Women in engineering

Last updated
A female engineer working on an optical communications system test. Working at an optical communications system testbed.jpg
A female engineer working on an optical communications system test.

Women are often under-represented in the academic and professional fields of engineering; however, many women have contributed to the diverse fields of engineering historically and currently. [1] A number of organizations and programs have been created to understand and overcome this tradition of gender disparity. Some have decried this gender gap, saying that it indicates the absence of potential talent. [1] Though the gender gap as a whole is narrowing, there is still a growing gap with minority women compared to their white counterparts. [1] Gender stereotypes, low rates of female engineering students, and engineering culture are factors that contribute to the current situation where men dominate in fields relating to engineering sciences.

Contents

History

The history of women as designers and builders of machines and structures predates the development of engineering as a profession. Prior to the creation of the term "engineer" in the 14th century, women had contributed to the technological advancement of societies around the globe. By the 19th century, women who participated in engineering work often had academic training in mathematics or science. Ada Lovelace was privately schooled in mathematics before beginning her collaboration with Charles Babbage on his analytical engine that would earn her the designation of the "first computer programmer." In the early years of the 20th century, greater numbers of women began to be admitted to engineering programs, but they were generally looked upon as anomalies by the men in their departments.

A 1953 Society of Women Engineers board meeting. Society of Women Engineers 1953.jpg
A 1953 Society of Women Engineers board meeting.

The first University to award an engineering's bachelor's degree for women was University of California, Berkeley. Elizabeth Bragg was the recipient of a bachelor's degree in civil engineering in 1876, becoming the first female engineer in the United States. [2] Prior to the 19th century, it was very rare for women to earn bachelor's degree in any field because they did not have the opportunity to enroll in universities due to gender disparities. Some universities started to admit women to their colleges by the early 1800s and by the mid-1800s they started to admit them into all academic programs including engineering. [2]

In the United States, the entry into World War II created a serious shortage of engineering talent, as men were drafted into the armed forces. To address the shortage, initiatives like General Electric on-the-job engineering training for women with degrees in mathematics and physics and the Curtiss-Wright Engineering Program among others created new opportunities for women in engineering. Curtiss-Wright partnered with Cornell, Penn State, Purdue, the University of Minnesota, the University of Texas, Rensselaer Polytechnic Institute and Iowa State University to create an engineering curriculum that lasted ten months and focused primarily on aircraft design and production. [3]

During this time, there were few public attacks on female engineers. Chiefly, these attacks were kept quiet inside institutions due to the fact that women did not pressure aggressively to shift the gender gap between men and women in the engineering field. Another reason why these “attacks” were kept private is due to how men believed that it was impossible for engineering to stop being a male-dominated field. [4]

Women's roles in the workforce, specifically in engineering fields, changed greatly during the Post–World War II period. As women started to marry at later ages, have fewer children, divorce more frequently and stopped depending on male breadwinners for economic support, they started to become even more active in the engineering labor force despite the fact that their salaries were less than men's. [5]

Women also played a crucial role in programming the ENIAC from its construction during the World War II period through the next several decades. Originally recruited by the Army in 1943, female ENIAC programmers made considerable advancements in programming techniques, such as the invention of breakpoints, now a standard debugging tool. [6]

In addition to the wartime shortage of engineers, the number of women in engineering fields grew due to the gradual increase of public universities admitting female students. [7] For example, Georgia Tech began to admit women engineering students in 1952, while the École Polytechnique in Paris, a premier French engineering institution, began to admit female students in 1972.

As a result, gender stereotypical roles have changed due to industrialization resolution.

