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A Systematic Application of Dual-Process Theory To Mathematics Education

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1 Leave a comment on paragraph 1 1 Abstract

2 Leave a comment on paragraph 2 2 Educational researchers have only recently and even then to a minimal extent begun to borrow analytical frameworks from cognitive psychology to address systematic cognitive biases that hamper student learning across a variety of subjects and age groups. This review seeks to bridge this troubling gap between educational research and cognitive psychology by analysing two empirical studies through the framework of dual-process analysis. The selected studies depict widespread and systematic cognitive biases, which dual-process theory can explain and potentially remedy. The first study, which is taken from Dooren et al. (2003), reveals how the probabilistic reasoning of 10th and 12th grade students is shaped by fallacious default responses generated by students’ Type 1 processing. By means of a second experimental study borrowed from Lehman and Nisbett (1990), this review evaluates the opposite channel of the relationship between reasoning and learning: the beneficial effect statistics education has on university students’ domain-general statistical reasoning. This observation is interpreted in terms of changes in learners’ Type 1 and Type 2 processing.      As a troubling consequence of scientific literature on cognitive science and mathematics education so far constituting separate bodies and scholarly communities, there remains a lack of empirical studies that build on cognitive psychology while investigating issues that are pertinent to mathematics education. By presenting the results of a dual-process analysis of two contrasting instances of mathematical learning, this review specifies and motivates promising future avenues for a fruitful collaboration between cognitive scientists and educational researchers. This essay concludes by identifying the design-experimental methodology as a viable way through which dual-process theory could increase the effectiveness of classroom interventions. In turn, theory-driven classroom interventions promise to instantiate and refine dual-process theory.

3 Leave a comment on paragraph 3 0 Keywords: cognitive processing, mathematics education research, Type 1 and Type 2 processing, mathematical reasoning, dual-process theory

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5 Leave a comment on paragraph 5 0 Introduction

6 Leave a comment on paragraph 6 0 Across the wide landscape of mathematics instruction, educators are often perplexed and even disheartened by students who despite having the requisite disciplinary knowledge, repeatedly fail to apply formal reasoning. Instead of drawing on their knowledge base, students often routinely rely on intuitive problem-solving strategies, which lead to erroneous or formally inadequate approaches. In light of the critical extent to which such intuitive problem-solving seems to systematically interfere with effective learning and instruction, there is an increasing appreciation for the educational significance of remedying such systematic biases in learners’ reasoning (Attridge and Inglis, 2014; Babai et al., 2015; Dooren et al., 2003; Leron and Hazzan, 2006).

7 Leave a comment on paragraph 7 0 To investigate the cognitive roots underlying this educational challenge, dual-process theorists attempt to explain how people’s learning is shaped and sometimes even predetermined by transitory prevalence of a single of the hypothesised two distinct processing types (Stanovich, 2011). Whereas Type 1 processing is typically coined as heuristic or intuitive and is said to engender automatic first-impression cognitive processes, Type 2 processing is described as analytic requiring cognitive effort that loads heavily on a learner’s working memory. Given its limited scope, this review will exclusively focus on experimental evidence leaving the evaluation of significant theoretical (Dubinsky, 2002; Lieberman, 2009; Tzur and Simon, 2004) and neuropsychological (Goel, 2008; Tsuji and Watanabe, 2009) contributions to other reviewers.

8 Leave a comment on paragraph 8 1 Since the empirical evidence of dual processes is primarily restricted to cognitive science research, dual-process theory remains to lack evidence of its applicability to concrete educational contexts (Gigerenzer, 2010; Keren and Schul, 2009). By conducting systematic dual-process analyses of experimental data drawn from two complementary mathematics education studies, this review directly addresses this major shortcoming of dual-process theory motivating future investigation along this worthy avenue. The ultimate goal of this research initiative is to map pathways for integrating the currently separate projects conducted by dual-process theorists and mathematics education researchers (Dooren et al., 2003; Kryjevskaia et al., 2014; Leron & Hazzan, 2009).

9 Leave a comment on paragraph 9 0 In the introductory part of this literature review, I will define the concepts that are integral to evaluating the symbiotic relationship between reasoning and mathematical learning. Key concepts that feature in this definitional section are Type 1 and Type 2 processing, mathematical problem-solving, and knowledge acquisition.

10 Leave a comment on paragraph 10 0 The subsequent section introduces the main body of this review and includes a summary of the state of the art of dual-process accounts. The dual-process theories elucidated in this part will serve as an interpretative lens through which I will proceed to evaluate two empirical studies borrowed from the mathematics education literature.

11 Leave a comment on paragraph 11 0 The third section will illuminate two particularly urgent areas of interaction between dual-process theory and mathematics education, namely their conflicting perspectives on erroneous problem-solving and how the two types of cognitive processes may inform the study of conceptual and procedural knowledge.

12 Leave a comment on paragraph 12 0 In the fourth part of this review, I will proceed to interpreting two experimental studies of mathematical reasoning through an application of dual-process theory.                   In the first study, Dooren et al. (2003) present experimental evidence for how the so-called illusion of proportionality biases secondary school students’ probabilistic reasoning. This empirical analysis enables me to qualify the learning implications of the two processing types depending on the learning setting in which mathematical problem-solving takes place.                                                                                                                                    A second empirical case included in this review is the longitudinal study taken from Lehman and Nisbett (1990). The authors establish a connection between university students’ improvements in domain-general statistical reasoning and the statistics education that those students received throughout their four years of undergraduate education. The evidence presented in Lehman and Nisbett is especially suitable for illuminating the second, equally pertinent, channel of the relationship between learners’ reasoning and knowledge acquisition: the learning benefits that domain-specific statistical learning may have for students’ domain-general cognitive processing.

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14 Leave a comment on paragraph 14 0 1. Key Terminology

15 Leave a comment on paragraph 15 0 1.1 Two Separable Types of Cognitive Processes

16 Leave a comment on paragraph 16 1 Table T1, which is adapted from “Table 1” in Evans and Stanovich (2013, p. 225) and “Table I.I” in Stanovich (2011, p. 18), juxtaposes the two types of cognitive processes in terms of their labels, attributes, functional features, and correlates.

17 Leave a comment on paragraph 17 0 Table T1.  Features, Correlates, and Attributes of the Two Cognitive Processing Types

Type 1 processes (intuitive) Type 2 processes (analytic)
Defining features
Autonomous processing Cognitive decoupling
Independent of working memory Limited by working memory capacity
Associated with the limbic system Associated with the prefrontal cortex
Parallel operation possible Only serial operation possible
Weightier among novice learners Weightier among expert learners
Functional attributes
Fast Slow
Autonomous Algorithmic
Automatic Conscious
Contextualised Abstract/decontextualised
Implicit/tacit Explicit
Intuitive Rational
Reflexive Reflective
Informal Formal
Associative Rule-based
Stimulus-bound Higher order
Cognitively effortless Cognitively effortful
Correlates
Biased/modal responses Normative/formal responses
Independent of cognitive ability Correlated with cognitive ability
Alternative Terminology
System 1 System 2
Heuristic processes Analytic processes
Evolutionary
Similar to animal cognition Distinctively human

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19 Leave a comment on paragraph 19 0 In light of the immense variety of labels associated with the two types of cognitive processes, I will pay special attention to justifying my choice of terminology. With the previously prevalent distinction between two types of cognitive systems (Stanovich, 1999) considered inadequate, there has been a recent trend to substitute system 1/ system 2(Kahneman, 2013) with Type 1 and Type 2 processing (Evans and Stanovich, 2013). I accorded with this definitional trend recognising that the labels system 1 and system 2 may wrongly imply that each of a person’s cognitive processes originate from a singular system 1 or system 2. By using terms as restrictive as system 1 and system 2, one excludes the possibility of a given cognitive process resulting from multiple cognitive systems and neural underpinnings (Evans and Stanovich, 2013). This restriction is especially problematic in the context of system 1 as Stanovich (2009) demonstrated in his analysis of the autonomous set of systems (TASS). Through using the labels Type 1 and Type 2 one can effectively distinguish between two types of cognitive processing without making a claim about the number of cognitive or neural systems underlying those types of processing.

