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Over the next 25 years, STEM (science, technology, engineering, and mathematics) occupations will increase at rates higher than those in any other professional field. The inevitable rise in career opportunities, and the multiplicative impact across technology in a wide range of fields, will continue to create gaps that can and should be filled by professionals with diverse skill sets. It is essential to increase equitable access to future available jobs for historically underserved populations, such as women with autism, as they possess skills and perspectives that offer different approaches to job tasks in STEM fields. Considering the intersectional barriers that women face in the workforce, we have written this chapter to bring much needed attention to the interventions that employers can and should enact to support the women of Generation A. We offer the FACES framework (Facilitation, Awareness, Connection, Exposure, Support) as a guidepost for companies and organizations that endeavor to support women with autism in professional preparation and on-the-job development. We corroborate our framework recommendations with labor market data that offers insight into future projections regarding STEM fields and the associated opportunities and careers.

This paper aims to explore the complexity of the “leaky pipeline” of women in science, technology, engineering and maths (STEM) in the intriguing contexts where there are a high number of STEM graduates but a low number of women working in these fields.

The authors conducted in-depth interviews with eight STEM “leavers” and eight “persisters” in Turkey to understand the multi-level influences on their career paths.

The behavioural ecological model is applied to enrich the understanding of women’s attrition from STEM. The authors found a complex system of actors, relationships and influences that impact the negotiations of women’s felt misfit/love of their STEM career and changing self-actualisation.

The authors highlight that social marketers should consider the complex influences on even the most individualistic-looking decisions to produce systemic change.

This paper deepens the use of the behavioural ecological model in the ways that the layers of motivator and demotivator influences interact with women’s internal negotiations of career choice. The paper integrates classic theories (self-actualisation (Maslow, 1943) and two-factor model (Herzberg et al., 1959)) within systems social marketing.

The purpose of this study was to make sense of the individual perspectives of former undergraduate student mentors from science, technology, engineering, and mathematics (STEM) fields who took part in an after-school STEM mentoring program. The study examined the following research questions: (1) How do former undergraduate student STEM mentors interpret and give meaning to their after-school STEM mentoring experiences? (2) In what way can an after-school STEM mentoring experience lead to a deeper understanding of the long-term implications of a STEM mentorship program?

The sample comprised 21 former undergraduate STEM mentors. The study was guided by the methods of content analysis and repertory grid (RepGrid), with data collected via highly structured interviews. Eight elements were pre-selected for the RepGrid to elicit constructs from participants. These include (1) mentoring, (2) teaching, (3) research, (4) career, (5) workforce, (6) Nebraska STEM for you (NE STEM 4U), (7) networking, and (8) communication. The researcher employed content analysis for cross-case analysis and used interpretative clustering to analyze nuanced similarities and differences among participants. Personal construct theory was used to understand how former STEM mentors made sense of their experiences.

The results highlight the diversity of viewpoints among participants, as well as their connections to various career paths, communication strategies, and mentorship styles. These insights contribute to a deeper understanding of how STEM mentorship experiences can be tailored to the experiences of mentees. The study stresses the significance of clear communication in STEM and advises professionals to avoid excessive technical jargon to convey complex ideas. Overall, the study provides valuable insights into the motivations, perspectives, and benefits of former undergraduate mentors. Ultimately, recognizing how these factors impact STEM mentoring programs is vital for the long-term success and advancement of the STEM pipeline.

The study has several limitations, including the inclusion of participants lacking knowledge or experience with the eight elements used in the RepGrids. While participants had completed a bachelor’s degree in a STEM field, not all had pursued advanced schooling or careers that required knowledge or implementation of research.

Findings underscore the importance of acknowledging the diverse career paths within STEM fields to understand participants’ perspectives toward mentorship. Considering the incorporation of STEM mentorship within regular school hours and making it a graduation prerequisite could enhance student participation and advancement. Integrating STEM outreach programs into higher education curricula could facilitate the development of essential professional skills (e.g. critical thinking, problem-solving) among STEM undergraduate students. These implications highlight the importance of diverse mentorship styles and professional skills to foster a more inclusive STEM workforce.

