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For the past fifty years, there has been a gap in the educational achievement of males and females in the United States, but which gender has been disadvantaged has fluctuated over the years. In the 1970s and 1980s, data showed girls trailing behind boys in a variety of academic performance measures, specifically in test scores in math and science. However, data in the last twenty years shows the general trend of girls outperforming boys in academic achievement in terms of class grades across all subjects and college graduation rates, but boys scoring higher on standardized tests and being better represented in the higher-paying and more prestigious STEM fields (science, technology, engineering, and math). ^[1]

Evidence of the gender achievement gap in the United States

Gender gap in literacy

 

Achievement gaps between boys and girls in the United States are more pronounced in reading and writing than in math and science.

Traditionally, girls have outperformed boys in reading and writing. Although this gap may be minimal in kindergarten, it grows as students continue their education. According the 2004 National Reading Assessment measured by the US Department of Education, the gap between boys and girls, only slightly noticeable in 4th grade, left boys 14 points behind girls during their 12th grade year. ^[2] On the 2008 test, female students continued to have higher average reading scores than male students at all three ages. The gap between male and female 4th graders was 7 points in 2008. By 12th grade, there was an 11 point gap between males and females.^[2]

On the 2002 National Writing Assessment, boys scored on average 17 points lower than girls in 4th grade. The average gap increased to 21 points by 8th grade and widened to 24 points by senior year in high school. ^[3] In the more recent 2007 National Assessment of Writing Skills, female students continued to score higher than male students, though margins closed slightly from previous assessments. The average score for female eighth-graders was 20 points higher than males, down 1 point from the 2002 score. For twelfth-graders, females outscored males by 18 points as opposed to 21 points in 2002. ^[4]

Gender gap in math and science

Which gender is disadvantaged by the gap in math and science achievement largely depends on how academic achievement is being measured. Female students generally have better grades in their math classes, and this gap starts off very minimal but increases with age. ^[5] However, males score higher on standardized math tests, and these score gaps also increase with age. Male students also score higher on measures of college readiness, such as the AP Calculus exams and the math section of the SAT. ^[6] The differences in National Assessment for Educational Progress (NAEP) math scores between boys and girls nearly double from the 9-year olds to the 17-year olds.^[7] This inconsistency in which gender shows more achievement could be due to the fact that class grades, especially in middle and high school, usually depend on a student’s completion of homework assignments, and studies have shown that girls report spending more time on homework than boys. ^[8]The gender gap in mathematics is particularly large among the highest-achieving students; for example, there is a 2.1-1 male-female ratio among students who score an 800 on the math portion of the SAT.^[9]

At least one study has challenged the existence of the gender gap in mathematics. In 2008 Janet Hyde and others published a study showing that male and female students did equally well on No Child Left Behind standardized tests that were administered in second through eleventh grades in ten states. However, Hyde and her team did find gaps that favored males at the upper end of the achievement distribution and tried to examine gaps on more difficult test questions (previous research has shown that males outperform females on more challenging items), but the tests they examined lacked adequately challenging items. This raised questions about whether there is still a gender gap in math achievement.^[10]

There is also a large discrepancy between the number of men and women working in STEM fields. Women have been, and continue to be, underrepresented in these fields. This underrepresentation is evident in the distribution of college majors among men and women; from 1997 to 2007, women earned only 18% of engineering bachelor’s degrees. ^[11]

Gender gap in graduation rates

According to recent data, 55 percent of college students are females and 45 percent are males. From 1995 until 2005, the number of males enrolled in college increased by 18 percent, while the number of female students rose by 27 percent.^[12] Males are enrolling in college in greater numbers than ever before, yet less than two-thirds of them are graduating with a bachelor’s degree. The numbers of both men and women receiving a bachelor’s degree have increased significantly, but the increasing rate of female college graduates exceeds the increasing rate for males.^[13] However, a higher proportion of men (29.4%) hold bachelor’s degrees than women (26.1%). In 2007, the United States Census Bureau estimated that 18,423,000 males ages over the age of 18 held a bachelor’s degree, while 20,501,000 females over the age 18 held one. In addition, fewer males held master’s degrees: 6,472,000 males compared to 7,283,000 females. However, more men held professional and doctoral degrees than women. 2,033,000 males held professional degrees compared to 1,079,000, and 1,678,000 males had received a doctoral degree compared to 817,000 females.^[14]

Although more women are graduating with undergraduate degrees, men are still earning disproportionately more in their lifetimes. This could be due to many factors, including different types of jobs for males and females. Females are greatly underrepresented in science and engineering fields, which are typically correlated with high lifetime earnings.^[15] Males and females also have vastly different labor market histories based on type of job and time spent in each job.