Factors contributing to lower female participation

Gender stereotypes

Stereotype threat may contribute to the under-representation of women in engineering. [8] Because engineering is a traditionally male-dominated field, women may be less confident about their abilities, even when performing equally. [9] At a young age, girls do not express the same level of interest in engineering as boys, possibly due in part to gender stereotypes. [10] There is also significant evidence of the remaining presence of implicit bias against female engineers, due to the belief that men are mathematically superior and better suited to engineering jobs. [10] The Implicit Association Test (IAT) shows that people subconsciously connect men with science and women with art, according to the results from over half a million people around the world between 1998 and 2010. This unconscious stereotype also has negative impact on the performance for women. [11] Women who persist are able to overcome these difficulties, enabling them to find fulfilling and rewarding experiences in the engineering profession. [12]

Due to this gender bias, women's choice in entering an engineering field for college is also highly correlated to the background and exposure they have had with mathematics and other science courses during high school. Most women that do choose to study engineering regard themselves as better at these types of courses and as a result, they are capable of studying in a male-dominated field. [13]

Women's self-efficacy is also a contributor to the gender stereotype that plays a role in the underrepresentation of women in engineering. Women's ability to think that they can be successful and perform well is correlated to the choices they make when choosing a college career. Women that show high self-efficacy personalities are more likely to choose to study in the engineering field. Self-efficacy is also correlated to gender roles because men often present higher self-efficacy than women, which can also be why when choosing a major most women opt to not choose the engineering major. [13]

Lower rates of female students in engineering degree programs

Over the past few years, 40% of women have left the engineering field. There are many factors leading to this, such as being judged about going into a difficult major such as engineering, or working in difficult workplace conditions. According to the Society of Women Engineers [14] one in four females leave the field after a certain age.

Women are under-represented in engineering education programs as in the workforce (see Statistics). Enrollment and graduation rates of women in post-secondary engineering programs are very important determinants of how many women go on to become engineers. Because undergraduate degrees are acknowledged as the "latest point of standard entry into scientific fields", the under-representation of women in undergraduate programs contributes directly to under-representation in scientific fields. [15] Additionally, in the United States, women who hold degrees in science, technology, and engineering fields are less likely than their male counterparts to have jobs in those fields. [16]

This degree disparity varies across engineering disciplines. Women tend to be more interested in the engineering disciplines that have societal and humane developments, such as agricultural and environmental engineering. They are therefore well-represented in environmental and biomedical engineering degree programs, receiving 40-50% of awarded degrees in the U.S. (2017–18), and are far less likely to receive degrees in fields like mechanical, electrical and computer engineering. [16] [17]

A study by the Harvard Business Review discussed the reasons why the rate of women in the engineering field is still low. The study discovered that rates of female students in engineering programs are continuous because of the collaboration aspects in the field. The results of the study chiefly determined how women are treated differently in group works in which there are more male than female members and how male members “excluded women from the real engineering work”. Aside from this, women in this study also described how professors treated female students differently “just because they were women”. [18]

Despite the fact that fewer women enroll in engineering programs across the nation, the representation of women in STEM-based careers can increase when college and university administrators work on implementing mentoring programs and work-life policies for women. Research shows that these rates are difficult to increase since women are judged as less competent than men to perform supposedly “masculine jobs”. [19]

Engineering culture

Autodidact computer chip designer and inventor, Jeri Ellsworth, at the Bay Area "Maker Faire" in 2009. 2009 Bay Area Maker Faire - Jeri.jpg
Autodidact computer chip designer and inventor, Jeri Ellsworth, at the Bay Area "Maker Faire" in 2009.

Another possible reason for lower female participation in engineering fields is the prevalence of values associated with the male gender role in workplace culture. [17] For example, some women in engineering have found it difficult to re-enter the workforce after a period of absence. Because men are less likely to take time off to raise a family, this disproportionately affects women. [20]

Men are also associated with taking leadership roles in the workplace. By holding a position of power over women, they may create an uncomfortable environment for them. For example, women may receive lower pay, more responsibilities, or less appreciation as compared to men. However, women may have more potential to become good leaders: studies have indicated that women have more key leadership skills; for example, the ability to motivate employees, build relationships, and take initiative. [21]

Communication is also a contributing factor to the divide between men and women in the workplace. Male-to-male communication is said to be more direct, [22] but when men explain a task to a women, they tend to talk down, or “dumb down” terms. This comes from the stereotype that men are more qualified than women, and can cause men to treat women as inferiors instead of equals. Other typically masculine traits, such as workplace sexual harassment and creating a hostile work environment also certainly contribute to this atmosphere of domineering attitudes towards women.