20 Leave a comment on paragraph 20 0 1.2 Problem-Solving in the Context of Mathematics

21 Leave a comment on paragraph 21 0 When using the term mathematical problem-solving, I refer to a “situation that proposes a mathematical question whose solution is not immediately accessible to the solver” (Callejo, 2009, p. 112). According to this definition, problem-solving is tied to Type 2 rather than Type 1 processing. This has to do with the assumption that Type 1 processing generates responses that are automatic and immediate – the opposite of what is thought to constitute problem-solving according to the above definition.

22 Leave a comment on paragraph 22 0 1.3 Knowledge Acquisition in Terms of Mathematical Learning

23 Leave a comment on paragraph 23 1 In this review, I will typically use the general term learning instead of narrower alternatives such as response acquisition, knowledge acquisition or knowledge construction (Mayer, 1992). As such, no claim is made about the relative merits or weaknesses of the competing attempts to conceptualise the way knowledge becomes manifest in a learner’s mind. Given this paper’s limited scope, I will primarily deal with the subset of literature that illuminates the connection between cognition and learning in the mathematical domain. Occasionally, I will present cases in which learning implications for other STEM domains are discussed.

24 Leave a comment on paragraph 24 0 2. Consensus and Disagreement among Dual-Process Theorists

25 Leave a comment on paragraph 25 0 2.1 A Bird’s-Eye View of Dual-Process Theory

26 Leave a comment on paragraph 26 0 Table T2 summarises the scientific synergy accomplished by experimental and neuroscientific approaches to dual-process theory. The depicted variety of scientific subfields for which separable types of cognitive processes were proposed gives weight to my hypothesis of the existence of qualitatively distinct types of cognitive processes.

27 Leave a comment on paragraph 27 1 Table T2. Methodological Approaches to Dual-Process Theory

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Methodology Key Publications Key Findings
Experimental Attridge & Inglis, 2014; De Neys, 2006 (a & b);   De Neys, W., Schaeken, W., & d’Ydewalle, 2005; Evans, 1996; Evans & Curtis-Holmes, 2005; Evans et al., 2010; Kahneman, 2011; Kahneman & Tversky, 2000; Roberts & Newton, 2001;                      Stanovich, 2011; Stevenson & Over, 1995; Van Hoof et al., 2013 ·         Administering a challenging task prior to a cognitive reflection test (CRT) makes it more likely that participants will inhibit Type 1 processing·         Belief bias increases, while logical accuracy decreases under (a) time constraints and (b) working memory load (inhibiting Type 2 processes)

29 Leave a comment on paragraph 29 0 ·         Conjunction fallacy more common among those who give quick responses (linked with default Type 1 processes)

30 Leave a comment on paragraph 30 0 ·         People’s ability to engage the reflective mind determines whether Type 2 processes will override Type 1 processes

31 Leave a comment on paragraph 31 0 ·         Type 2 processing positively correlated with cognitive ability and formally correct responses

Neuroscientific Goel, 2008; Greene, Nystrom, Engell, Darley, & Cohen, 2004); Lieberman, 2007;        Tsuji and Watanabe, 2009;  ·         Belief-based responses were systematically linked with different brain areas compared to reason-based responses·         When belief-based reasoning was inhibited, right prefrontal cortex areas were activated

32 Leave a comment on paragraph 32 0 ·         Prefrontal and frontal cortical areas were activated when participants made monetary decisions on the basis of deferred rather than immediate reward

33 Leave a comment on paragraph 33 0 ·         By contrast, when immediate reward was chosen, this was associated with the limbic system

34 Leave a comment on paragraph 34 0 ·         Greater activity of prefrontal cortex and parietal lobes when deontological reasoning was overridden by consequentialist reasoning

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35 Leave a comment on paragraph 35 0 2.2 Cognitive Architecture: Parallel-Competitive versus Default-Interventionist Structure

36 Leave a comment on paragraph 36 0 Apart from knowing the distinctive roles and features of Type 1 and Type 2 processing, an important project pursued by dual-process theorists is to map the ways in which these two types interact in a given brain. There are currently two major mappings suggested by dual-process researchers: the parallel-competitive and the default-interventionist structure (Evans and Stanovich, 2013).

37 Leave a comment on paragraph 37 0 The parallel-competitive model proposed by Sloman (1996) suggests that Type 1 and 2 processing operate independently providing their individual solutions to problems. Despite the word competitive being part of its label, the parallel-competitive structure presupposes a cooperation between Type 1 and 2 processing, which is captured by the analogy of “two experts who are working cooperatively to compute sensible answers” (Sloman, 1996, p. 6). Thus, although Type 1 and 2 processing are assumed to proceed autonomously, an agent’s eventual response may result from work performed by both types of processing (Leron and Hazzan, 2006). The simultaneous operation of Type 1 and Type 2 processing characteristic of the parallel-competitive model makes it especially challenging to pinpoint the type of processing that generated a response or solution in a given educational instance.

38 Leave a comment on paragraph 38 0 By contrast, according to the default-interventionist model originally coined by Evans (2007) rapid and automatic Type 1 processing provides a default response to a given task or problem, while Type 2 processing has as a monitory function and may promote an alternative response if the default response generated by Type 1 processing is deemed inadequate. According to Evans (2007), this creates three possible processing outcomes:

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  2. The default response R generated by Type 1 processing is chosen without the intervention of Type 2 processing,
  3. The default response R generated by Type 1 processing is chosen despite the intervention of Type 2 processing,
  4. The alternative response A is chosen after an intervention of Type 2 processing.

40 Leave a comment on paragraph 40 0 In contrast to the parallel-competitive model, the default-interventionist structure allows one to pinpoint the processing type that determined a person’s response in all three of the above cases. In the first outcome, the agent would lack awareness of the process that guided her response, which suggests that Type 1 processing was at work. In the second outcome, the agent will remember both the intervention of Type 2 processing and her decision to favour a response, which wasn’t consciously generated. In the third case, the agent will explain her response in terms of the intervention of Type 2 processing whose response was favoured by the agent.

41 Leave a comment on paragraph 41 0 2.3 An Extension of Conventional Dual-Process Theory: Stanovich’s Tri-Process Model

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43 Leave a comment on paragraph 43 0 As illustrated in Figure 1, Stanovich’s tri-process model of the mind (2009; 2011) consists of the autonomous mind (Type 1 processing), the algorithmic mind (Type 2 processing), and the reflective mind. The latter construct cannot be attributed to either of the two processing types.

44 Leave a comment on paragraph 44 0 Figure 1. Stanovich’s Tri-Process Model of the Mind

45 Leave a comment on paragraph 45 0  vol2_dpt_figure_1

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47 Leave a comment on paragraph 47 0 At the heart of Stanovich’s model is the concept of “cognitive decoupling” (2011, p. 48), which describes a person’s ability to simulate secondary representations that are abstractions of the person’s primary representations of the surrounding world. Cognitive decoupling enables hypothetical thinking and is indispensable for departing from the automatic Type 1 responses generated by the autonomous mind. For a person to perform cognitive decoupling, an intricate interplay between the algorithmic and reflective minds has to take place: First, the reflective mind signals the need to engage in cognitive simulation to the algorithmic mind, which may inhibit and override Type 1 processing. In turn, the algorithmic mind is responsible for sustaining the effortful cognitive decoupling. Provided a successful decoupling operation, the agent will perform the Type 2 response generated by the algorithmic mind or the alternative response generated by the reflective mind. Figure 1’s bidirectional arrows connecting the autonomous, algorithmic, and reflective minds illustrate that the three minds can both send and receive information from each other.

48 Leave a comment on paragraph 48 0 The reflective mind is argued to overlap with the category of Type 2 processing, while being functionally different from what is typically associated with Type 2 processing: whereas the algorithmic mind has been empirically linked to fluid intelligence and executive functioning (Stanovich, 2011; Tsuji and Watanabe, 2009), conventional dual-process theory failed to account for individual differences in critical thinking skills prior to Stanovich’s introduction of the reflective mind. According to Stanovich and West (1997), the reflective mind encompasses a person’s rational thinking dispositions, which is a latent construct that they inferred from a total of 11 variables with notable examples such as participants’ openness to ideas, their counterfactual thinking or their degree of dogmatism. Critical thinking skills or thinking dispositions were underscored to be both separable of cognitive ability and predicting considerable variation in participants’ argument evaluation performance (Stanovich and West, 1997).

