Book contents
- Frontmatter
- Contents
- Preface
- Acknowledgments
- List of Contributors
- 1 Research on the Women and Mathematics Issue: A Personal Case History
- 2 The Perseverative Search for Sex Differences in Mathematics Ability
- 3 A Psychobiosocial Model: Why Females Are Sometimes Greater Than and Sometimes Less Than Males in Math Achievement
- 4 Gender Differences in Math: Cognitive Processes in an Expanded Framework
- 5 Cognitive Contributions to Sex Differences in Math Performance
- 6 Spatial Ability as a Mediator of Gender Differences on Mathematics Tests: A Biological–Environmental Framework
- 7 Examining Gender-Related Differential Item Functioning Using Insights from Psychometric and Multicontext Theory
- 8 The Gender-Gap Artifact: Women's Underperformance in Quantitative Domains Through the Lens of Stereotype Threat
- 9 “Math is hard!” (Barbie™, 1994): Responses of Threat vs. Challenge-Mediated Arousal to Stereotypes Alleging Intellectual Inferiority
- 10 The Role of Ethnicity on the Gender Gap in Mathematics
- 11 The Gender Gap in Mathematics: Merely a Step Function?
- 12 “I can, but I don't want to”: The Impact of Parents, Interests, and Activities on Gender Differences in Math
- 13 Gender Effects on Mathematics Achievement: Mediating Role of State and Trait Self-Regulation
- 14 Gender Differences in Mathematics Self-Efficacy Beliefs
- 15 Gender Differences in Mathematics: What We Know and What We Need to Know
- Author Index
- Subject Index
- References
4 - Gender Differences in Math: Cognitive Processes in an Expanded Framework
Published online by Cambridge University Press: 05 June 2012
Book contents
- Frontmatter
- Contents
- Preface
- Acknowledgments
- List of Contributors
- 1 Research on the Women and Mathematics Issue: A Personal Case History
- 2 The Perseverative Search for Sex Differences in Mathematics Ability
- 3 A Psychobiosocial Model: Why Females Are Sometimes Greater Than and Sometimes Less Than Males in Math Achievement
- 4 Gender Differences in Math: Cognitive Processes in an Expanded Framework
- 5 Cognitive Contributions to Sex Differences in Math Performance
- 6 Spatial Ability as a Mediator of Gender Differences on Mathematics Tests: A Biological–Environmental Framework
- 7 Examining Gender-Related Differential Item Functioning Using Insights from Psychometric and Multicontext Theory
- 8 The Gender-Gap Artifact: Women's Underperformance in Quantitative Domains Through the Lens of Stereotype Threat
- 9 “Math is hard!” (Barbie™, 1994): Responses of Threat vs. Challenge-Mediated Arousal to Stereotypes Alleging Intellectual Inferiority
- 10 The Role of Ethnicity on the Gender Gap in Mathematics
- 11 The Gender Gap in Mathematics: Merely a Step Function?
- 12 “I can, but I don't want to”: The Impact of Parents, Interests, and Activities on Gender Differences in Math
- 13 Gender Effects on Mathematics Achievement: Mediating Role of State and Trait Self-Regulation
- 14 Gender Differences in Mathematics Self-Efficacy Beliefs
- 15 Gender Differences in Mathematics: What We Know and What We Need to Know
- Author Index
- Subject Index
- References
Summary
Scientists and nonscientists alike construct theories to explain variations in the environment (Byrnes, 2001a). For example, zoologists devise theories to explain observable differences in the physical appearance of species, and developmental scientists create theories to explain changes in performance that occur between early childhood and adulthood. The authors in this book are chiefly concerned with variations in math performance that are evident when one compares boys with girls or men with women. Explaining these gender-based variations is not an easy task because the size and direction of differences change with age, content, measure, and context (Hyde, Fennema, & Lamon, 1990). The purpose of this chapter is to present a comprehensive account of gender differences that explains most of the variations that have been revealed to date. As I will argue later, the primary virtue of such an account is that it could form the basis of highly effective forms of intervention.
The rest of this chapter is organized as follows. In the first section, I provide a brief overview of the pattern of gender differences that have been reported in the literature. This pattern represents the phenomenon that needs to be explained by any theory of gender differences. In the second section, I summarize and critique existing explanations of these findings (including a Cognitive Process approach that my colleagues and I proposed in the mid-1990s). In the third section, I present a new explanatory model that was created to extend and integrate the existing explanations (called the Three Conditions model).
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- Chapter
- Information
- Gender Differences in MathematicsAn Integrative Psychological Approach, pp. 73 - 98Publisher: Cambridge University PressPrint publication year: 2004
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