Part of the male dominance in the engineering field is explained by their perception towards engineering itself. A study in 1964 found that both women and men believed that engineering was masculine in nature. [23]

Over the past several decades, women's representation in the workforce in STEM fields, specifically engineering, has slowly improved. In 1960, women made up around 1% of all engineers, and by the year 2000, women made up 11% of all engineers, for an increase of 0.25 percentage points per year. At this rate, one would not expect 50-50 gender parity in engineering to occur until the year 2156. [19]

Several colleges and universities nationwide are attempting to decrease the gender gap between men and women in the engineering field by recruiting more women into their programs. Their strategies include increasing women's exposure to STEM courses during high school, planting the idea of a positive outlook on female participation from the engineering culture, and producing a more female-friendly environment inside and outside the classroom. These strategies have helped institutions encourage more women to enroll in engineering programs as well as other STEM-based majors. For universities to encourage women to enroll in their graduate programs, institutions have to emphasize the importance of recruiting women, emphasize the importance of STEM education at the undergraduate level, offer financial aid, and develop more efficient methods for recruiting women to their programs. [24]

Statistics

Percentage of female undergraduate students with engineering degree in India, Australia, Canada, the UK, and US [17] [25] [26] [27] [28]
Country % of womenyear
Australia14%2010
Canada21.8%2017
India29.7%2018
United Kingdom17.57%2016-2017
United States19.7%2015-2016

United States

In 2014, there were 7.9% female freshmen among all first-year students planning to study in STEM (science, technology, engineering, and mathematics) related majors. In comparison, 26.9% male freshmen intended to major in STEM. For female students who chose engineering, over 32% decided to switch to a different major. [29]

Since 1997, the percentage of Asian females enrolling in engineering majors has risen from about 30% to 34% but somehow also dropped in 2002. African American females have increased their representation in engineering from 21% to 33% in the same time frame. Mexican American and Puerto Rican females have had an increase in their representation from 25% to 31%. Even if ethnicities are included in these statistics, men from all ethnicities still outnumber the proportion of women who enroll in engineering bachelor programs. [24]

The percentage of master's degrees awarded to women has not changed much from 2003 (22.3%) to 2012 (23.1%). [30] The percentage of doctoral degrees awarded to women in engineering increased from 11.6% in 1995, to 17.4% in 2004, [31] to 21.1% in 2008, [32] then to 22.2% in 2012. [30]

There is a significant drop-off rate regarding the number of women who earn a bachelor's degree and the women who afterward enroll in graduate school. Over the last 35 years, women have been more likely than men to enroll in graduate school right after receiving their bachelor's degree. Women who do not enroll in a graduate program right after earning their bachelor's degree tend to be caregivers who face work-family conflicts in the context of family women. [33] The workforce remains the area of lowest representation for women. There were 13% female engineers in 2016. Usually, the salary of female engineers is 10% less than male engineers. [29] The retention of female engineers is also disproportionally low; in 2006, 62.6% of qualified male engineers were employed in engineering professions, as opposed to 47.1% of qualified female engineers. [34]

Female engineering students in class Female engineers in school.jpg
Female engineering students in class

Canada

Though women tend to make up more than half of the undergraduate population in Canada, the number of women in engineering is disproportionately low. [35] In 2017, 21.8% of undergraduate engineering students were women, and 20.6% of undergraduate engineering degrees were awarded to women. [36] The enrollment of women in engineering climbed from 16% in 1991 to over 20% in 2001, but by 2009 this number had fallen to 17%. [35] One commentator attributed this drop to a number of factors, such as the failure of higher education programs to explain how engineering can improve others' lives, a lack of awareness of what engineers do, lack of networking opportunities and discomfort of being in a male-dominated environment and the perception that women must adapt to fit in. [35]

In the 1990s, undergraduate enrollment of women in engineering fluctuated from 17% to 18%, while in 2001, it rose to 20.6%. [37] In 2010, 17.7% of students in undergraduate engineering were women. [38]