49 Leave a comment on paragraph 49 0 One significant example of how the algorithmic mind can harm learning in the absence of reflective thought is one-sided thinking. One-sided thinking describes situations in which people fail to consider alternative approaches or information that might be crucial for revising the response generated by their Type 2 processing or algorithmic mind to reference Stanovich’s terminology (2009). Thus, Stanovich promotes a concept of rationality that is more encompassing than the conventional account of Type 2 processing: people’s thinking dispositions constitute a second integral component and driver of Type 2 processing in addition to cognitive ability. Stanovich depicts the mutual dependence between the algorithmic and reflective mind by visualising the algorithmic mind as the mechanical foundation of rationality, which is a necessary, but insufficient condition for rationality: rational thought and action remain contingent on the agent’s thinking dispositions, which are intrinsic to her reflective mind (Stanovich, 2009).

50 Leave a comment on paragraph 50 0 The substantial effect of thinking dispositions on task performance is supported by Toplak’s and Stanovich’s (2002) results from regression analyses of data on six problem-solving and decision-making tasks: the two thinking dispositions variables predicted twice of the unique variance (11.8%) of participants’ task performance relative to the cognitive ability measure (5.2%). Meanwhile, the value of thinking dispositions as a variable of special interest to educational researchers hinges on learners’ thinking dispositions being malleable, which is the case according to Baron’s investigation (2005).

51 Leave a comment on paragraph 51 0 3. Interaction between Dual-Process Theory and Mathematics Education Research

52 Leave a comment on paragraph 52 0 Having outlined the cornerstones of recent advances in dual-process theory, I will turn to exposing notable areas of overlap and tension between views held by dual-process theorists and mathematics education researchers. As such, the present section will indicate avenues through which dual-process theory may productively inform mathematics education.

53 Leave a comment on paragraph 53 0 3.1 Two Conflicting Perspectives on Erroneous Problem-Solving

54 Leave a comment on paragraph 54 0 According to the first perspective associated with mathematics teachers and education researchers, errors in students’ problem-solving are bugs that can be explained by one or a combination of the following learning circumstances:

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  2. Students lack the requisite conceptual or procedural knowledge for formal reasoning and problem-solving (Leron & Hazzan, 2009),
  3. Students lack the requisite cognitive ability for formal reasoning (Kryjevskaia et al., 2014).

56 Leave a comment on paragraph 56 0 Whereas the first explanation allows for the possibility that students will eventually acquire the disciplinary knowledge that is necessary for formal reasoning, the second explanation entails that some students may be generally incapable of processing formal reasoning. A seminal example of the first explanation is the Van Hiele model of geometric thought (Crowley, 1987), which comprises five hierarchical levels of understanding. This model implies that through progressing to more advanced levels of geometric understanding, learners’ initially superficial and informal reasoning will tend to become more formal.

57 Leave a comment on paragraph 57 1 For example, a novice to geometry tends to describe geometric shapes such as triangles or rectangles in terms of their overall shape rather than their formal characteristics like the number of sides or angles. At the basic levels of geometric understanding described by Van Hiele’s visualisation or analysis level (Crowley, 1987), learners are yet unable to apply formal reasoning. Once learners achieve more sophisticated levels of understanding such as deduction or rigour (Crowley, 1987), learners can be expected to consistently apply formal rather than intuitive reasoning. Assuming that students possess both the disciplinary knowledge and the requisite cognitive hardware, which are collectively considered sufficient conditions for formal reasoning, this perspective cannot account for students’ inconsistent use of formal reasoning.

58 Leave a comment on paragraph 58 0 Dual-process theory, which is largely ignored by mathematics educators and education researchers (Kryjevskaia et al., 2014), meaningfully fills the above explanatory gap. This account suggests that in addition to the two learning circumstances already discussed in this section, two additional conditions need to be fulfilled for formal reasoning to manifest in students’ problem-solving (Stanovich, 2011):

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  2. Students need to consciously engage the specific Type 2 processes that allow them to process their acquired formal understanding,
  3. The activated Type 2 processes need to override students’ default Type 1 processes, which offer an informal, often intuitively appealing, approach to problem-solving.

60 Leave a comment on paragraph 60 0 The human tendency to act as a “cognitive miser (Stanovich, 2011, p. 21) exerting as little cognitive effort as possible explains instances in which learners engage in cognitively effortful Type 2 processing in an insufficient manner or avoid it altogether. Crucially, a richer domain-specific understanding can only attenuate this educationally troubling tendency to miserly processing, which persists even among expert learners. Under both of the above scenarios, the lack of cognitive effort often means that students default to responses that are effortlessly generated by their Type 1 processing. Given that both educator and student can only observe the erroneous problem-solving that results from miserly Type 1 processing, students’ disciplinary knowledge and ability to formal reasoning may remain hidden and therefore unknown. This phenomenon constitutes the unfortunate source of the first perspective, which is solely based on students’ responses and thus neglects the cognitive processes that underlie those responses.

61 Leave a comment on paragraph 61 0 3.2. Linking Procedural and Conceptual Knowledge with the Two Processing Types

62 Leave a comment on paragraph 62 0 The well-established distinction between conceptual and procedural knowledge bears not only great significance in the domain of mathematics education, it also exhibits striking overlap with this paper’s distinction between Type 1 and Type 2 processing. Conceptual knowledge is described as a “connected web of knowledge, a network in which the linking relationships are as prominent as the discrete pieces of information” (Hiebert, 1986, pp. 3-4). Such knowledge is independent of specific problem types and can be known explicitly and implicitly. By contrast, procedural knowledge or skill refers to “knowledge of procedures, including action sequences and algorithms used in problem solving” (Star & Stylianides, 2013, p. 6) and can only be retrieved by the learner when solving the specific set of problems for which this knowledge was acquired. The relationship between conceptual and procedural is suggested to be reciprocal and iterative (Rittle-Johnson & Alibali, 1999): It is reciprocal in the sense that gains in one type of knowledge usually engender gains in the other knowledge type. The relationship is also iterative as the two types of knowledge are said to develop in a tandem. Strikingly, my dual-process analysis of the empirical case presented in Section 4.2 proposes an analogous reciprocal relationship between the two cognitive processing types: through learning to consciously engage in Type 2 processing, which is a necessary condition for formal statistical reasoning, the quality of students’ default responses (Type 1) improved throughout their undergraduate education.

63 Leave a comment on paragraph 63 1 In light of this analogy, it seems sensible to conjecture that algorithmic Type 2 processes play a decisive role in learners’ acquisition of procedural knowledge, whereas structural changes in learners’ Type 1 processing may underlie the achieved gains in conceptual understanding. This connection between knowledge and processing types illustrates the need for a closer investigation of learning progressions through combining the two perspectives. By promoting this synergy one may tap into the cognitive mechanisms that can explain and predict learners’ gains in conceptual and procedural knowledge. Such insights would help to increase the effectiveness of classroom interventions that are designed to facilitate students’ acquisition of conceptual and procedural knowledge. There are, at least, two conditions that this research project needs to fulfil:

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  2. It needs to rely on repeated continuous rather than categorical measures of participants’ growth in conceptual and procedural knowledge (Rittle-Johnson & Alibali, 1999),
  3. It needs to account for any qualitative changes in participants’ cognitive processing, which are expected to manifest as participants progress in their learning. These changes may be measured through administering a standard or modified version of the Cognitive Reflection Test (Frederick, 2005; Toplak, West, & Stanovich, 2011; Toplak, West, & Stanovich, 2014).

65 Leave a comment on paragraph 65 1 The above examples are only a small subset of significant areas of overlap between dual-process theory and mathematics education research. To gain greater understanding of these areas of overlap as well as their educational implications, researchers in the two fields need to pursue collaborative rather than independent efforts.

