SYL, syllogisms; Mean, the mean across the 4 problem types.

In addition, note that consistent with previous findings, reasoners’ accuracy at the incongruent trials is typically below or near 50%, (and close to guessing accuracy). However, the high accuracy on the congruent trials confirms that participants are not merely guessing throughout the study. Instead, they are simply lured by the heuristic cue when solving the incongruent items.

To examine whether there was an effect of the response stage (initial; final) and congruency status (incongruent; congruent) on response accuracy, a two-way within-subjects ANOVA was conducted. As Figure 4 shows, the accuracy at the congruent trials was higher than that at the incongruent trials (F(1,158) = 402.54, p < .001, η ² g = 0.518), and the accuracy at the final stage was higher than that at the initial stage (F(1,158) = 29.91, p < .001, η ² g = 0.008), showing that accuracy improved after deliberation. Finally, this difference between initial and final accuracy was higher for incongruent compared to congruent trials, as indicated by the response stage by congruency interaction (F(1,158) = 4.08, p < .05, η ² g = 0.001).

4.2.2.2. Stability index

Like in the Stroop task, we calculated a stability index for the initial responses of the critical, incongruent trials. For each participant, we calculated on how many out of their initial responses in the incongruent trials they showed the same accuracy (i.e., ‘0’ or ‘1’). The average stability index was 95.5% (SD = 11.1%) in the bat-and-ball task, 93.0% (SD = 14.6%) in the base-rate task, and 81.3% (SD = 19.6%) in the syllogistic reasoning task. If initial responses were susceptible to systematic random guessing, we would observe more inconsistency in response patterns.

4.2.2.3. Direction of change

To get a more precise picture of how participants changed their responses after deliberation we also conducted a direction of change analysis (Bago and De Neys, Reference Bago and De Neys2017, Reference Bago and De Neys2019a). As Figure 5A shows, at the composite level, the majority of the critical, incongruent trials had a ‘00’ pattern (52.2%) which confirms that reasoners are easily lured by the heuristic response when solving reasoning items. Critically, in the incongruent trials, the proportion of ‘11’ responses (35.2%) is higher than that of the ‘01’ responses (9.2%). The mean composite non-correction rate (i.e., proportion 11/11 + 01) reached 79.3%. Hence, as in the Stroop task, although there is some accuracy increase after deliberation, correct responses are, for the most part, already generated intuitively.

Figure 5 Direction of change in the Reasoning task of Study 3 separately for incongruent and congruent trials. (A) The proportion of each direction of change category at the composite level. (B) The proportion of each direction of change category at the Bat-and-Ball trials. (C) The proportion of each direction of change category at the Base-Rates trials. (D) The proportion of each direction of change category at the Syllogistic reasoning trials. The error bars represent the Standard Error of the Mean. 00, incorrect initial and incorrect final response; 01, incorrect initial and correct final response; 10, correct initial and incorrect final response; 11, correct final and correct initial response.

4.2.3.1. Accuracy

As a first step, we looked into whether the individual accuracies of participants in the Stroop task and the Reasoning task were related. As Table 1 shows, although there was a slight trend toward a positive association between the final Stroop performance and the initial and final Reasoning performance, all correlations were weak and typically did not reach significance.

Table 1 Pearson’s product–moment correlation between the average accuracy of each individual on the Stroop task, and the accuracy of that individual on the Reasoning task

Note: Correlations are reported both at the composite level and for each type of reasoning problem, separately for each Response stage (initial response; final response). Significant correlations (p < .05) are in bold.

BB, bat-and-ball; BR, base-rates; SYL, Syllogisms.

4.2.3.2. Direction of change

In order to obtain a more detailed picture of the relationship between the 2 tasks, we focused on the direction of change patterns (i.e., ‘00’, ‘01’, ‘10’, ‘11’). This allowed us to examine whether the tendency to change one’s response after deliberation (or not) was related in the 2 tasks. More specifically, for each direction of change category, we examined whether the proportion of trials of each category in the Stroop task was correlated with the proportion of trials of this same category in the Reasoning task. Table 2 shows the main results, but a full cross-tabulation table can also be found in Supplementary Material Section E.

Table 2 Pearson’s product–moment correlation between the proportion of each direction of change (i.e., ‘00’, ‘01’, ‘10’, ‘00’) of each individual in the Stroop task, and the proportion of each direction of change of that individual in the Reasoning task

Note: Correlations are reported both at the composite level and separately for each type of reasoning problem. 00, incorrect initial and incorrect final response; 01, incorrect initial and correct final response; 10, correct initial and incorrect final response; 11, correct final and correct initial response. Significant correlations (p < .05) are in bold.

BB, bat-and-ball; BR, base-rates; SYL, syllogisms.

As Table 2 shows, at the composite level, there was overall evidence for a weak positive association between the direction of change patterns of each task. The more a participant showed a specific change pattern in the Stroop task, the more they tended to show this pattern in the Reasoning task. At the composite level, the correlation reached significance for the ‘00’ and ‘01’ pattern. Hence, the more a reasoner tended to provide entirely incorrect responses in the Stroop task (i.e., both their initial and final responses were incorrect), the more they tended to do so in the Reasoning task. Likewise, the more a reasoner tended to correct an initial incorrect response after deliberation in the Stoop task, the more they tended to show this change pattern in the Reasoning task. For the ‘11’ and ‘10’ patterns the composite correlations did not reach significance. At the individual task level, the trends were more diffuse (Table 2).

To test whether the tendency to generate a correct final response through deliberation (i.e., a ‘01’ pattern) showed a stronger link between the 2 tasks than the tendency to generate a correct response through intuitive processing (i.e., a ‘11’ pattern) we also contrasted the composite ‘01’ (r = .18) and ‘11’ (r = .12) correlations directly. The difference between these correlations did not reach significance, p = 0.61.

In sum, the correlational analyses indicated that there is evidence for a weak association between Stroop and Reasoning performance. However, there was no clear indication that initial Stroop performance would be a better predictor than the final Stroop performance or vice versa.