2016 percentage of women enrolled in tertiary education programs in Canada [38]
ProvinceUndergraduateGraduateDoctoral
Alberta 22%23.3%23.3%
British Columbia 16.5%27.5%27.5%
Manitoba 16%22.9%22.9%
New Brunswick 15.9%19.3%19.3%
Newfoundland and Labrador 20.9%20.6%20.6%
Northwest Territories
Nova Scotia 18.7%15.8%15.8%
Nunavut
Ontario 17.7%21.4%21.4%
Prince Edward Island
Quebec 16.3%20.4%20.4%
Saskatchewan 19%27.9%27.9%
Yukon Territory
Canada17.7%21.9%21.9%

In 2017, the disciplines with the highest proportion of undergraduates who are women were environmental, biosystems, and geological engineering. [38] Four out of the five disciplines with the largest percentages of undergraduate who are women were also the disciplines with the fewest overall undergraduate students enrolled. The lowest proportion of women were found in mechanical (14.2%), software (14.6%), and computer engineering (14.8%). [39]

The number of women enrolled in undergraduate, graduate, and doctoral engineering programs tends to vary by province, with the proportion in Newfoundland and Labrador, Prince Edward Island, and Alberta. [39]

The percentage of engineering faculty who are women increased from 13.4% in 2013 to 15.5% in 2017. [38] The University of Toronto has the highest number of female professors in Canada (21) and École Polytechnique de Montréal (18), University of Waterloo (17) and the University of British Columbia (16). [38]

CCWE1992 goals for 1997 and actual 2009 percentage of women involved in engineering in Canada [40]
Women in...19972009
1st year undergraduate25-25%
Undergraduate programs17.4%
Master's studies20%24.1%
Doctoral studies10%22%
Faculty members: professors5%Full: 7%
Associate: 11%
Assistant: 18%
Eng. degree graduates18%17.6%
Profession10.4%

In 2011, the INWES (International Network of Women Engineers and Scientists) Education and Research Institute (ERI) held a national workshop, Canadian Committee of Women in Engineering (CCWE+20), to determine ways of increasing the number of women in the engineering field in Canada. [41] CCWE+20 identified a goal of increasing women's interest in engineering by 2.6% by 2016 to a total of 25% through more incentives such as through collaboration and special projects. [41] The workshop identifies early education as one of the main barriers in addition to other factors, such as: "the popular culture of their generation, the guidance they receive on course selection in high school and the extent to which their parents, teachers, and counsellors recognize engineering as an appropriate and legitimate career choice for women." [41] The workshop report compares enrollment, teaching, and professional statistics from the goals identified in 1997 compared to the actual data from 2009, outlining areas of improvement (see table, right).

United Kingdom

According to the Women's Engineering Society's statistics document, 12.37% of engineers in the UK are female in 2018. 25.4% of females from 16 to 18 years old plan to have a career in the engineering field, compared to 51.9% of males from the same age group. [42]

The Royal Academy of Engineering reported in 2020 that the gender pay gap in the engineering profession is smaller than the average for all UK employment. The mean (10.8%) and median (11.4%) pay gap for engineers in the sample analysed is around two thirds the national average. [43] In 2017, the average salary for female engineers across all engineering fields was £38,109, whereas the average salary for male engineers across all fields was £48,866. The industry average salary is £48,000 [44]

The 2016 Hollywood film Hidden Figures follows three African American women engineers' work at NASA in 1960. The film was nominated for the 89th Academy Award for Best Picture. In 2019, Mary Robinette Kowal published SF novel The Calculating Stars , which also tells the story of women engineers working in NASA around the same period. The novel received Nebula Award for Best Novel and Hugo Award for Best Novel.


See also

Related Research Articles

Achievement gaps in the United States are observed, persistent disparities in measures of educational performance among subgroups of U.S. students, especially groups defined by socioeconomic status (SES), race/ethnicity and gender. The achievement gap can be observed through a variety of measures, including standardized test scores, grade point average, dropout rates, college enrollment, and college completion rates. The gap in achievement between lower income students and higher income students exists in all nations and it has been studied extensively in the U.S. and other countries, including the U.K. Various other gaps between groups exist around the globe as well.