66 Leave a comment on paragraph 66 0 4. Dual-Process Analyses of Mathematical Reasoning

67 Leave a comment on paragraph 67 0 Table T3 sketches only a few examples of previous dual-process analyses of mathematical reasoning, which served as a springboard for this section’s two empirical studies. The depicted diversity of mathematical domains for which dual-process theory was suggested to be a meaningful analytical framework strengthens my hypothesis of its applicability to issues pertaining to mathematics education.

68 Leave a comment on paragraph 68 1 Table T3. Thumbnail Summary of Existing Applications of Dual-Process Theory to Mathematics Education

Publications Mathematical Area Observed Cognitive Bias
Obersteiner et al., 2013 Number Theory Natural Number Bias
Clement et al., 1981;         Leron & Hazzan, 2006 Algebra ·   Word order matching·   Static comparison

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Babai et al., 2015;              Stavy & Tirosh, 1996  Geometry Larger shape area is associated with a larger perimeter
Dooren et al., 2003;         Leron & Hazzan, 2009; Kahneman, 2013 Probability and statistics ·   Proportional/linear reasoning·   Base rate neglect/fallacy

70 Leave a comment on paragraph 70 0 ·   Conjunction fallacy

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72 Leave a comment on paragraph 72 0 4.1 Empirical Study I: The Illusion of Proportionality in Probabilistic Reasoning

73 Leave a comment on paragraph 73 0 4.1.1 Study Background and Reasons for Inclusion

74 Leave a comment on paragraph 74 1 The experimental study in Dooren et al. (2003) suggests that participants’ probabilistic reasoning results from an application of a proportional reasoning strategy: participants’ problem-solving reflects the proportions outlined in the task instructions. Since this proportional strategy instantly becomes participants’ default problem-solving strategy, implies that Type 1 cognitive processes prevailed whenever participants applied the proportional strategy. This experiment’s underlying connection between observed patterns in participants’ problem-solving and the cognitive architecture inherent to dual-process theory justifies its appearance in this review. Another reason is that Dooren et al. (2003) and Kahneman (2013) underscore probabilistic reasoning as a domain of mathematics for which there is conclusive empirical evidence on the misleading nature of people’s intuitions and preconceptions, which I will link with the predominant role of Type 1 processing. Meanwhile, the illusion of proportionality is a notable example of fallacious reasoning in the study of both probability and geometry (Dooren et al., 2003). Another striking feature of this study is that students’ proportional reasoning led to varying test outcomes across distinct types of test questions. Whereas being guided by a proportional strategy would typically lead to finding the correct solution in the case of a qualitative item, this strategy was the prime reason for mistakes on quantitative questions (Dooren et al., 2003).

75 Leave a comment on paragraph 75 0 An educationally troubling observation is that participants’ proportional reasoning was the direct result of the prior mathematics education they received at school. Since their mathematics instruction emphasised and valued proportional reasoning, students began to routinely rely on this type of reasoning without exerting cognitive effort to assess whether it is most or even minimally applicable in a specific learning circumstance. The following dual-process analysis will reveal how prior knowledge of proportionality may entice learners to employ Type 1 instead of Type 2 processing.

76 Leave a comment on paragraph 76 0 4.1.2 Dual-Process Analysis

77 Leave a comment on paragraph 77 0 In case of the qualitative test items, which received 88.9% correct answers, my theory proposes that participants’ Type 1 processing enabled students to arrive at the correct solution. There are, at least, two reasons for supposing that participants were employing Type 1 rather than Type 2 processing in those instances:

78 Leave a comment on paragraph 78 0 Firstly, as emphasised by Dooren et al. (2003), the concept of proportionality is a centrepiece of participants’ mathematics education prior to the experiment. Analogous to the driving case presented in Leron and Hazzan (2006), the use of proportional reasoning probably constituted a cognitively effortful Type 2 process before students began to extensively practise this approach in the classroom. Through repeated application and due to the intuitiveness of proportional reasoning (Dooren et al., 2003), its application became a default Type 1 process to students.

79 Leave a comment on paragraph 79 0 Secondly, by knowing that the experimental participants employed proportional thinking when solving the quantitative test problems, there is little reason to suppose that their cognitive processing changed within a single experiment: both the quantitative and qualitative test items were testing a single type of probabilistic reasoning.

80 Leave a comment on paragraph 80 0 The same proportional reasoning strategy that led to 88.9% correct answers on qualitative problems, misguided participants on quantitative problems with the latter receiving only 22.4% correct answers. What is especially striking is that most participants perceived the incorrect application of linear thinking as self-evident. For instance, a 12th grader named Anneken remarked: “In the second case, you get double as much occasions to obtain double as much fives. Therefore, logically speaking, the statement should be correct” (Dooren et al., 2003, p.131). Similarly, a 10th grader called Karen explained his fallacious reasoning in the following manner: “The occasions are halved, but also the goals. It is still directly proportional” (Dooren et al., 2003, p. 129). Crucially, the varying test and learning outcomes triggered by the participants’ use of Type 1 processing across qualitative and quantitative test items, is in line with dual-process theory. There is nothing about Type 1 processes that guarantees them to lead to correct problem-solving for a specific category of mathematical problems. Thus, it would be erroneous to infer from the above experiment that Type 1 processing generally yields correct answers on qualitative test items. Similarly, there is no ground for establishing that Type 1 processing always or even typically misguides students in the case of quantitative problems.

81 Leave a comment on paragraph 81 0 Rather, Type 1 processing’s learning implications depend on the quality of those cognitive processes in a given learner. The results of the probabilistic experiment imply that most of the participants’ Type 1 processing is at a level that allows correct problem-solving on the experiment’s qualitative items, but rules out correct problem-solving on the experiment’s quantitative items. In illustration, it is worth consulting a specific set of test items. For that purpose, I will consult experimental variable p, which exhibits the most drastic variation of correct answers between qualitative and quantitative items among all the study’s variables. Whereas the qualitative items received, on average, 95.6% correct answers, only an average of 16% of participants gave the correct answer on the quantitative item.

82 Leave a comment on paragraph 82 0 The qualitative test item on variable p:

83 Leave a comment on paragraph 83 0 “I roll a fair die several times. The chance to have at least once an even number if I can roll two times is

84 Leave a comment on paragraph 84 0 (a) larger than,

85 Leave a comment on paragraph 85 0 (b) smaller than or,

86 Leave a comment on paragraph 86 0 (c) equal to

87 Leave a comment on paragraph 87 0 the chance to have at least once a six if I can roll two times” (Dooren et al., 2003, p. 131).

88 Leave a comment on paragraph 88 0 The corresponding quantitative item:

89 Leave a comment on paragraph 89 0 “I roll a fair die several times. The chance to have at least once an even number if I can roll three times is three times as large as the chance to have at least once a five if I can roll three times.

90 Leave a comment on paragraph 90 0 (a) This is true,

91 Leave a comment on paragraph 91 0 (b) This is not true” (Dooren et al., 2003, p. 131).

92 Leave a comment on paragraph 92 0 By consulting participants’ written explanations, Dooren et al. were able to verify whether students’ problem-solving was characterised by proportional thinking. From that data, Dooren et al. ascertained that 95.6% of 10th graders and 86.9% of 12th graders applied proportional thinking when giving an incorrect answer on the above quantitative item. An explanation offered by Mathilde who is one of the 10th graders participating in the experiment will illustrate how using proportionality as a default strategy can lead to a mistake:

93 Leave a comment on paragraph 93 0 “The odd numbers on a die are 1,3,5 = 3/6

94 Leave a comment on paragraph 94 0 The chance to get one of the three numbers is three times as large as the chance to get a five = 1/6. (Dooren et al., p. 131)”.

