Sex differences in intelligence

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Differences in human intelligence have long been a topic of debate among researchers and scholars. With the advent of the concept of g factor or general intelligence, many researchers have argued that there are no significant sex differences in general intelligence,[1][2][3] although ability in particular types of intelligence does appear to vary.[3][4]

While some test batteries show slightly greater intelligence in males, others show slightly greater intelligence in females.[3][4] In particular, studies have shown female subjects performing better on tasks related to verbal ability,[2] and males performing better on tasks related to rotation of objects in space, often categorized as spatial ability.[5]

Some research indicates that male advantages on some cognitive tests are minimized when controlling for socioeconomic factors.[1][4] Other research has concluded that there is slightly larger variability in male scores in certain areas compared to female scores, which results in more males than females in the top and bottom of the IQ distribution.[6]

Historical perspectives[]

Prior to the 20th century, it was a commonly held view that men were intellectually superior to women.[7][8] In 1801, Thomas Gisborne said that women were naturally suited to domestic work and not spheres suited to men such as politics, science, or business. He stated that this was because women did not possess the same level of rational thinking that men did and had naturally superior abilities in skills related to family support.

In 1875, Herbert Spencer said that women were incapable of abstract thought and could not understand issues of justice and had only the ability to understand issues of care.[9] In 1925, Sigmund Freud also stated that women were less morally developed in the concept of justice and, unlike men, were more influenced by feeling than rational thought.[9] Early brain studies comparing mass and volumes between the sexes concluded that women were intellectually inferior because they have smaller and lighter brains.[10] Many believed that the size difference caused women to be excitable, emotional, sensitive, and therefore not suited for political participation.[11]

In the nineteenth century, whether men and women had equal intelligence was seen by many as a prerequisite for the granting of suffrage.[11] Leta Hollingworth argued that women were not permitted to realize their full potential, as they were confined to the roles of child-rearing and housekeeping.

During the early twentieth century, the scientific consensus shifted to the view that gender plays no role in intelligence.[12]

In his 1916 study of children's IQs, psychologist Lewis Terman concluded that "the intelligence of girls, at least up to 14 years, does not differ materially from that of boys". He did, however, find "rather marked" differences on a minority of tests. For example, he found boys were "decidedly better" in arithmetical reasoning, while girls were "superior" at answering comprehension questions. He also proposed that discrimination, lack of opportunity, women's responsibilities in motherhood, or emotional factors may have accounted for the fact that few women had careers in intellectual fields.[13][14]

Research on general intelligence[]

See also: Intelligence quotient

Background[]

Chamorro-Premuzic et al. stated, "The g factor, which is often used synonymously with general intelligence, is a latent variable which emerges in a factor analysis of various cognitive ('IQ') tests. They are not exactly the same thing. g is an indicator or measure of general intelligence; it's not general intelligence itself."[15]

All or most of the major tests commonly used to measure intelligence have been constructed so that there are no overall score differences between males and females. Thus, there is little difference between the average IQ scores of men and women.[16][17] Differences have been reported, however, in specific areas such as mathematics and verbal measures.[4][6][5] Also, studies have found the variability of male scores is greater than that of female scores, resulting in more males than females in the top and bottom of the IQ distribution.[6]

In favor of males or females in g factor[]

Research, using the Wechsler Adult Intelligence Scale (WAIS III and WAIS-R), that finds general intelligence in favor of males indicates a very small difference.[3] This is consistent across countries.[3] In the United States and Canada, the IQ points range from two to three points in favor of males, while the points rise to four points in favor of males in China and Japan.[3] By contrast, some research finds greater advantage for adult females.[4] For children in the United States and the Netherlands, there are one to two IQ point differences in favor of boys.[3] Other research has found a slight advantage for girls on the residual verbal factor.[3]

A 2004 meta-analysis by Richard Lynn and Paul Irwing published in 2005 found that the mean IQ of men exceeded that of women by up to 5 points on the Raven's Progressive Matrices test.[18][19] Lynn's findings were debated in a series of articles for Nature.[20] He argued that there is a greater male advantage than most tests indicate, stating that because girls mature faster than boys, and that cognitive competence increases with physiological age, rather than with calendar age, the male-female difference is small or negative prior to puberty, but males have an advantage after adolescence and this advantage continues into adulthood.[3]

In favor of no sex differences or inconclusive consensus[]

Most studies find either a very small difference in favor of males or no sex difference with regard to general intelligence.[3][21] In 2000, researchers Roberto Colom and conducted a large study of 10,475 adults on five IQ tests taken from the and found negligible or no significant sex differences. The tests conducted were on vocabulary, spatial rotation, verbal fluency and inductive reasoning.[21]