The study focused on the individual perspectives of participants rather than employing a thematic analysis.

Supporting the advancement of science, technology, engineering and mathematics (STEM) in ways that help to ensure the health, prosperity, welfare and security of the nation has been central to the mission of the US National Science Foundation (NSF) since 1950, the year Congress created the agency. Preparing a highly qualified and diverse STEM workforce plays a central role in supporting this mission. The paper aims to discuss these issues.

Over the past several decades, many positive steps have been taken throughout the US education system to help ensure a more diverse STEM workforce. Even so, women remain underrepresented among STEM faculty in higher education, especially at the upper ranks. Contributing to women’s underrepresentation are systemic obstacles to the recruitment, retention and promotion of women of different racial, ethnic, disability, sexual orientations and nationality statuses.

The NSF ADVANCE Program is designed to address these barriers. Success for ADVANCE is, therefore, best defined in terms of the changes made to the structures and climates of academic workplaces, rather than in numbers of women hired, retained or promoted in any one institution at a given point in time.

This introduction briefly examines the origins of ADVANCE, key transitions in the program over time, its reach nationally and internationally, and its future.

Gender diversity, or in-diversity, has long been a problem in the tech industry. Until now, significant gaps and barriers still exist. This paper examines how recruitment practices within the technology sector can contribute to gender inequality and how recruitment practices can be improved to support a gender-diverse organization.

This paper adopted library research and case study as papers' methodologies.

There are many benefits of gender diversity, including better performance, better financial returns, and lower volatility. However, most tech companies do not make diversity a priority, and usually display conscious or unconscious gender biases. Some of the recommendations to overcome this diversity issue are to make diversity a goal, offer unconscious bias training, and expand recruitment efforts.

The findings imply that companies not pursuing a diverse workforce are in danger of experiencing lags in innovation and could be left behind. The findings also show that a technology company can increase the diversity of the company's workforce by applying practices that have already proven to be successful.

This paper confirms that gender parity is not just a social mission nor is gender parity solely a public relations initiative to improve a company's image. Technology companies must be continually innovating to thrive in companies' highly competitive and rapidly changing industry.

This chapter traces the career trajectories of the teachHOUSTON science, technology, engineering, and mathematics (STEM) teachers since the inception of the program. It asks whether the National Science Foundation (NSF) investment of millions of dollars in STEM education produced more STEM teachers of high quality for the diverse, urban area. The chapter is filled with descriptive statistics and stories. Two major findings are that the teachHOUSTON program produced double-digit physics teachers when the Greater Houston area had not had a freshly prepared physics teacher in over a decade. Additionally, teachHOUSTON graduates have distinguished themselves by being named recipients of several awards such as beginning teacher of the year awards, district teacher of the year awards, among other distinctions. teachHOUSTON alumni are also serving in a variety of leadership capacities for high-need public school districts. The chapter ends with a discussion of the program's strengths as well as the areas in which it continues to grow. Three new NSF grants allow for continued improvement and transition this work into two additional books proposed in this three-volume series.

The purpose of this paper is to describe the objectives, activities and outcomes of the National Science Foundation ADVANCE project, Institutions Developing Excellence in Academic Leadership (IDEAL) during 2009–2012. The goal of IDEAL was to create an institutional learning community empowered to develop and leverage knowledge, skills, resources and networks to transform academic cultures and enhance gender equity, diversity and inclusion in science, technology, engineering and math (STEM) disciplines at six research universities in the northern Ohio region. Over the three-year period, these institutions developed academic leaders and institutionalized gender equity transformation through multi-dimensional and multi-level initiatives, improving the advancement and leadership of women faculty in STEM disciplines.