95 Leave a comment on paragraph 95 0 Strikingly, although Mathilde was able to correctly determine the probability of getting an odd number on a single try, she ignored an essential piece of information mentioned in the instruction: the die is rolled three times rather than once. Dooren et al. promote this type of error being the result of pupils’ linear thinking producing an automatic mental response. Thus, the immediate availability of this response predetermined pupils’ problem-solving. Crucially, the way Dooren et al. interpret participants’ behaviour extensively overlaps with the definition of Type 1 processing featured at an earlier stage of this review. Supporting our hypothesis that Type 1 processes informed participants’ reasoning is that Mathilde’s act of calculating the probability of a simplified event is compatible with what Kahneman (2013) denotes as substitution.

96 Leave a comment on paragraph 96 0 Being presented with a cognitively challenging probabilistic problem, people tend to subconsciously substitute a difficult problem with an easier heuristic one. Thus, Mathilde gives a correct answer to a wrong problem, which was set up by her Type 1 processing. Through the creation of an easy-to-solve problem with an immediately accessible solution, Mathilde managed to maintain cognitive ease (Kahneman, 2013): a situation perceived as familiar and comfortable without the need for effortful engagement of Type 2 processing. Mathilde’s erroneous problem-solving is argued to be common among novices who tend to focus on surface-level features of a task (Berliner and Calfee, 1996). By contrast, more experienced learners tend to integrate task elements into abstract schemas that are elusive to novices (Berliner and Calfee, 1996).

97 Leave a comment on paragraph 97 0 It is timely to recall the disagreement among dual-process theorists whether a person’s cognitive architecture is best described by a parallel-competitive (Sloman, 1996) or a default-interventionist model (Evans, 2007). Verifying the applicability of the parallel-competitive model, the written explanations collected from the 10th and 12th graders participating in Dooren’s experiment (2003) show no indication for a conflict or a parallel interplay between distinct types of processing. Rather, pupils seem to be guided by a default response that was unconsciously generated in their minds (Dooren et al., 2003). Instead of reflecting on the validity and suitability of the automatic responses emerging in their minds (Stanovich and West, 1997), an overwhelming majority of pupils resolutely implemented those default responses when completing the quantitative test items. The only compatible among the three possible processing outcomes proposed by Evans (2007) is the case in which Type 1 processing generates a response without any intervention by Type 2 processing. Hence, this interpretation gives weight to the default-interventionist model of cognitive architecture.

98 Leave a comment on paragraph 98 0 4.2 Empirical Study II: The Cognitive Effects of Undergraduate Education on Statistical Reasoning

99 Leave a comment on paragraph 99 0 4.2.1 Study Background and Reasons for Inclusion

100 Leave a comment on paragraph 100 1 The following task and data found in Lehman and Nisbett (1990) provide an empirical foundation for illuminating the reverse channel of the relationship between reasoning and learning performance: the effect of knowledge acquisition on learners’ use of Type 1 and Type 2 processing and its effectiveness. There are several pertinent reasons for including this specific study: First, the study’s results suggest a particularly significant improvement in students’ statistical-methodological reasoning, which is of central concern to both dual-process theorists and mathematics education researchers. Second, participants’ statistical-methodological reasoning was measured both in a domain-specific and domain-general setup: the study’s participants completed a test that combined scientific and everyday-life problems. This variety of mathematical problems intentionally designed by Lehman and Nisbett indicates that the observed changes in students’ reasoning hold for domains that can be regarded as mutually independent. For that reason, I find this study’s results more credible than alternative ones, which verify changes in people’s reasoning in a single or otherwise more narrow context (e.g., Lem, 2015; Morsanyi, Busdraghi, and Primi, 2014).

101 Leave a comment on paragraph 101 0 An additional strength of Lehman’s and Nisbett’s study is its sample data, which features a total of 121 students across a wide range of subjects including the natural sciences, humanities, social sciences, and psychology. The richness of the sample makes it possible to verify the presence of heterogenous treatment effects. In other words, it is possible to compare changes in statistical reasoning not only within individuals, but also between students with varying degrees of statistics training. The experimental data that the following analysis relies on is taken from Lehman and Nisbett (1990).

102 Leave a comment on paragraph 102 0 4.2.2 Dual-Process Analysis

103 Leave a comment on paragraph 103 0 My conjecture is that there are two possible explanations for the substantial improvement in statistical reasoning that experimental participants achieved throughout their undergraduate studies (Lehman and Nisbett, 1990): First, after having received statistics training in the course of their undergraduate education, the now 4th year students were more likely to approach statistical problems through the use of Type 2 processing. Thus, compared to when the same students were in their very first semester, their reasoning was more likely to be dominated by Type 2 processes. In other words, as a consequence of their statistics training, students were increasingly able to critically reflect on the default responses generated by Type 1 processing with Type 2 processing interfering when necessary (Stanovich and West, 1997).

104 Leave a comment on paragraph 104 0 A second explanation is that through their statistical training students’ Type 1 processing improved in a way that would be compatible with the observed improvements in statistical reasoning (Lehman and Nisbett, 1990). What previously would require effortful Type 2 processes was now performed by means of the immediate responses generated by Type 1 processes. Thus, even without interventions of Type 2 processing, students’ refined Type 1 processing may explain the highlighted improvements in statistical reasoning.

105 Leave a comment on paragraph 105 0 Meanwhile, these two dual-process explanations are by no means mutually exclusive. Through repeated practice learners’ performance is said to become more automatic, whereby an increasing number of previously controlled cognitive processes becomes available for abstract processing (Gagné, 1985). Gagné maintains that this process of unitisation is marked by people’s reorganisation of knowledge: the skills that are necessary to complete a given task or problem are organised into larger and more efficient units enabling more effective problem-solving. Extrapolating from Gagné’s theory of unitisation, one may argue that the students with enhanced statistical reasoning featuring in the sample collected by Lehman and Nisbett, were more likely to exhibit two cognitive trends:

  1. 106 Leave a comment on paragraph 106 0
  2. Following their statistical training, students’ Type 1 processing became more efficient compared to their Type 1 processing prior to taking statistics courses and thus engendered the observed improvements in reasoning,
  3. Having already practiced with numerous statistical problems, the statistical reasoning test administered by Lehman and Nisbett created less cognitive strain among students compared to when the students were new to statistical problems (Kahneman, 2013). As a consequence of the reduced cognitive strain, students were more likely to employ abstract Type 2 processing, which gave rise to their improved test performance.

107 Leave a comment on paragraph 107 1 In order to further evaluate the relationship between knowledge acquisition and reasoning one should consider the significant correlations between the number of statistics courses taken by students and the associated improvement in their “statistical-methodological reasoning” (Lehman and Nisbett, 1990, p. 957). Such a correlation was observed across three out of the four subject areas: psychology, social sciences, and natural sciences with the respective correlation coefficients amounting to .23, .23, and .28. Due to the small number of statistics courses taken by humanities students, Lehman and Nisbett regarded the sample of humanities students as insufficient for calculating a correlation. The observed correlation coefficients give weight to the general hypothesis that, by working on statistics courses, students not only acquire statistical knowledge, but also enhance their overall statistical reasoning. An even more notable observation is that students’ improvements in reasoning are contingent on the number of courses they have taken throughout their studies. The latter relationship can be explained by expanding on the two dual-process explanations that I elucidated earlier in this section.

108 Leave a comment on paragraph 108 0 The first explanation, which centres on the increased role of Type 2 processing, entails that students who took a relatively large number of statistics courses were more likely to employ strenuous Type 2 processing compared to students who received relatively little statistical training. Thus, the former group’s problem-solving was more immune to misleading Type 1 processing compared to the latter group. In terms of the three possible outcomes originating from Evans’ default-interventionist model (2007), the former group was more likely than the latter to achieve either the second outcome – the default response R generated by Type 1 processing is chosen despite the intervention of Type 2 processing – or the third outcome – the alternative response A is chosen after an intervention of Type 2 processing (Evans, 2007). Thus, the students with extensive statistical training benefited from Type 2 processing as an analytical monitor of their Type 1 processing, whereby they managed to deviate from an erroneous default response R.

