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1 – 10 of 990Sayo O. Fakayode, Jennifer Jennings Davis, Linus Yu, Paulette Ann Meikle, Ron Darbeau and Georgia Hale
Strengthening the nation’s technological workforce, competing and expanding its relevance in the global economy, and maintaining personal as well as homeland security will be…
Abstract
Strengthening the nation’s technological workforce, competing and expanding its relevance in the global economy, and maintaining personal as well as homeland security will be highly dependent on the quantity, quality, and diversity of the next generations of scientists, engineers, technologists, and mathematicians. Production of a diverse generation of human resources with relevant, competitive skills is critical. However, so too is the need to raise an enlightened citizenry with cross-cultural experience and cultural awareness competency, with a broad worldview and global perspectives. These requirements are critical to understanding the challenges and opportunities of scholarly activity in a pluralistic global environment and positioning ourselves to capitalize upon them. Scholars with cross-cultural experience and competency are empowered to adapt and work collaboratively, nationally and globally, with scholars of different races, geopolitical, socioeconomic, and cultural backgrounds. Development of effective strategies to transform science, technology, engineering, and mathematics (STEM) departments for inclusion and to broaden the participation in STEM across cultures, socioeconomic standing, race, and gender in higher education has been a dominant topic of pedagogical interest of national priority in the last several decades. However, success in these endeavors is achievable only through systemic change and a cultural shift to address the underlying root causes of socioeconomic disparity, gender, and racial disparities and a paucity of cultural awareness among all educational stakeholders. STEM departments can only be truly transformed for inclusion through the development of sensitive, creative, and student-engaging curricula and targeted recruitment and retention of underrepresented minorities in STEM. Formation of well-coordinated alliances spanning educational sectors, governmental and non-governmental organizations, and community engagement and outreach are also critical to promoting inclusive and broad participation in STEM education.
The first section of the chapter gives an introduction to various challenges, obstacles, and hindrances that prevent a successful transformation of K–12 science education as well as STEM departments in higher education for inclusion. The second section discusses historical perspectives of the University of Arkansas-Fort Smith (UAFS) – the institutional profile, missions, and visions of UAFS as a regional university. Policies and strategies for addressing the socioeconomic disparity, faculty gender, and racial disparities and cultural competency awareness at UAFS are also highlighted in this section. Other approaches including targeted efforts to recruit and retain underrepresented minority students, provision of financial assistance for students from low-income families, and a creative “Math-up” curriculum innovation to promote inclusive and broad participation in STEM at UAFS are highlighted in the latter section of the chapter. Formation of alliances between UAFS, local K–12 school districts, and governmental and non-governmental agencies to promote broad participation in STEM at UAFS are discussed. The last section of the chapter provides recommendations for adaptation and sustainability of strategies and efforts aimed at transforming national STEM departments for inclusion.
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Lindsay Portnoy, Ash Sadler and Elizabeth Zulick
Amidst continued calls for the democratization of access to higher education for historically underrepresented populations alongside the first global health crisis in a century…
Abstract
Purpose
Amidst continued calls for the democratization of access to higher education for historically underrepresented populations alongside the first global health crisis in a century lies the opportunity to address persistent societal needs: increasing access for underrepresented minority students to educational pathways that lead to careers in lucrative fields of science, technology, engineering and math (STEM).
Design/methodology/approach
Student participants enrolled in the biotechnology pathway Associates, Bachelors and Masters programs share programmatic experience in an accelerated biotechnology program through a bi-annual survey grounded in the central tenets of social-cognitive career theory aimed at understanding requisite academic, social and financial support for student success.
Findings
The pathway program described in this paper emerged to address the need to support underrepresented students in degree attainment and taking on roles in the growing field of biotechnology through a novel, multi-degree, multi-institutional pathway to STEM degree attainment and career success.
Social implications
This work has advanced understanding about how to effectively align higher education institutions with each other and with evolving STEM labor market demands while documenting the impact of essential academic, career and social supports recognized in the literature as high impact practices in broadening participation and increasing retention of underrepresented minority students in lucrative STEM careers.
Originality/value
Pathway programs which best support student success include robust mentoring, experiential learning and robust student scholarship support, part of the design of this unique pathway program. The authors share how this program utilizes high impact practices to provide low-income, underrepresented minority students with supportive, accelerated biotechnology degrees in preparation for success in the job market. What's more, of all our BS-level graduates thus far, 100% are employed and 93% within the biotechnology field. For many, the opportunity to raise their family out of poverty via a stable, high paying job is directly tied to their successes within this program.