Possible causes of the gender achievement gap in the United States

Teacher interactions and evaluations

How a student interacts with and is evaluated by his or her teachers is closely correlated with that student’s future academic achievement. There are two competing views of how teachers can indirectly impact the achievement of their students. The first is that teachers are more likely to give special attention and extra assistance to students who appear to be struggling in their class. In reading and writing classes, male students are often behind female students in terms of achievement. Therefore, male students are more likely to get more teacher attention, and this extra interaction could give males an advantage in terms of future achievement. The second view is that teachers demand more and show more respect toward students who they view to be high achievers.^[16]

How teachers perceive students’ knowledge and abilities varies by gender and influences classroom processes and student achievement in both reading and math. Teachers usually have higher expectations for students they view as higher achievers and treat these students with more respect.^[16] Researchers have also found that when students are split into reading groups based on their abilities, the students in the higher-ability reading groups were more likely to demonstrate positive learning behaviors and higher achievement. Teachers are more likely to favor girls when evaluating what types of readers students seem to be. Because studies have shown that teacher perceptions of students can determine how much individualized attention a student receives and can serve as an indicator of future academic progress, if teachers underestimate males’ reading abilities and use ability grouping in their classrooms, male students might be put at a disadvantage and have their learning in reading classes be negatively affected.^[17][18] The opposite trend has been found in math classes. Teachers still tend to view math as a “masculine” subject and tend to have higher expectations for and better attitude towards their male students in these classes.^[19] Studies have also shown that teachers tend to name males when asked to list their “best math students.”^[20] Females are more likely than males to be negatively impacted than male students by this underestimation of their math abilities.^[21]

There is conflicting evidence about whether teacher assessments of student performance and ability are consistent with cognitive assessments like standardized tests. Teacher assessment evidence comes from a relatively small number of classrooms when compared to standardized tests, which are administered in every public school in all fifty states.^[22]

Stereotyping and parent socialization

Gender stereotyping within classrooms can also lead to differences in academic achievement and representation for female and male students. Math and science are often perceived as “masculine” subjects because they lead to success in “masculine” fields, such as medicine and engineering. English and history, on the other hand, are often perceived as “feminine” subjects because they are more closely aligned with “feminine” jobs, such as teaching or care work. These stereotypes can influence student achievement in these areas. Research on stereotype threat has shown that gender stereotypes decrease the mathematical self-esteem of many female students, and that this lack of academic confidence leads to anxiety and poorer performance on math exams.^[23] If self-esteem declines throughout a student’s schooling, the achievement gap between genders will increase.

How a child's parents view his or her skills can also contribute to the gender achievement gap in education. Studies have shown that adults rate female children as having better social skills than male children, and that girls are more likely to be seen as "good children" than boys. These gender-based stereotypes can perpetuate the gender achievement gap in education by influencing parents' perceptions of their childrens' skills, and these perceptions can influence the types of activities and subjects parents steer their children toward.^[24]

Implications of the gap

It is important to address the gender achievement gap in education because failure to cultivate the academic talents of any one group will have aggregate negative consequences. If women are underrepresented in STEM fields, and if men are underrepresented in the social sciences and humanities, both genders are missing opportunities to develop diverse skill sets that can help them in the workplace.^[25] If the gender achievement gap in education continues to exist, so does the stereotype that medicine, science, and engineering are all “masculine” fields and that women belong in fields like teaching, counseling, or social work. This stereotype can lead to the image that women who pursue careers in the STEM fields are seen as “nerdy” or “geeky,” and this can have a detrimental effect on the self-esteem of females who do choose to enter these fields. Researchers have found that the gender achievement gap has a large impact on the future career choices of high-achieving students. Part of this is a result of the college majors that men and women choose; men are more likely to major in engineering or the hard sciences, while women are more likely to receive degrees in English, psychology, or sociology. Therefore, men are statistically more likely to enter careers that have more potential for higher long-term earnings than women. The careers that are aligned with these majors have different levels of prestige and different salaries, which can lead to a gender wage gap. U.S. Census data indicates that women who work full-time earn only 77% of what their male counterparts earn. For men and women who are ten years out of college, women earn only 69% of the salaries of their male workers.^[11] The perpetuation of the gender achievement gap will also lead to the perpetuation of this gender wage gap.

Attempts to reduce the gap

Values affirmation

There have been several studies done of interventions aimed at reducing the gender achievement gap in science classes. Some interventions, such as instituting mentoring programs aimed at women or restructuring the course curriculum, have had limited success. The most successful interventions have been a form of psychological interventions called values affirmation. Values affirmation has been successful in reducing the differences between male and female academic achievement in college-level introductory physics classes. These exercises require students to either write about their most important values or their least important values two times at the beginning of the 15-week course. After this intervention, the modal grades of women enrolled in the course increased from a C to a B. Psychological interventions such as this one show promise for increasing women's achievement in math and science courses and reducing the achievement gap that exists between the genders in these subject areas, but further research will need to be done in order to determine whether the positive effects are long-lasting. ^[26]