109 Leave a comment on paragraph 109 0 The second explanation of students’ refined statistical reasoning, which proposes a more efficient working of Type 1 processing, implies that the more statistical instruction students receive, the more adept their Type 1 processing becomes at solving any type of statistical problems or tasks. Different from Evans’ model (2007), which includes only one possible response R generated by Type 1 processing, this interpretation allows for multiple responses being generated by Type 1 processes accounting for changes in learners’ knowledge base. Accordingly, it may be that a participant’s original Type 1 response R, which determined her problem-solving during the experiment’s first reasoning test (Lehman and Nisbett, 1990) is qualitatively different from the Type 1 response R’ appearing in the same participant’s mind during the experiment’s second reasoning test during her 4th year of undergraduate studies. Whereas response R may have elicited a fallacious solution, response R’ may have helped the student to arrive at a correct solution.

110 Leave a comment on paragraph 110 0 A principal strength of the experimental analysis conducted by Lehman and Nisbett is that they were able to test both domain-specific and domain-general reasoning ability. Given that domain-general reasoning is an especially pressing concern among educators and educational researchers, tapping into a potential cause of this type of reasoning is an educationally paramount project (e.g., Fuchs et al., 2012; Niaz, 1994). By choosing this form of research design, Lehman and Nisbett accounted for the possibility that the observed changes in domain-specific reasoning may result from students’ refined statistical knowledge base rather than fundamental changes in their cognitive processing. Given that participants’ statistical reasoning improved on both domain-specific and domain-general test items, it seems that as a result of their statistics education students began to employ more refined statistical reasoning even when dealing with novel and unrelated problems that weren’t covered in their statistics classes. What exactly justifies this argumentative leap?

111 Leave a comment on paragraph 111 0 To assert the validity of this argument it is worth looking at an exemplary every-day life problem, which forms part of the statistical reasoning test featuring in Lehman and Nisbett. Participants were asked to explain why rookies of the year in major-league baseball tend not to do as well in their second league year. The statistical principle of regression to the mean, which facilitates correct problem-solving on this test item, was not mentioned by the experimenters. In order to solve this problem, participants had to apply the statistical principle they learned in class. Since it is exceedingly unlikely that students learned about regression to the mean by means of this particular baseball example, the participants’ improved test performance indicates that their understanding of regression of the mean transformed the way their cognitive processing would function when presented with such a or a similar problem. Thus, one would expect the students to successfully identify regression to the mean problems taken from other randomly selected domains with which students had no prior learning experience.

112 Leave a comment on paragraph 112 0 One important question that remained untouched by Lehman and Nisbett is how temporary or permanent the observed improvements in students’ reasoning are. As suggested by the theoretical and empirical evidence on Type 1 processing evaluated in this review, Type 1 processes are not fixed algorithms, but evolve in response to individual learning progressions (Lehrer and Schauble, 2012). In light of this malleability associated with Type 1 processing an important educational and theoretical consideration is whether and how changes in cognitive processing that are favourable to people’s learning, as for instance the statistical reasoning improvements documented by Lehman and Nisbett, can be sustained over time. Hence, when designing an experimental study similar to the one found in Lehman and Nisbett, it appears advantageous to verify participants’ cognitive processing at a third time point at which participants have already completed their statistics education.

113 Leave a comment on paragraph 113 0 Conclusion and Avenues for Future Research

114 Leave a comment on paragraph 114 0 Researchers of mathematics education are increasingly cognisant that cognitive psychology in general and dual-process theory in particular offer a valuable analytical framework for evaluating and improving students’ mathematical reasoning and thus learning performance. While the application of dual-process theory to the study of mathematics education is only at its advent, this research avenue continues to gain ground with increasing speed and impact (see Kryjevskaia et al., 2014; Lem, 2015; Morsanyi, Busdraghi, & Primi, 2014).

115 Leave a comment on paragraph 115 2 In this review, I have first outlined recent conceptual trends in dual-process theory of reasoning followed by an analysis of two empirical studies of mathematical learning, which can be productively informed by dual-process theory. My analysis has revealed the immense extent to which the effectiveness of mathematics education relies on learners’ use of Type 1 and Type 2 processing. As a result, this essay presents a case for bridging the two vastly separate bodies of literature on dual processing and mathematics education, which promises to benefit both scientific communities.

116 Leave a comment on paragraph 116 2 On the one hand, dual-process theorists could markedly refine their accounts by testing the exact interplay between Type 1 and 2 processing in concrete instances of mathematical instruction and learning. This form of theory testing promises to advance dual-process theory in two key regards: First, to reveal whether the two hypothesised types of cognitive processing exhibit a parallel-competitive or default-interventionist structure (Evans and Stanovich, 2013). Second, to empirically test Stanovich’s hypothesis of the existence of a reflective mind that evaluates responses generated by Type 2 processing.

117 Leave a comment on paragraph 117 1 On the other hand, dual-process theory offers educational researchers a valuable interpretative lens through which they can tap into and effectively remedy cases in which mathematics students are misled by either type of cognitive processing or their combined failure. One promising way to nurture a collaboration between dual-process theorists and mathematics education researchers is to analyse the varying roles Type 1 and 2 processing play across different time points of a mathematical learning unit both within the same and across distinct learners. A potential methodological direction for accomplishing a fruitful collaboration between cognitive science and mathematics education research is to conduct longitudinal design-experiments across distinct classroom settings. This methodology combines the practical purpose of improving instruction and the theoretical purpose of refining dual-process theory.

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120 Leave a comment on paragraph 120 0 References

121 Leave a comment on paragraph 121 0  Ackerman, P. L. (1992). Predicting individual differences in complex skill acquisition: dynamics of ability determinants. The Journal of Applied Psychology, 77(5), 598–614.

122 Leave a comment on paragraph 122 0 Amsel, E., Klaczynski, P. A., Johnston, A., Bench, S., Close, J., Sadler, E., & Walker, R. (2008). A dual-process account of the development of scientific reasoning: The nature and development of metacognitive intercession skills. Cognitive Development, 23(4), 452–471. http://doi.org/10.1016/j.cogdev.2008.09.002

123 Leave a comment on paragraph 123 0 Attridge, N., & Inglis, M. (2014). Increasing cognitive inhibition with a difficult prior task: implications for mathematical thinking. ZDM, 47(5), 723–734. http://doi.org/10.1007/s11858-014-0656-1

124 Leave a comment on paragraph 124 0 Babai, R., Shalev, E., & Stavy, R. (2015). A warning intervention improves students’ ability to overcome intuitive interference. ZDM, 47(5), 735–745. http://doi.org/10.1007/s11858-015-0670-y

125 Leave a comment on paragraph 125 0 Barbey, A. K., & Sloman, S. A. (2007). Base-rate respect: From ecological rationality to dual processes. The Behavioral and Brain Sciences, 30(3), 241–254; discussion 255–297. http://doi.org/10.1017/S0140525X07001653

126 Leave a comment on paragraph 126 0 Baroody, A. J., Purpura, D. J., Eiland, M. D., Reid, E. E., & Paliwal, V. (2015). Does Fostering Reasoning Strategies for Relatively Difficult Basic Combinations Promote Transfer by K-3 Students? Journal of Educational Psychology, No Pagination Specified. http://doi.org/10.1037/edu0000067

127 Leave a comment on paragraph 127 0 Bethany Rittle-Johnson, M. W. A. (1999). Conceptual and Procedural Knowledge of mathematics: Does one lead to the other? Journal of Educational Psychology, 91, 175-189. Journal of Educational Psychology, 91(1), 175–189. http://doi.org/10.1037/0022-0663.91.1.175

128 Leave a comment on paragraph 128 0 Bielaczyc, K., Pirolli, P. L., & Brown, A. L. (1995). Training in Self-Explanation and Self-Regulation Strategies: Investigating the Effects of Knowledge Acquisition Activities on Problem Solving. Cognition and Instruction, 13(2), 221–252. http://doi.org/10.1207/s1532690xci1302_3

129 Leave a comment on paragraph 129 0 Boehler, C. N., Hopf, J.-M., Krebs, R. M., Stoppel, C. M., Schoenfeld, M. A., Heinze, H.-J., & Noesselt, T. (2011). Task-load-dependent activation of dopaminergic midbrain areas in the absence of reward. The Journal of Neuroscience: The Official Journal of the Society for Neuroscience, 31(13), 4955–4961. http://doi.org/10.1523/JNEUROSCI.4845-10.2011