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Countless pundits have referred to young African American males as an “endangered species.” While this description of the state of African American male youth between the ages of…
Abstract
Countless pundits have referred to young African American males as an “endangered species.” While this description of the state of African American male youth between the ages of 18 and 25 years can be said to apply in many different circumstances, nowhere is it more apt than in engineering education. Their rates of matriculation, persistence, and graduation in engineering trail not only those of their white, Latino, and Asian counterparts but those of African American females as well.
Angela W. Peters and Verlie A. Tisdale
Claflin University is leading the way in graduating underrepresented minorities at the bachelor’s level and preparing them for graduate school in STEM. Claflin University is a…
Abstract
Claflin University is leading the way in graduating underrepresented minorities at the bachelor’s level and preparing them for graduate school in STEM. Claflin University is a small liberal arts institution with the primary focus on teaching. However, because of the national demand for STEM professions, and the gap between the supply and demand, Claflin administrators were astute enough (14 years ago) to realize that in order to be effective as a teaching institution, there must be a delicate balance between teaching and research. For the state of South Carolina which has the third largest percent population of African Americans (31%) in the country, educated and trained minorities in the STEM fields are in even higher need as they can serve as role models and help build up a minority higher education pipeline within their home towns. HBCUs are central to this mission of increasing minority participation in STEM and have been playing a vital role in educating underrepresented groups. Therefore, Claflin University made a courageous decision (14 years ago) to enhance the role of research-based teaching, specifically in STEM. This synergistic move would bolster Claflin’s competitiveness as a teaching institution with a strong and sustainable research core.
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Valerie Gray Hardcastle, Stacie Furst-Holloway, Rachel Kallen and Farrah Jacquez
Despite significant investments in efforts to broaden participation, the number of women in science, technology, engineering, and mathematics (STEM) fields who leave the academy…
Abstract
Despite significant investments in efforts to broaden participation, the number of women in science, technology, engineering, and mathematics (STEM) fields who leave the academy is disheartening. Some reports suggest half of women STEM faculty will leave tenure track positions within 10 years after hire (Kaminski & Geisler, 2012). For women of color, the data are equally bleak (Ginther & Kahn, 2012) and affirm the need for continuously evolving practices and policies to retain underrepresented faculty in STEM and ensure career satisfaction and success. Unfortunately, current programs for career development and mentoring largely promote rigid conformity to traditional performance expectations, which enable the persistence of narrow departmental norms regarding markers of success. By drawing on person–environment (PE) fit theory, and combining data from our own institution with evidence-based practices from others, the authors have created a faculty development program designed to upend this practice. The objective of this program is to help faculty advance their careers in the academy while staying true to what they value, while simultaneously helping departments reflect on how they can create more inclusive and supportive environments for all faculty. The authors describe the program in detail and provide initial assessments of impact on faculty participants as well as departmental and institutional practice.
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Krystal L. Williams, Brian A. Burt and Adriel A. Hilton
This study aims to better understand how students’ academic strains and multilevel strengths relate to their math achievement, with a particular emphasis on underrepresented…
Abstract
Purpose
This study aims to better understand how students’ academic strains and multilevel strengths relate to their math achievement, with a particular emphasis on underrepresented students of color and girls given the need to broaden science, technology, engineering and math (STEM) participation for these groups.
Design/methodology/approach
National Education Longitudinal Study of 1988 data was used for a historical examination of the various student academic strains and multilevel strengths that relate to math achievement in high school. T-tests and chi-square tests were conducted to examine differences in strains and strengths across policy-relevant student subgroups. Ordinary least squares (OLS) regression was used to examine how students’ strains and strengths related to their math achievement and the relative importance of each of these factors.
Findings
The findings suggest that both the academic strains and multilevel strengths that students’ experience in middle school are related to their high school math achievement and the prevalence of these factors varies across different policy-relevant student subgroups. Furthermore, the relative importance of these factors on achievement differs.
Originality/value
Studies which focus on either students’ academic challenges or their adaptive strengths fall short of a more nuanced discussion about how both factors relate to math outcomes. This study addresses this limitation and emphasizes that stakeholders who are interested in STEM diversity should consider holistic strategies for alleviating gender and racial/ethnic discrepancies in secondary math achievement.