The literature on sex differences in intelligence has produced inconsistent results due to the type of testing used, and this has resulted in debate among researchers.[15] Garcia (2002) argues that there might be a small insignificant sex difference in intelligence in general (IQ) but this may not necessarily reflect a sex difference in general intelligence or g factor.[15] Although most researchers distinguish between g and IQ, those that argued for greater male intelligence asserted that IQ and g are synonymous (Lynn & Irwing 2004) and so the real division comes from defining IQ in relation to g factor. In 2008 Lynn and Irwing proposed that since working memory ability correlates highest with g factor, researchers would have no choice but to accept greater male intelligence if differences on working memory tasks are found. As a result, a neuroimaging study published by Schmidt (2009) conducted an investigation into this proposal by measuring sex differences on an n-back working memory task. The results found no sex difference in working memory capacity, thus contradicting the position put forward by Lynn and Irwing (2008) and more in line with those arguing for no sex differences in intelligence.[15] A later meta analysis of Raven's Progressive Matrices data featuring large, international datasets revealed no sex differences in performance.[22][23]

A 2012 review by researchers Richard E. Nisbett, Joshua Aronson, Clancy Blair, William Dickens, James Flynn, Diane F. Halpern and Eric Turkheimer discussed Arthur Jensen's 1998 studies on sex differences in intelligence. Jensen's tests were significantly g-loaded but were not set up to get rid of any sex differences (read differential item functioning). They summarized his conclusions as he quoted, "No evidence was found for sex differences in the mean level of g or in the variability of g. Males, on average, excel on some factors; females on others." Jensen's conclusion that no overall sex differences existed for g has been reinforced by researchers who analyzed this issue with a battery of 42 mental ability tests and found no overall sex difference.[24]

Although most of the tests showed no difference, there were some that did. For example, they found female subjects performed better on verbal abilities while males performed better on visuospatial abilities.[24] For verbal fluency, females have been specifically found to perform slightly better in vocabulary and reading comprehension and significantly higher in speech production and essay writing.[25] Males have been specifically found to perform better on spatial visualization, spatial perception, and mental rotation.[25] Researchers had then recommended that general models such as fluid and crystallized intelligence be divided into verbal, perceptual and visuospatial domains of g; this is because, as this model is applied, females excel at verbal and perceptual tasks while males excel on visuospatial tasks, thus evening out the sex differences on IQ tests.[24]

Variability[]

Main article: Variability hypothesis

Some studies have identified the degree of IQ variance as a difference between males and females. Males tend to show greater variability on many traits; for example having both highest and lowest scores on tests of cognitive abilities.[6][5]

Feingold (1992b) and Hedges and Nowell (1995) have reported that, despite average sex differences being small and relatively stable over time, test score variances of males were generally larger than those of females."[26] Feingold "found that males were more variable than females on tests of quantitative reasoning, spatial visualisation, spelling, and general knowledge. ... Hedges and Nowell go one step further and demonstrate that, with the exception of performance on tests of reading comprehension, perceptual speed, and associative memory, more males than females were observed among high-scoring individuals."[26]

Brain and intelligence[]

See also: Neuroscience of sex differences

Differences in brain physiology between sexes do not necessarily relate to differences in intellect. Although men have larger brains, men and women have equal IQs and are equal in IQ scores.[27] For men, the gray matter volume in the frontal and parietal lobes correlates with IQ; for women, the gray matter volume in the frontal lobe and Broca's area (which is used in language processing) correlates with IQ.[28]

Women have greater cortical thickness, cortical complexity and cortical surface area (controlling for body size) which compensates for smaller brain size.[29] Meta-analysis and studies have found that brain size explains 6–12% of variance among individual intelligence and cortical thickness explains 5%.[30]

Mathematics performance[]

Girl scouts compete in the USS California Science Experience at Naval Surface Warfare. In 2008, the National Science Foundation reported that, on average, girls perform as well as boys on standardized math tests, while boys are overrepresented on both ends of the spectrum.

Across countries, males have performed better on mathematics tests than females, but the male-female difference in math scores is related to gender inequality in social roles.[31] In a 2008 study paid for by the National Science Foundation in the United States, researchers stated that "girls perform as well as boys on standardized math tests. Although 20 years ago, high school boys performed better than girls in math, the researchers found that is no longer the case. The reason, they said, is simple: Girls used to take fewer advanced math courses than boys, but now they are taking just as many."[32][33] However, the study indicated that, while boys and girls performed similarly on average, boys were over-represented among the very best performers as well as among the very worst.[34]

A small performance difference in mathematics on the SAT[35] persists in favor of males, though the gap has shrunk from 40 points (5.0%) in 1975[36] to 18 points (2.3%) in 2020.[37] However, the SAT is not a representative sample, given that it tests only college-bound students, and more women than men have attended college since the 1990s.[38] Conversely, the international PISA exam provides representative samples. On the 2018 math PISA, there was no statistically significant difference between the performances of girls and boys in 39.5% of the 76 countries that participated. Meanwhile, boys outperformed girls in 32 countries (42.1%), while girls outperformed boys in 14 (18.4%).[39] On average, boys performed 5 points (1%) higher than girls. However, overall, the gender gap in math and science for boys and girls from similar socio-economic backgrounds was not significant.[39]