130 Leave a comment on paragraph 130 0 Clement, J., Lochhead, J., & Monk, G. S. (1981). Translation Difficulties in Learning Mathematics. The American Mathematical Monthly, 88(4), 286. http://doi.org/10.2307/2320560

131 Leave a comment on paragraph 131 0 Culham, J. C., Cavanagh, P., & Kanwisher, N. G. (2001). Attention Response Functions: Characterizing Brain Areas Using fMRI Activation during Parametric Variations of Attentional Load. Neuron, 32(4), 737–745. http://doi.org/10.1016/S0896-6273(01)00499-8

132 Leave a comment on paragraph 132 0 Dooren, W. V., Bock, D. D., Depaepe, F., Janssens, D., & Verschaffel, L. (2003). The Illusion of Linearity: Expanding the evidence towards probabilistic reasoning. Educational Studies in Mathematics, 53(2), 113–138. http://doi.org/10.1023/A:1025516816886

133 Leave a comment on paragraph 133 0 Dougherty, M. R. ., & Franco-Watkins, A. M. (2000). Who is rational: studies of individual differences in reasoning. Keith E. Stanovich. Lawrence Erlbaum Associates. Mahwah, NJ, 1999. No. of pages 296. ISBN 0-8058-2473-1. Applied Cognitive Psychology, 14(6), 595–597. http://doi.org/10.1002/1099-0720(200011/12)14:6<595::AID-ACP712>3.0.CO;2-I

134 Leave a comment on paragraph 134 0 Dubinsky, E. (2002). Reflective Abstraction in Advanced Mathematical Thinking. In D. Tall (Ed.), Advanced Mathematical Thinking (pp. 95–126). Springer Netherlands. Retrieved from http://link.springer.com/chapter/10.1007/0-306-47203-1_7

135 Leave a comment on paragraph 135 0 Evans, J. S. B. T. (1996). Deciding before you think: Relevance and reasoning in the selection task. British Journal of Psychology, 87(2), 223–240. http://doi.org/10.1111/j.2044-8295.1996.tb02587.x

136 Leave a comment on paragraph 136 0 Evans, J. S. B. T. (2003). In two minds: dual-process accounts of reasoning. Trends in Cognitive Sciences, 7(10), 454–459. http://doi.org/10.1016/j.tics.2003.08.012

137 Leave a comment on paragraph 137 0 Evans, J. S. B. T. (2007). On the resolution of conflict in dual process theories of reasoning. Thinking & Reasoning, 13(4), 321–339. http://doi.org/10.1080/13546780601008825

138 Leave a comment on paragraph 138 0 Evans, J. S. B. T. (2012). Questions and challenges for the new psychology of reasoning. Thinking & Reasoning, 18(1), 5–31. http://doi.org/10.1080/13546783.2011.637674

139 Leave a comment on paragraph 139 0 Evans, J. S. B. T., & Curtis-Holmes, J. (2005). Rapid responding increases belief bias: Evidence for the dual-process theory of reasoning. Thinking & Reasoning, 11(4), 382–389. http://doi.org/10.1080/13546780542000005

140 Leave a comment on paragraph 140 0 Evans, J. S. B. T., & Stanovich, K. E. (2013). Dual-Process Theories of Higher Cognition: Advancing the Debate. Perspectives on Psychological Science: A Journal of the Association for Psychological Science, 8(3), 223–241. http://doi.org/10.1177/1745691612460685

141 Leave a comment on paragraph 141 0 Geary, D. C., Hoard, M. K., Byrd-Craven, J., Nugent, L., & Numtee, C. (2007). Cognitive mechanisms underlying achievement deficits in children with mathematical learning disability. Child Development, 78(4), 1343–1359. http://doi.org/10.1111/j.1467-8624.2007.01069.x

142 Leave a comment on paragraph 142 0 Gillard, E., Van Dooren, W., Schaeken, W., & Verschaffel, L. (2009). Proportional reasoning as a heuristic-based process: time constraint and dual task considerations. Experimental Psychology, 56(2), 92–99. http://doi.org/10.1027/1618-3169.56.2.92

143 Leave a comment on paragraph 143 0 Goel, V. (2007). Anatomy of deductive reasoning. Trends in Cognitive Sciences, 11(10), 435–441. http://doi.org/10.1016/j.tics.2007.09.003

144 Leave a comment on paragraph 144 0 Greene, J. D., Nystrom, L. E., Engell, A. D., Darley, J. M., & Cohen, J. D. (2004). The neural bases of cognitive conflict and control in moral judgment. Neuron, 44(2), 389–400. http://doi.org/10.1016/j.neuron.2004.09.027

145 Leave a comment on paragraph 145 0 Jaeggi, S. M., Seewer, R., Nirkko, A. C., Eckstein, D., Schroth, G., Groner, R., & Gutbrod, K. (2003). Does excessive memory load attenuate activation in the prefrontal cortex? Load-dependent processing in single and dual tasks: functional magnetic resonance imaging study. NeuroImage, 19(2), 210–225. http://doi.org/10.1016/S1053-8119(03)00098-3

146 Leave a comment on paragraph 146 0 Johnson, M. A., & Lawson, A. E. (1998a). What are the relative effects of reasoning ability and prior knowledge on biology achievement in expository and inquiry classes? Journal of Research in Science Teaching, 35(1), 89–103. http://doi.org/10.1002/(SICI)1098-2736(199801)35:1<89::AID-TEA6>3.0.CO;2-J

147 Leave a comment on paragraph 147 0 Johnson, M. A., & Lawson, A. E. (1998b). What are the relative effects of reasoning ability and prior knowledge on biology achievement in expository and inquiry classes? Journal of Research in Science Teaching, 35(1), 89–103. http://doi.org/10.1002/(SICI)1098-2736(199801)35:1<89::AID-TEA6>3.0.CO;2-J

148 Leave a comment on paragraph 148 0 Just, M. A., & Carpenter, P. A. (1992). A capacity theory of comprehension: individual differences in working memory. Psychological Review, 99(1), 122–149.

149 Leave a comment on paragraph 149 0 Kahneman, D. (2013). Thinking, fast and slow.

150 Leave a comment on paragraph 150 0 Kahneman, D., & Klein, G. (2009). Conditions for intuitive expertise: A failure to disagree. American Psychologist, 64(6), 515–526. http://doi.org/10.1037/a0016755

151 Leave a comment on paragraph 151 0 Kokis, J. V., Macpherson, R., Toplak, M. E., West, R. F., & Stanovich, K. E. (2002). Heuristic and analytic processing: age trends and associations with cognitive ability and cognitive styles. Journal of Experimental Child Psychology, 83(1), 26–52.

152 Leave a comment on paragraph 152 0 Kryjevskaia, M., Stetzer, M. R., & Grosz, N. (2014). Answer first: Applying the heuristic-analytic theory of reasoning to examine student intuitive thinking in the context of physics. Physical Review Special Topics – Physics Education Research, 10(2), 020109. http://doi.org/10.1103/PhysRevSTPER.10.020109

153 Leave a comment on paragraph 153 0 Lem, S. (2015). The intuitiveness of the law of large numbers. ZDM, 47(5), 783–792. http://doi.org/10.1007/s11858-015-0676-5

154 Leave a comment on paragraph 154 0 Leron, U., & Hazzan, O. (2006). The Rationality Debate: Application of Cognitive Psychology to Mathematics Education. Educational Studies in Mathematics, 62(2), 105–126.

155 Leave a comment on paragraph 155 0 Leron, U., & Hazzan, O. (2009). Intuitive vs Analytical Thinking: Four Perspectives. Educational Studies in Mathematics, 71(3), 263–278.