<span class="mw-page-title-main">Maria Klawe</span> Canadian-American computer scientist

Maria Margaret Klawe is a computer scientist and the fifth president of Harvey Mudd College. Born in Toronto in 1951, she became a naturalized U.S. citizen in 2009. She was previously Dean of the School of Engineering and Applied Science at Princeton University. She is known for her advocacy for women in STEM fields.

<span class="mw-page-title-main">Women in science</span> Contributions of women to the field of science

The presence of women in science spans the earliest times of the history of science wherein they have made significant contributions. Historians with an interest in gender and science have researched the scientific endeavors and accomplishments of women, the barriers they have faced, and the strategies implemented to have their work peer-reviewed and accepted in major scientific journals and other publications. The historical, critical, and sociological study of these issues has become an academic discipline in its own right.

<span class="mw-page-title-main">Science, technology, engineering, and mathematics</span> Group of academic disciplines

Science, technology, engineering, and mathematics (STEM) is an umbrella term used to group together the distinct but related technical disciplines of science, technology, engineering, and mathematics. The term is typically used in the context of education policy or curriculum choices in schools. It has implications for workforce development, national security concerns, and immigration policy, with regard to admitting foreign students and tech workers.

Historically, women in the United States have been represented at lower rates than men in both science and engineering college programs and careers. Over time, this pattern has led to a significantly higher concentration of male professional engineers compared to women. Additionally, this disparity has led to careers in Education, History, English, Humanities and the like to be seen as "feminine" careers and areas of study. Some Feminist theorists suggest that these social and historical factors have perpetuated women's low participation rates in engineering over time. Numerous explanations and points of view have been offered to explain women's participation rates in this field. These explanations include beliefs regarding women's lack of interest in science and engineering, their physiological inability to succeed as engineers, and environmental factors in women's childhoods that discourage them from entering science and engineering fields.

<span class="mw-page-title-main">Sex differences in education</span> Educational discrimination on the basis of sex

Sex differences in education are a type of sex discrimination in the education system affecting both men and women during and after their educational experiences. Men are more likely to be literate on a global average, although higher literacy scores for women are prevalent in many countries. Women are more likely to achieve a tertiary education degree compared to men of the same age. Men tended to receive more education than women in the past, but the gender gap in education has reversed in recent decades in most Western countries and many non-Western countries.

<span class="mw-page-title-main">Feminisation of the workplace</span> The trend towards broader inclusive modes of working

The feminization of the workplace is the feminization, or the shift in gender roles and sex roles and the incorporation of women into a group or a profession once dominated by men, as it relates to the workplace. It is a set of social theories seeking to explain occupational gender-related discrepancies.

<span class="mw-page-title-main">Sexism in academia</span> Discrimination in higher education

Sexism in academia refers to the discrimination and subordination of a particular sex or gender academic institutions, particularly universities, due to the ideologies, practices, and reinforcements that privilege one sex or gender over another. Sexism in academia is not limited to but primarily affects women who are denied the professional achievements awarded to men in their respective fields such as positions, tenure and awards. Sexism in academia encompasses institutionalized and cultural sexist ideologies; it is not limited to the admission process and the under-representation of women in the sciences but also includes the lack of women represented in college course materials and the denial of tenure, positions and awards that are generally accorded to men.

<span class="mw-page-title-main">Women in STEM fields</span> Female participants in science, technology, engineering, and mathematics

Many scholars and policymakers have noted that the fields of science, technology, engineering, and mathematics (STEM) have remained predominantly male with historically low participation among women since the origins of these fields in the 18th century during the Age of Enlightenment.

Many in Canada share concerns about the current and future roles of women in computing, especially as these occupations increase in importance. As in many nations where computing and information technology are large industries, women in Canada have historically faced underrepresentation in education and industry. As a result, some Canadian women pursuing careers in these fields have had a lack of role models and faced sexism. There are many institutions and initiatives in Canada, however, which seek to increase representation for women in computing fields, as well as the fields of natural science and engineering in general.

