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The purposes of this study were to describe the roles mentors enacted as part of an afterschool science, technology, engineering and mathematics (STEM) program and how those roles varied across three sites and to explain those differences.

The authors used a comparative case study design and collected data primarily from interviews with program mentors and observations of the sessions.

The authors found that the mentors played four roles, depending on the school site: teachers, friends, support and role models. Mentors interpreted cues from the environment in light of their own identities, which ultimately led them to construct a plausible understanding of their roles as mentors.

The authors identify four mentoring roles that are somewhat consistent with prior research and demonstrate that the roles mentors enact can vary systematically across sites, and these variations can be explained by sensemaking. This study also contributes to research on mentoring roles by elaborating each identified role and offering a framework to explain variability in mentor role enactment.

The authors recommend that mentoring program directors discuss the roles that mentors may enact with mentors as part of their training and that they engage mentors in identity work and also recommend that program managers create unstructured time for mentors to socialize outside STEM activities with their mentees.

This study contributes to mentoring research by using sensemaking theory to highlight how and why mentoring roles differ across school sites.

A recent President’s Council of Advisors on Science and Technology report predicts a shortfall of 1 million college graduates in STEM (science, technology, engineering, and mathematics) fields in the United States over the next several years (2012). Recommendations to address this include diversifying the STEM workforce, which is plagued by a lack of gender diversity (Hill, Corbett, & St. Rose, 2010). University–School partnerships are crucial in developing a pipeline that moves interested primary and secondary students (aged 5-18) into majoring and eventually working in STEM fields. The lower involvement of women in STEM fields is multi-factorial and affects all communities, including Abilene, Texas. Abilene Independent School District’s STEM high school, the Academy for Technology, Engineering, and Science (ATEMS) consistently has a female student population at or below 35%. A local university, Abilene Christian University (ACU), has struggled to increase female undergraduate students in STEM fields. Creating a University–School partnership between ACU and ATEMS aided in building a STEM pipeline for girls in the Abilene community. In this chapter, we describe this collaboration between ACU and ATEMS and highlight the key features that led to success of the collaboration.

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.

Studies have shown that science, technology, engineering and mathematics (STEM) careers remain to be one of the areas where there is considerable job growth (Lacey & Wright, 2009; National Science Board, 2010; Singh et al., 2002). However, in many rural regions, science teachers still find it challenging to motivate adolescents to develop an interest in these fields or pursue opportunities in STEM at their schools or in their communities. In exploring a distinctive way to motivate students from rural regions to develop and maintain a STEM mindset, the authors provided students opportunities to participate in programs within their communities to increase their interests in STEM. The authentic STEM learning experiences, “at no cost” for the high school students, helped them focus on cognitive and social abilities as they engaged in experiences developing identities as pre-STEM professionals. This paper reports on how the authors were able to develop research through the support of the professional development system at the university.

The authors explored the experiences of the high school students and parents as they engaged in the Science Olympiad events, community volunteering and mentoring projects over three years in the southeastern United States. A total of 50 high school students participated from the Science Olympiad team from ethnic backgrounds: Hispanic/Latino Americans (55%), African Americans (10%) and White Americans/Caucasians (35%) participated. The high school students and parents were asked to participate by completing required permissions and also completing pre- and post-surveys to help understand their reasons for participating in the activities. At the end of the semester, an interview was conducted with participants to better understand their experiences with working on the team and their STEM perspectives. Parents and guardians of the high school students were also asked to share their thoughts about their children participating in these activities through indirect conversations. The school partnership teacher, also Science Olympiad co-coach, invited high school students to participate in additional STEM activities throughout the school year through the university partnership.

The pre- and post-survey responses provided insight to researchers about the “lived experiences” of the students as they developed a STEM mindset. Analysis of data indicates students’ interests in STEM and working with youth increased as a result of the STEM opportunities. To help in increasing their interests, additional opportunities are needed for these youth to engage in STEM tasks and mentoring. The professional development system (PDS) creates the space for these opportunities to take place, leading to new knowledge for learning and “boundary-spanning roles” for school-university faculty to discover and experiment new ideas that “transcend institutional settings” (National Association for Professional Development Schools, 2021).

Additional research is needed in helping high school students develop a STEM mindset as they participate in volunteer STEM experiences. The survey tools should be revised to address the specific STEM activities that the students participate in during the year. In addition to feedback from the youth and parents using focus group interviews or other defined survey instruments.

The school-university partners continue to explore the successes and challenges of the collaborative effort. Disruptions in the collaborative effort such as school closures due to severe weather and the pandemic have resulted in cancellations of STEM opportunities for high school students. Despite challenges, this collaborative effort continues with an additional focus on STEM learning.

Suggested research may involve investigating parental involvement strategies that increase the likelihood of actual high school student attendance during out-of-school time activities, such as community STEM fairs, competitions and summer STEM camps. Use of focus group interviews provided students setting to talk freely.