156 Leave a comment on paragraph 156 0 Liang, K.-Y., & Zeger, S. L. (1986). Longitudinal data analysis using generalized linear models. Biometrika, 73(1), 13–22. http://doi.org/10.1093/biomet/73.1.13

157 Leave a comment on paragraph 157 0 Liang, P., Jia, X., Taatgen, N. A., Zhong, N., & Li, K. (2014). Different strategies in solving series completion inductive reasoning problems: an fMRI and computational study. International Journal of Psychophysiology: Official Journal of the International Organization of Psychophysiology, 93(2), 253–260. http://doi.org/10.1016/j.ijpsycho.2014.05.006

158 Leave a comment on paragraph 158 0 Lieberman, M. D. (2009). What Zombies Can’t Do: A Social Cognitive Neuroscience Approach to the Irreducibility of Reflective Consciousness. In K. Frankish & J. S. B. T. Evans (Eds.), In Two Minds: Dual Processes and Beyond (pp. 293–316). Oxford University Press.

159 Leave a comment on paragraph 159 0 María Luz Callejo, A. V. (2009). Approach to mathematical problem solving and students’ belief systems: two case studies. Educational Studies in Mathematics, 72(1), 111-126. Educational Studies in Mathematics, 72(1), 111–126. http://doi.org/10.1007/s10649-009-9195-z

160 Leave a comment on paragraph 160 0 Mayer, R. E. (1992). Cognition and instruction: Their historic meeting within educational psychology. Journal of Educational Psychology, 84(4), 405–412. http://doi.org/10.1037/0022-0663.84.4.405

161 Leave a comment on paragraph 161 0 Mayer, R. E., & Moreno, R. (1998). A split-attention effect in multimedia learning: Evidence for dual processing systems in working memory. Journal of Educational Psychology, 90(2), 312–320. http://doi.org/10.1037/0022-0663.90.2.312

162 Leave a comment on paragraph 162 0 Means, M. L., & Voss, J. F. (1996). Who Reasons Well? Two Studies of Informal Reasoning Among Children of Different Grade, Ability, and Knowledge Levels. Cognition and Instruction, 14(2), 139–178. http://doi.org/10.1207/s1532690xci1402_1

163 Leave a comment on paragraph 163 0 Morsanyi, K., Busdraghi, C., & Primi, C. (2014). Mathematical anxiety is linked to reduced cognitive reflection: a potential road from discomfort in the mathematics classroom to susceptibility to biases. Behavioral and Brain Functions: BBF, 10(1), 31. http://doi.org/10.1186/1744-9081-10-31

164 Leave a comment on paragraph 164 0 Neys, W. D. (2006). Dual Processing in Reasoning Two Systems but One Reasoner. Psychological Science, 17(5), 428–433. http://doi.org/10.1111/j.1467-9280.2006.01723.x

165 Leave a comment on paragraph 165 0 Obersteiner, A., Van Dooren, W., Van Hoof, J., & Verschaffel, L. (2013). The natural number bias and magnitude representation in fraction comparison by expert mathematicians. Learning and Instruction, 28, 64–72. http://doi.org/10.1016/j.learninstruc.2013.05.003

166 Leave a comment on paragraph 166 0 Osman, M. (2004). An evaluation of dual-process theories of reasoning. Psychonomic Bulletin & Review, 11(6), 988–1010. http://doi.org/10.3758/BF03196730

167 Leave a comment on paragraph 167 0 Pace, J. P. (1991). [Review of Review of Structure and Insight: A Theory of Mathematics Education, by P. M. van Hiele]. Educational Studies in Mathematics, 22(1), 95–103.

168 Leave a comment on paragraph 168 0 Pirie, S., & Kieren, T. (1994). Growth in mathematical understanding: How can we characterise it and how can we represent it? Educational Studies in Mathematics, 26(2-3), 165–190. http://doi.org/10.1007/BF01273662

169 Leave a comment on paragraph 169 0 Reyna, V. F., Chick, C. F., Corbin, J. C., & Hsia, A. N. (2014). Developmental Reversals in Risky Decision Making Intelligence Agents Show Larger Decision Biases Than College Students. Psychological Science, 25(1), 76–84. http://doi.org/10.1177/0956797613497022

170 Leave a comment on paragraph 170 0 Roberts, M. J., & Newton, E. J. (2001). Inspection times, the change task, and the rapid-response selection task. The Quarterly Journal of Experimental Psychology. A, Human Experimental Psychology, 54(4), 1031–1048. http://doi.org/10.1080/713756016

171 Leave a comment on paragraph 171 0 Sidney, P. G., & Alibali, M. W. (2015). Making Connections in Math: Activating a Prior Knowledge Analogue Matters for Learning. Journal of Cognition and Development, 16(1), 160–185. http://doi.org/10.1080/15248372.2013.792091

172 Leave a comment on paragraph 172 0 Silver, E. A. (1979). Student Perceptions of Relatedness among Mathematical Verbal Problems. Journal for Research in Mathematics Education, 10(3), 195–210. http://doi.org/10.2307/748807

173 Leave a comment on paragraph 173 0 Simon, H. A. (1990). Invariants of Human Behavior. Annual Review of Psychology, 41(1), 1–20. http://doi.org/10.1146/annurev.ps.41.020190.000245

174 Leave a comment on paragraph 174 0 Stanovich, K. E., & West, R. F. (2000). Individual differences in reasoning: implications for the rationality debate? The Behavioral and Brain Sciences, 23(5), 645–665; discussion 665–726.

175 Leave a comment on paragraph 175 0 Stanovich, K. E., & West, R. F. (2007). Natural myside bias is independent of cognitive ability. Thinking & Reasoning, 13(3), 225–247. http://doi.org/10.1080/13546780600780796

176 Leave a comment on paragraph 176 0 Stavy, R., & Tirosh, D. (1996). Intuitive rules in science and mathematics: the case of ‘more of A ‐‐ more of B’. International Journal of Science Education, 18(6), 653–667. http://doi.org/10.1080/0950069960180602

177 Leave a comment on paragraph 177 0 Stein, M. K., Grover, B. W., & Henningsen, M. (1996a). Building Student Capacity for Mathematical Thinking and Reasoning: An Analysis of Mathematical Tasks Used in Reform Classrooms. American Educational Research Journal, 33(2), 455–488. http://doi.org/10.2307/1163292

178 Leave a comment on paragraph 178 0 Toplak, M. E., & Stanovich, K. E. (2002). The domain specificity and generality of disjunctive reasoning: Searching for a generalizable critical thinking skill. Journal of Educational Psychology, 94(1), 197–209. http://doi.org/10.1037/0022-0663.94.1.197

179 Leave a comment on paragraph 179 0 Toplak, M. E., West, R. F., & Stanovich, K. E. (2011). The Cognitive Reflection Test as a predictor of performance on heuristics-and-biases tasks. Memory & Cognition, 39(7), 1275–1289. http://doi.org/10.3758/s13421-011-0104-1

180 Leave a comment on paragraph 180 0 Toplak, M. E., West, R. F., & Stanovich, K. E. (2014). Assessing miserly information processing: An expansion of the Cognitive Reflection Test. Thinking & Reasoning, 20(2), 147–168. http://doi.org/10.1080/13546783.2013.844729

181 Leave a comment on paragraph 181 0 Tsujii, T., & Watanabe, S. (2009). Neural correlates of dual-task effect on belief-bias syllogistic reasoning: a near-infrared spectroscopy study. Brain Research, 1287, 118–125. http://doi.org/10.1016/j.brainres.2009.06.080

182 Leave a comment on paragraph 182 0 Tzur, R., & Simon, M. (2004). Distinguishing Two Stages of Mathematics Conceptual Learning. International Journal of Science and Mathematics Education, 2(2), 287–304. http://doi.org/10.1007/s10763-004-7479-4

183 Leave a comment on paragraph 183 0 VanderStoep, S. W., & Shaughnessy, J. J. (1997). Taking a Course in Research Methods Improves Reasoning about Real-Life Events. Teaching of Psychology, 24(2), 122–124. http://doi.org/10.1207/s15328023top2402_8

184 Leave a comment on paragraph 184 0 Zhang, L., Gan, J. Q., & Wang, H. (2015). Localization of neural efficiency of the mathematically gifted brain through a feature subset selection method. Cognitive Neurodynamics, 9(5), 495–508. http://doi.org/10.1007/s11571-015-9345-1

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