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Mary A. Smith, Angela M. White, Kelsie M. Bernot, Cailisha L. Petty, C. Dinitra White, Grace E. Byfield, Robert H. Newman, Roy J. Coomans and Checo J. Rorie
As the US transitions to a majority–minority population, the underrepresentation in the science, technology, engineering, and mathematics (STEM) workforce must be resolved to…
Abstract
As the US transitions to a majority–minority population, the underrepresentation in the science, technology, engineering, and mathematics (STEM) workforce must be resolved to ensure that our nation maintains its competitiveness and global economic advantage. The persistent problem of retaining underrepresented minority (URM) students in STEM continues to be a national priority after several decades of attention. The role of historically black colleges and universities (HBCUs) in addressing this challenge cannot be overstated, given their history in producing African American STEM graduates. As the largest HBCU in the country, North Carolina A&T State University (NC A&T) serves a combined undergraduate and graduate population of 11,877 students, 78% of which self-identify as African American. To overcome the multiple challenges that impede retention and persistence to degree completion in biology, the Department of Biology at NC A&T has adopted a major cultural shift in its advising strategy. The new approach encompasses a Life Mapping and Advising Model that builds faculty–student relationships and engages both parties effectively in the process. The model includes six important pillars to drive student success: (1) dedicated advising space, the Life Mapping and Advising Center (LMAC), (2) effective advisors, (3) integrated peer mentor and peer tutoring programs, (4) an intrusive advising strategy, (5) integration with first-year student success courses, and (6) life coaching. Although the program is in its infancy, based on the first-year assessment data, we have observed many promising trends that, together, point toward successful retention and persistence of our students in the major.
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Leyte L. Winfield, Lisa B. Hibbard, Kimberly M. Jackson and Shanina Sanders Johnson
The racial and ethnic representation of individuals in the workforce is not comparable to that in the general population. In 2010, African Americans constituted 12.6% of the US…
Abstract
The racial and ethnic representation of individuals in the workforce is not comparable to that in the general population. In 2010, African Americans constituted 12.6% of the US population. However, African Americans represented less than 5% of PhD recipients in 2010; African American women comprised less than 1% of the degrees awarded in that same year. These disappointing statistics have sparked conversations regarding the retention of underrepresented groups with a focus on what helps to ensure these individuals will transition through the science, technology, engineering, and mathematics (STEM) pipeline. This chapter provides insight into the elements of the Spelman College learning environment that empower women of African descent to become agents of their success while facilitating their movement through the STEM pipeline. The chapter focuses on interventions and resources developed in the Chemistry and Biochemistry Department to foster student-centered learning. Described herein are cocurricular strategies and course-based interventions are used synergistically to enhance student outcomes. The approach to curricular innovation is framed by theories related to community of inquiry (CoI), metacognition, agency, and self-regulated learning. Strategic institutional investments have underpinned these efforts. In addition to providing a snapshot of student outcomes, the authors discuss lessons learned along with the realities of engaging in this type of intellectual work to elucidate the feasibility of adopting similar strategies at other institutions.
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Carina Roemer, Sharyn Rundle-Thiele, Bo Pang, Patricia David, Jeawon Kim, James Durl, Timo Dietrich and Julia Carins
Females are underrepresented in Science, Technology, Engineering and Mathematics (STEM), both in the workforce and in universities. Low self-efficacy and limited access to role…
Abstract
Purpose
Females are underrepresented in Science, Technology, Engineering and Mathematics (STEM), both in the workforce and in universities. Low self-efficacy and limited access to role models are key factors preventing retention of female STEM students enrolled in university degrees. This paper aims to report on one social marketing pilot programme that was co-designed to increase self-efficacy in females currently enrolled in STEM programmes.
Design/methodology/approach
The Co-create, Build and Engage (C-B-E) framework was applied. Process and outcome evaluations were conducted using a repeated measure design to assess pilot programme effectiveness.
Findings
A significant increase in self-efficacy and high satisfaction rates were observed for STEM students that attended the bias literacy workshop. Social advertisements raised awareness for available STEM specific university services.
Originality/value
This paper outlines the application of the C-B-E framework. To the best of the authors’ knowledge, this study delivers the first scientific paper reporting an outcome evaluation for a social marketing programme seeking to retain women enrolled in university STEM degrees.
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Ani Nahapetian, Virginia Huynh, Omar Ruvalcaba, Ric Alviso and Gloria Melara