See Also

References

1. Kafir, Krista (April 2007). "Taking the Boy Crisis in Education Seriously: How School Choice can Boost Achievement Among Boys and Girls." Independent Women's Forum.
2. Perie, M. (2005). NAEP 2004 Trends in Academic Progress. Washington, DC: US Department of Education.
3. Persky, H. (2003). The Nation's Report Card: Writing 2002. US Department of Education.
4. Salahu-Din, Debra (2008). The Nation's Report Card: Writing 2007. US Department of Education.
5. Dee, T. (2007). Teachers and the gender gaps in student achievement. The Journal of Human Resources, XLII(3), 1–28; Adeleke, M. (2007). Gender disparity in mathematical performance revisited: can training in problem solving bring difference between boys and girls?. Essays in Education, 21.
6. Amelink, C. (2009). Information sheet: gender differences in math performance . Assessing Women in Engineering, 1–4.
7. Dee, T. (2007). Teachers and the gender gaps in student achievement. The Journal of Human Resources, XLII(3), 1–28.
8. Lubienski, S. T., McGraw, R., & Strutchens, M. (2004). NAEP findings regarding gender: Mathematics achievement, student affect, and learning practices. In P. Kloosterman, & F. K. Lester Jr. (Eds.), Results and interpretations of the 1990 through 2000 mathematics assessments of the National Assessment of Educational Progress (pp. 305–336). Reston, VA: National Council of Teachers of Mathematics.
9. CollegeBoard.com. 2010. “SAT Percentile Rank or Males, Females, and Total Group, 2007 College-Bound Seniors—Mathematics.” A table. h t t p : // w w w . c o l l e g e b o a r d . c o m / p r o d _ d o w n l o a d s /highered/ra/sat/SAT_percentile_ranks _males_females_total_group_mathematics.pdf.
10. Hyde, J. S., Lindberg, S. M., Linn, M. C., Ellis, A. B., & Williams, C. C. (2008). Gender similarities characterize mathematics performance. Science, 321(5888), 494–495.
11. Dey, J. G., & Hill, C. (2007). Beyond the pay gap. Washington, DC: American Association of University Women Educational Foundation.
12. Digest of Education Statistics 2007
13. Mead, Sara. (2006). The Evidence Suggests Otherwise: The Truth About Boys and Girls. Washington: Education Sector.
14. U.S. Census Bureau, Current Population Survey, Annual Social and Economic Supplement 2007.
15. Bedard, Kelly and Insook Cho. (2010). Early gender test score gaps across OECD countries. Economics of Education Review, 29(1): 348-363.
16. Good, T. L. (1987). Two decades of research on teacher expectations: Findings and future directions. Journal of Teacher Education, 38(4), 32–47.
17. Tach, L. M., & Farkas, G. (2006). Learning-related behaviors, cognitive skills, and ability grouping when schooling begins. Social Science Research, 35(4), 1048–1079.
18. Nigro, G., M. Tappan, and S. Desrochers. (2008). The gender divide in academic engagement: Perspectives from Maine boys and young men. Report presented at the annual meeting of the Maine Boys Network conference, Bates College, Lewiston, ME.
19. Li, Q. (1999). Teachers’ beliefs and gender differences in mathematics: A review. Educational Research, 41(1), 63–76.
20. Fennema, E., Peterson, P. L., Carpenter, T. P., & Lubinski, C. (1990). Teachers’ attributions and beliefs about girls, boys, and mathematics. Educational Studies in Mathematics, 21(1), 55–69.
21. McKown, C., & Weinstein, R. S. (2002). Modeling the role of child ethnicity and gen- der in children’s differential response to teacher expectations. Journal of Applied Social Psychology, 32, 159–184.
22. Robinson, Joseph Paul and Sarah Theule Lubienski. (2010). The Development of Gender Achievement Gaps in Mathematics and Reading During Elementary and Middle School: Examining Direct Cognitive Assessments and Teacher Ratings. American Education Research Journal 48(268): 268-302.
23. Amelink, C. (2009). Information sheet: gender differences in math performance . Assessing Women in Engineering, 1–4.
24. Jacobs, Janis E. and Jacquelynne S. Eccles. (1992). The Impact of Mothers' Gender-Role Stereotypic Beliefs on Mothers' and Children's Ability Perceptions. Journal of Personality and Social Psychology 63(6): 932-944.
25. Ellison, Glenn and Ashley Swanson. (2010). The Gender Gap in Secondary School Mathematics at High Achievement Levels: Evidence from the American Mathematics Competitions. Journal of Economic Perspectives 24(2): 109-128.
26. Akira Miyake, Lauren E. Kost-Smith, Noah D. Finkelstein, Steven J. Pollock, Geoffrey L. Cohen, and Tiffany A. Ito. (2010). Reducing the Gender Achievement Gap in College Science: A Classroom Study of Values Affirmation. Science 330(6008): 1234-1237.