The authors describe the objectives, activities and outcomes of the NSF ADVANCE project, IDEAL during 2009–2012. The six research institutions included in IDEAL were Bowling Green State University, Case Western Reserve University (the lead institution), Cleveland State University, Kent State University, University of Akron and University of Toledo.

IDEAL’s outcomes included the institutionalization of a number of gender equity initiatives at each university, an increase in the number of tenured women faculty in science and engineering disciplines over three years across the six universities, and increases in the numbers of women in faculty and administrative leadership positions. Out of 62 of the IDEAL participants (co-directors and change leaders), 25 were promoted or appointed to roles of leadership within or beyond their institutions during or after their participation in IDEAL. A number of new institutional collaborations and exchanges involving the six universities occurred during and emerged from IDEAL. An integrative model of the IDEAL program is developed, describing the nested components of each institution’s gender equity transformation within the IDEAL partnership consortium and the larger NSF ADVANCE community, and highlighting the dynamic interactions between these levels.

The IDEAL program demonstrates that systemic change to achieve equity for women and underrepresented minority faculty in STEM disciplines must be rooted on individual campuses but must also propagate among higher education systems and the broader scientific community. The effort to develop, sustain and expand the IDEAL partnership model of institutional transformation (IT) in higher education illuminates how innovative, context-sensitive, cost-effective and customized institutional strategies may be implemented to advance gender equity, diversity, inclusion and leadership of women faculty at all levels across the country.

This is an original description of a unique and distinctive partnership among research universities to foster gender equity IT. The manuscript details the objectives, activities and outcomes of the IDEAL program, established with the aim of broadening participation in the STEM academic workforce and advancing gender equity, diversity and inclusion in institutions of higher education. An integrative model is developed, illustrating the key components and outcomes of the IDEAL program.

This study aims to provide a comprehensive review and bibliometric analysis of the literature in the field of science, technology, engineering and mathematics (STEM) education over the past 15 years, with a specific focus on global distribution and research trends.

This study collected 1,718 documents from the Web of Science (WOS) database and analyzed their timeline distribution, geographical distribution, research topics, subject areas, learning stages and citation burst using a bibliometric approach with VOSviewer and Citespace.

Results indicated that: overall, STEM education has increasingly gained scholarly attention and is developing diversely by emphasizing interdisciplinary, cross-domain and regional collaboration. In terms of global collaboration, a collaborative network with the USA in the center is gradually expanding to a global scope. In terms of research themes, four key topics can be outlined including educational equity, pedagogy, empirical effects and career development. Social, cultural and economic factors influence the way STEM education is implemented across different countries. The developed Western countries highlighted educational equity and disciplinary integration, while the developing countries tend to focus more on pedagogical practices. As for research trends, eastern countries are emphasizing humanistic leadership and cultural integration in STEM education; in terms of teachers’ professional development, teachers’ abilities of interdisciplinary integration, technology adoption and pedagogy application are of the greatest importance. With regards to pedagogy, the main focus is for developing students’ higher-order abilities. In terms of education equity, issues of gender and ethnicity were still the hottest topics, while the unbalanced development of STEM education across regions needs further research.

This study provides a global landscape of STEM education along the timeline, which illustrates the yearly progressive development of STEM education and indicates the future trends.

Findings within the last decade reveal a core set of activities that have been correlated to student success metrics such as persistence, retention, and graduation (Kuh, 2008). These research-based activities are called high-impact practices (HIPs). Students who have participated in HIPs have shown gains in retention, in persistence, intellectually and in an overall positive college experience. This chapter provides an overview of 10 HIPs and their importance and benefits to underserved students, that is, first-generation college students, low-income college students, and underrepresented students of color such as African American, Latino/a, and Native American. Findings within the chapter also recognize how HIPs can be extremely beneficial for historically Black colleges and universities to build capacity and to ensure student success, particularly in science, technology, engineering, and mathematics (STEM).