Gender inequality in the United States has been diminishing throughout its history and significant advancements towards equality have been made beginning mostly in the early 1900s. However, despite this progress, gender inequality in the United States continues to persist in many forms, including the disparity in women's political representation and participation, occupational segregation, and the unequal distribution of household labor. The alleviation of gender inequality has been the goal of several major pieces of legislation since 1920 and continues to the present day. As of 2021, the World Economic Forum ranks the United States 30th in terms of gender equality out of 149 countries.

<span class="mw-page-title-main">Women's education in Iran</span>

Formal education for women in Iran began in 1907 with the establishment of the first primary school for girls. Education held an important role in Iranian society, especially as the nation began a period of modernization under the authority of Reza Shah Pahlavi in the early 20th century when the number of women's schools began to grow. By mid-century, legal reforms granting women the right to vote and raising the minimum age for marriage offered more opportunities for women to pursue education outside the home. After periods of imposed restrictions, women's educational attainment continued its rise through the Islamification of education following the Iranian Revolution of 1979, peaking in the years following radical changes in the curriculum and composition of classrooms. By 1989, women dominated the entrance examinations for college attendance.

<span class="mw-page-title-main">Gender disparity in computing</span> Imbalance

Gender disparity in computing concerns the disparity between the number of men in the field of computing in relation to the lack of women in the field. Originally, computing was seen as a female occupation. As the field evolved, so too did the demographics, and the gender gap shifted from female dominated to male dominated. The believed need for more diversity and an equal gender gap has led to public policy debates regarding gender equality. Many organizations have sought to create initiatives to bring more women into the field of computing.

Sex differences in education in the United States refers to the specific issues, such as gender-based discrimination related to coursework and use of disciplinary action, that American students of all genders encounter. Furthermore, while sex differences in education explains the prevalence of gender-based differences in education on a global scale, the American education system includes specific forms of gender discrimination dissimilar to other countries.

<span class="mw-page-title-main">Female education in STEM</span>

Female education in STEM refers to child and adult female representation in the educational fields of science, technology, engineering, and mathematics (STEM). In 2017, 33% of students in STEM fields were women.

<span class="mw-page-title-main">Gender-equality paradox</span> Concept in psychology and sociology

The gender-equality paradox is the finding that various gender differences in personality and occupational choice are larger in more gender equal countries. Larger differences are found in Big Five personality traits, Dark Triad traits, self-esteem, depression, personal values, occupational and educational choices. This phenomenon is seemingly paradoxical because one would expect the differences to be reduced as countries become more gender egalitarian. Such a paradox has been discussed by numerous studies ranging from science, mathematics, reading, personality traits, basic human values and vocational interests.

Women are under-represented in the economics profession worldwide. This has wide social and material implications, as economists work in banks and government, and have a direct role in policy making. Studies have shown that decisions made and executed by diverse teams delivered 60% better results. While many other fields, including STEM fields, have seen growth in the share of professors and students who are women, economics has stagnated with little improvement at any level in the last 15 years.

Sapna Cheryan is an American social psychologist. She is a Full professor of social psychology in the Department of Psychology at the University of Washington.

Identity safety cues are aspects of an environment or setting that signal to members of stigmatized groups that the threat of discrimination is limited within that environment and / or that their social identities are welcomed and valued. Identity safety cues have been shown to reduce the negative impacts impact of social identity threats, which are when people experience situations where they feel devalued on the basis of a social identity. Such threats have been shown to undermine performance in academic and work-related contexts and make members of stigmatized groups feel as though they do not belong. Identity safety cues have been proposed as a way of alleviating the negative impact of stereotype threat or other social identity threats, reducing disparities in academic performance for members of stigmatized groups, and reducing health disparities caused by identity related stressors.

According to the National Science Foundation (NSF), women and racial minorities are underrepresented in science, technology, engineering, and mathematics (STEM). Scholars, governments, and scientific organizations from around the world have noted a variety of explanations contributing to this lack of racial diversity, including higher levels of discrimination, implicit bias, microaggressions, chilly climate, lack of role models and mentors, and less academic preparation.