A 2008 meta-analysis published in Science using data from over 7 million students found no statistically significant differences between the mathematical capabilities of males and females.[40] A 2011 meta-analysis with 242 studies from 1990 to 2007 involving 1,286,350 people found no overall sex difference of performance in mathematics. The meta-analysis also found that although there were no overall differences, a small sex difference that favored males in complex problem solving was still present in high school. However, the authors note that boys continue to take more physics courses than girls, which train complex solving abilities and may provide stronger training than pure mathematics.[41]

Researchers also note that differences in mathematics course performance measures favor females.[42]

With regard to gender inequality, some psychologists believe that many historical and current sex differences in mathematics performance may be related to boys' higher likelihood of receiving math encouragement than girls. Parents were, and sometimes still are, more likely to consider a son's mathematical achievement as being a natural skill while a daughter's mathematical achievement is more likely to be seen as something she studied hard for.[43] This difference in attitude may contribute to girls and women being discouraged from further involvement in mathematics-related subjects and careers.[43]

Stereotype threat has been shown to affect performance and confidence in mathematics of both males and females.[10][42]

Reading and verbal skills[]

Studies have shown a female advantage in reading and verbal skills.[2] On the international PISA reading exam, girls consistently outperform boys across all countries, and all differences are statistically significant. In the most recent PISA exam (2018), girls outperformed boys by almost 30 points.[44] On average in OECD countries, 28% of boys did not obtain a reading proficiency level of 2.

Studies have shown that girls spend more time reading than boys and read more for fun, likely contributing to the gap.[45]

Spatial ability[]

Examples of figures from mental rotation tests.
A man playing a video game at the Japan Media Arts Festival. Spatial abilities can be affected by experiences such as playing action video games, complicating research on sex differences in spatial abilities.

Meta-studies show a male advantage in mental rotation, assessing horizontality and verticality, and a male advantage for most aspects of spatial memory.[46][47][48] A number of studies have shown that women tend to rely more on visual information than men in a number of spatial tasks related to perceived orientation.[49] Women have an advantage for certain components of spatial memory. Whereas men show a selective advantage for fine-grained metric positional reconstruction, where absolute spatial coordinates are emphasized, women show an advantage in spatial location memory, which is the ability to accurately remember relative object positions (where objects are);[47][50][51] however, the advantage in spatial location memory is small and inconsistent across studies.[51]

A proposed evolutionary hypothesis is that men and women evolved different mental abilities to adapt to their different roles, including labor-based roles, in society.[51][52] For example, "ancestral women more often foraged for fruits, vegetables, and roots over large geographic regions."[51] The labor-based role explanation suggests that men may have evolved greater spatial abilities as a result of behaviors such as navigating during a hunt.[53]

Results from studies conducted in the physical environment are not conclusive about sex differences. Various studies on the same task show no differences. There are studies that show no difference in finding one's way between two places.[54]

Performance in mental rotation and similar spatial tasks is affected by gender expectations.[10][55] For example, studies show that being told before the test that men typically perform better, or that the task is linked with jobs like aviation engineering typically associated with men versus jobs like fashion design typically associated with women, will negatively affect female performance on spatial rotation and positively influence it when subjects are told the opposite.[56]

Experiences such as playing video games also significantly increase a person's mental rotation ability.[54] Playing action video games in particular benefits spatial abilities in women more than in men, up to a point where gender differences in spatial attention are eliminated.[57] The action video games (e.g. First-person shooters) studied in this context are currently not preferred by female players.[citation needed]

The possibility of testosterone and other androgens as a cause of sex differences in psychology has been a subject of study, but results have been mixed. A meta-analysis of women who were exposed to unusually high levels of androgens in the womb due to congenital adrenal hyperplasia concluded that there is no evidence of enhanced spatial ability among these individuals.[58] The meta-analysis speculates that average sex differences in some spatial tasks could be partially explained by androgen exposure at a different time of the life span, such as during mini-puberty, or by the different socialization males and females experience.[58] In addition, a meta-analysis showed that, although female-to-male transgender individuals who received testosterone therapy did improve their spatial abilities, male-to-female transgender individuals who took androgen-suppressants also showed an improvement or no deterioration of spatial skills.[59]

Sex differences in academics[]

A 2014 meta-analysis of sex differences in scholastic achievement published in the journal of Psychological Bulletin found females outperformed males in teacher-assigned school marks throughout elementary, junior/middle, high school and at both undergraduate and graduate university level.[60] The meta-analysis, done by researchers Daniel Voyer and Susan D. Voyer from the University of New Brunswick, drew from 97 years of 502 effect sizes and 369 samples stemming from the year 1914 to 2011.[60]

Beyond sex differences in academic ability, recent research has also been focusing on women's underrepresentation in higher education, especially in the fields of natural science, technology, engineering and mathematics (STEM).[61]

See also[]

References[]

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