Through a new initiative established by the PDS at the university, “PDS Master Teachers,” the school-university faculty were invited to participate and engage in purposeful, intentional professional learning and leading to enhance the quality of the experiences for teacher candidates (Professional Development System, Watson College of Education at the University of North Carolina Wilmington, 2022). This innovative program inspired the school-university faculty to reflect on practice and create new approaches to expand STEM learning in the school and community. Through this collaborative effort, the following National Association for Professional Development Schools (NAPDS) Nine Essentials were addressed: Essential 2: Clinical Preparation; Essential 3: Professional Learning and Leading; Essential 4: Reflection and Innovation; Essential 5: Research and Results; and Essential 8: Boundary-Spanning Roles (National Association for Professional Development Schools, 2021). The University’s PDS comprehensive approach to professional learning and its dedication to providing a space for all to engage in reflective practices for professional growth provided the required support for this project.

This study aims to comprehend vocational preservice teachers' recalled experiences with the Cooperative Problem-based Learning (CPBL) pedagogical approach in an entrepreneurship course and to reveal how these experiences will impact their future teaching practice. The course under study intends to improve preservice teachers' entrepreneurial attitudes while equipping them with the skills necessary to create a comparable teaching strategy at school after graduation.

This study used the semi-structured interview data to triangulate the qualitative data collected from the students' reflection journals. The data were thematically analyzed whereas the codes with comparable elements were combined, resulting in themes that describe the relevance of scaffolding used with each component of the MUSIC motivational model.

The results revealed that the student teachers who took part in the research stated in their comments how the scaffolds used in the CPBL sessions impacted their learning. Additionally, they could articulate the experiences that strengthened their perceptions regarding entrepreneurs and entrepreneurship education.

By implementing scaffolded CPBL in entrepreneurship course during the teacher preparation program, the preservice teachers would be able to put a similar approach into the practice of their future teaching profession in guiding students to accomplish instructional outcomes.

This study highlights the importance of providing more innovative practices for entrepreneurship education across teacher preparation curricula to help develop the skills necessary for entering the future profession. The findings also emphasize the value of scaffolding in PBL, including expert, peer and activity design scaffolding. It also completes the body of research indicating that PBL-based entrepreneur education instruction can help students develop their entrepreneurial skills and attitudes while also providing a great chance to improve their teaching abilities.

Metadiscourse is an important dialogue technique used in productive knowledge building to help a group evaluate and advance their knowledge progress. Previous studies have identified and defined various types of metadiscourse. However, there is scant knowledge about how different metadiscourse types emerge among different groups or what implicit correlations lie between progressive discourse and metadiscourse. Moreover, research on how different types of metadiscourse influence groups' knowledge advancement and artifacts is still inadequate. Therefore, this study aims to further examine the roles that different types of metadiscourse play in the collaborative knowledge building community on both a fine-grained (i.e. progressive discourse) and coarse-grained (i.e. group knowledge advancement and group artifacts) level.

Data for this study are drawn from the behaviour of undergraduate students participating in a 12-week course at a key university in China. On the fine-grained level, epistemic network analysis (ENA) is applied to illustrate how metadiscourse promotes the development of progressive discourse. On the coarse-grained level, two different chi-square tests are conducted to examine the roles of different types of metadiscourse in groups' knowledge advancement and artifacts.

The analysis allowed several conclusions to be drawn. First, the types of metadiscourse that students most often adopted were reflecting on ideas development (RD) and commenting on ideas (CI); they less frequently adopted setting group goals (SG) and making group plans (MP). Second, most types of metadiscourse correlated with developments in progressive discourse, particularly RD and CI. Third, the metadiscourse types RD, CI and coordinating group efforts (CE) played essential roles in knowledge advancement. Fourth, higher-quality artifacts could be created by using the metadiscourse type reviewing the state of knowledge building progress (RP).

A more profound comprehension of the role that metadiscourse plays in the collaborative knowledge building community not only contributes to the literature in the knowledge building field but also carries a significant meaning in regulating community, promoting learner agency and sustained knowledge, and consequently improving collaborative learning performance.

This paper aims to investigate the potential for digital badges to support alternate learning and career pathways in formal and informal learning environments. Stakeholder groups in higher education and industry discussed how digital badges might transform current processes of admitting undergraduate students and hiring young professionals.

This research uses a thematic analysis of in-depth interviews with 30 stakeholders in higher education and the technology industry.

Interview participants expressed optimism about the potential for digital badges to make learning pathways visible to learners and external audiences and to promote equity in STEM (STEM: science, technology, engineering, and mathematics) education and careers. Participants noted several obstacles, largely focused on issues of credibility and logistics of working with badges across settings.

Though the research approach is limited in geographic scope, the findings have broad applicability and insight for the use of digital badges in general.

Education policymakers, employers and scholars will be able to use the insights from this investigation in their efforts to find innovative ways to expand and diversify the STEM workforce, as well as support a wider range of learners than is currently supported by initiatives aligned with the school-to-workforce pipeline metaphor.

This paper directly confronts issues of real-world applications of digital badges by discussing practical implications with college admissions officers and employers. The current study fills a need for research that investigates the use of digital badges across – as opposed to within – contexts.

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.