References

  1. 1 2 3 MentorNet (2003). The Underrepresentation of Women in Engineering and Related Sciences: Pursuing Two Complementary Paths to Parity. National Academies Press.
  2. 1 2 Society of Women Engineers Blog. "History of Women Engineers". All Together Society Of Women Engineers. Society of Women Engineers. Archived from the original on 1 December 2017. Retrieved 10 November 2017.
  3. Bix, Amy Sue, "'Engineeresses' Invade Campus: Four decades of debate over technical coeducation." IEEE Technology and Society Magazine, Vol. 19 Nr. 1 (Spring 2000), 21.
  4. Bix, Amy Sue (2013). Girls coming to tech! : a history of American engineering education for women. Cambridge, Mass.: MIT Press. pp.  14–43. ISBN   9780262019545.
  5. Yang, Juemei (2016). The impact of power status on gender stereotypes, sexism, and gender discrimination toward women in the workplace and the career identity development of women. University of North Dakota: University of North Dakota. pp. 1–20.
  6. Abbate, Janet. "Recoding Gender: Women's Changing Participation in Computing". MIT Press.
  7. Thompson, Clive (2019-02-13). "The Secret History of Women in Coding". New York Times . Retrieved 2019-02-13.
  8. Carter, Ruth (1989-12-01). Women in Engineering: A Good Place To Be?. Macmillan International Higher Education. ISBN   978-1-349-20409-0.
  9. Jones, Brett D.; Ruff, Chloe; Paretti, Marie C. (2013). "The impact of engineering identification and stereotypes on undergraduate women's achievement and persistence in engineering". Social Psychology of Education. 16 (3): 471–493. doi:10.1007/s11218-013-9222-x. S2CID   144031559.
  10. 1 2 Hill, Catherine; Corbett, Christine; St. Rose, Andresse (2010). "Why So Few?: Women in Science, Technology, Engineering and Mathematics" (PDF). AAUW.
  11. "Why So Few? Women in Science, Technology, Engineering, and Mathematics". AAUW: Empowering Women Since 1881. Retrieved 2019-10-03.
  12. Buse, Kathleen; Bilimoria, Diana; Perelli, Sheri (2013). "Why they stay: women persisting in US engineering careers". Career Development International. 18 (2): 139–154. doi:10.1108/CDI-11-2012-0108.
  13. 1 2 Blaisdell, Stephanie (1994). "Factors In The Underrepresentation Of Women In Science and Engineering: A Review Of The Literature". Penn State University : 167–168. Retrieved 17 November 2017.
  14. Adams, Rebecca (2014-08-12). "40 Percent Of Female Engineers Are Leaving The Field. This Might Be Why". Huffington Post . Retrieved 2018-05-04.
  15. Fox, Mary; Sonnert, Gerhard; Nikiforova, Irina (2011). "Programs for Undergraduate Women in Science and Engineering: Issues, Problems, and Solutions". Gender & Society . 25 (5): 591. doi:10.1177/0891243211416809. S2CID   145693091.
  16. 1 2 Yoder, Brian L. (2018). "Engineering by the Numbers" (PDF). American Society for Engineering Education.{{cite journal}}: Cite journal requires |journal= (help)
  17. 1 2 3 Franzway, Suzanne; Sharp, Rhonda; Mills, Julie E; Gill, Judith (2009). "Engineering Ignorance: The Problem of Gender Equity in Engineering". Frontiers: A Journal of Women Studies. 30 (1): 90. doi:10.1353/fro.0.0039. S2CID   144127186.
  18. Silbey, Susan S. (23 August 2016). "Why Do So Many Women Who Study Engineering Leave the Field?". Harvard Business Review . Retrieved 17 November 2017.
  19. 1 2 Hill, Ph.D., Catherine; Corbett, Christiane; St. Rose, Ed.D., Andresse (2010). Why So Few?: Women In Science, Technology, Engineering and Mathematics. AAUW. ISBN   9781879922402.{{cite book}}: |website= ignored (help)
  20. Evetts, Julia (1993). "Women and management in engineering: The 'glass ceiling' for". Women in Management Review. 8 (7). doi:10.1108/09649429310046391.
  21. Zenger, Jack; Folkman, Joseph (2019-06-25). "Research: Women Score Higher Than Men in Most Leadership Skills". Harvard Business Review. ISSN   0017-8012 . Retrieved 2019-11-01.
  22. Dutta, Debalina1. "Sustaining The Pipeline: Experiences Of International Female Engineers In U.S. Graduate Programs." Journal of Engineering Education 104.3 (2015): 326-344. Education Source.
  23. Blaisdell, Stephanie (1994). "Factors In The Underrepresentation Of Women In Science And Engineering: A Review Of The Literature". Penn State University: 169–170.
  24. 1 2 Committee on the Guide to Recruiting and Advancing Women Scientists and Engineers in Academia, Committee on Women in Science and Engineering, and National Research Council (2006). To Recruit and Advance : Women Students and Faculty in U.S. Science and Engineering. National Academic Press. p. 26.{{cite book}}: CS1 maint: multiple names: authors list (link)
  25. "Women in Science, Technology, Engineering, and Mathematics (STEM): Quick Take". Catalyst. Retrieved 2019-11-22.
  26. "Higher Education Student Statistics: UK, 2016/17 - Subjects studied | HESA". www.hesa.ac.uk. Retrieved 2019-11-22.
  27. "Canada Undergraduate Enrollment". Research and Trends for Women in STEM. 2016-08-18. Retrieved 2019-11-22.
  28. Bendemra, Hamza. "Caught short: a snapshot of Australian engineering". The Conversation. Retrieved 2019-11-22.
  29. 1 2 "SWE Research Update: Women in Engineering By the Numbers". All Together. 2018-09-11. Retrieved 2019-10-14.
  30. 1 2 Yoder, Brian. "Engineering by the Numbers" (PDF). ASEE. American Society for Engineering Education.
  31. "Table 2. Doctorates awarded to women, by field of study: 1995–2004" (PDF). National Science Foundation. Retrieved 10 Apr 2012.
  32. Scott Jaschik, Women Lead in Doctorates, Inside Higher Ed, September 14, 2010 (accessed June 18, 2013)
  33. Committee on the Guide to Recruiting and Advancing Women Scientists and Engineers in Academia; Committee on Women in Science and Engineering; National Research Council. To Recruit and Advance : Women Students and Faculty in U.S. Science and Engineering. pp. 14–47.
  34. Kaspura, Andre (2014). "THE ENGINEERING PROFESSION: A STATISTICAL OVERVIEW". 11. Engineers Australia: 117.{{cite journal}}: Cite journal requires |journal= (help)
  35. 1 2 3 Myers, Jennifer (9 Nov 2010). "Why more women aren't becoming engineers". The Globe and Mail . Retrieved 24 Mar 2013.
  36. "Canadian Engineers for Tomorrow | Engineers Canada". engineerscanada.ca. Retrieved 2019-06-23.
  37. "Women in Engineering". Engineers Canada. Archived from the original on 23 June 2012. Retrieved 30 Jun 2012.
  38. 1 2 3 4 5 "Canadian Engineers for Tomorrow: Trends in Engineering Enrolment and Degrees Awarded 2013 to 2017". Engineers Canada. Retrieved 23 Jun 2019.
  39. 1 2 "Canadian Engineers for Tomorrow | Engineers Canada". engineerscanada.ca. Retrieved 2019-06-23.
  40. "INWES Education and Research Institute: CCWE+20 National Workshop Project Final Report" (PDF). INWES Education and Research Institute. Jul 2011. Retrieved 24 Mar 2013.
  41. 1 2 3 "Canada needs more women engineers—how do we get there?". University of Ottawa. 26 Jul 2011. Retrieved 24 May 2013.
  42. "Useful Statistics | Women's Engineering Society". www.wes.org.uk. Retrieved 2019-10-21.
  43. "Engineering gender pay gap in the UK less than feared, but still requires action". Royal Academy of Engineering. 2020-01-28. Retrieved 2020-06-08.
  44. Excell, Jon (2017-06-20). "How big is the gender pay gap in UK engineering?". The Engineer. Retrieved 2019-10-21.

Further reading

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.