Search results

The purpose of this paper is to report the change in students' STEM perceptions in two different informal learning environments: an online STEM camp and a face-to-face (FTF) STEM camp.

For this quasi-experimental study, 26 students participated in an online STEM summer camp and another 26 students participated in the FTF STEM camp. Students from each group took the same pre- and post-STEM Semantics Survey documenting their perceptions of the individual STEM fields and of STEM careers. Wilcoxon Signed-Rank tests, Mann–Whitney U tests and corresponding effect sizes were used to compare the pre- and post-scores within and between the camps.

Results indicate that both camps produce similar outcomes regarding STEM field and career perceptions. However, analysis of all statistical values indicates that the online STEM camp can produce a larger positive influence on STEM field perceptions and the FTF camp can produce a larger positive influence on STEM career perceptions.

This suggests that STEM camps, both online and in-person, can improve students' perceptions of the STEM fields and of STEM careers. Implications from this study indicate that modifications of informal learning environments should be based on the type of learning environment.

This manuscript discusses the development and impact of an online STEM camp to accommodate for the sudden onset of the COVID-19 pandemic and the inability to hold an in-person STEM camp. These results may influence the curriculum and organization of future online and FTF STEM camps.

This paper investigated the impact a camp on informal science, technology, engineering and mathematics (STEM) had on students' perceptions of STEM fields and careers.

A quasiexperimental design was used to assess students' perceptions toward STEM fields and careers. Secondary students (n = 57) who participated in the STEM summer camp completed STEM projects, went on lab tours and attended panels during the one- or two-week residential camps. Students completed a STEM Semantics survey to assess their perceptions prior to and after attending the camp. Descriptive statistics, Cohen's d effect sizes, paired sample t-tests and Pearson's correlation were conducted to analyze the data.

Results suggested that although there was no significant change in students' dispositions toward each individual STEM field, there was a statistically significant improvement of students' perceptions of STEM careers (p = 0.04; d = 0.25). Furthermore, the results of the Pearson's correlation indicated that there was a statistically significant positive association between perceptions of a STEM career and perceptions in science, mathematics and engineering.

This suggests that various components of the informal learning environment positively contributed to students' perceptions toward STEM careers. Implications from the study indicate that when students are engaged in hands-on science or STEM PBL activities and have opportunities to be exposed to various STEM careers, their perceptions of STEM pathways will improve.

These results may influence future curriculum and the organization of future STEM camps by encouraging teachers and camp directors to integrate practical hands-on STEM projects and expose students to potential STEM pathways through lab tours and panels of STEM professionals.

This chapter illuminates the impact of providing informal learning experiences for students pursuing Science, Technology, Engineering, and Mathematics (STEM) teaching careers at a time when there is a considerable shortage of qualified teachers in America's urban centers. Preservice STEM teachers were provided with the opportunity to participate in a National Science Foundation (NSF) grant funded Noyce Internship Program prior to serving as counselors and teaching assistants in a STEM camp for underrepresented middle school students. Through the Noyce Internship Institute, participants were introduced to interactive sessions that model promising teaching practices including inquiry-based and project-based learning. This narrative inquiry examines the impact of these experiences on preservice STEM teachers' self-efficacy and highlights outcomes in three areas: increase of preservice teachers' confidence, classroom management, and strengthening their desire to teach STEM.

The purpose of this study is to examine a week-long science, technology, engineering and mathematics (STEM) project-based learning (PBL) activity that integrates a new educational technology and the engineering design process to teach middle and high school students the concepts involved in rotational physics. The technology and teaching method described in this paper can be applied to a wide variety of STEM content areas.

As an educational technology, the dynamic and interactive mathematical expressions (DIME) map system automatically generates an interactive, connected concept map of mathematically based concepts extracted from a portable document format textbook chapter. Over five days, students used DIME maps to engage in meaningful self-guided learning within the engineering design process and STEM PBL.

Using DIME maps within a STEM PBL activity, students explored the physics behind spinning objects, proposed multiple creative designs and built a variety of spinners to meet specified criteria and constraints.

STEM teachers can use DIME maps and STEM PBL to support their students in making connections between what they learn in the classroom and real-world scenarios.

For any classroom with computers, tablets or phones and an internet connection, DIME maps are an accessible educational technology that provides an alternative representation of knowledge for learners who are underserved by traditional methods of instruction.

For STEM teachers and education researchers, the activity described in this paper uses advances in technology (DIME maps and slow-motion video capture on cell phones) and pedagogy (STEM PBL and the engineering design process) to enable students to engage in meaningful learning.

Learning through formal and informal experiences is critical for building content knowledge, pedagogical skills, and self-efficacy/confidence for preservice teachers. teachHOUSTON offers numerous teacher enhancement opportunities outside the teacher education courses which allows preservice teachers to connect to the real world which includes being able to relate to a diverse population of students and to understand how the course content can be related to them, their families, and communities in their everyday experiences. Through formal and informal experiences such as professional development workshops, discipline specific courses, research experiences, and internships, preservice teachers have the opportunity to engage in hands-on science activities they can use with their students, develop lessons, and gain knowledge on how to deliver this content while managing their classroom. This chapter will give an overview of the formal and informal experiences offered through teachHOUSTON with a highlight on the structure and content of the six week Noyce Internship Program which engaged interns as counselors and teaching assistants in a summer STEM camp for underserved middle school students and introduces the interns to interactive sessions that model promising practices for teaching.

The purpose of this paper is to explore the designed cultural ecology of a hip-hop and computational science, technology, engineering, and mathematics (STEM) camp and the ways in which that ecology contributed to culturally sustaining learning experiences for middle school youth. In using the principles of hip-hop as a CSP for design, the authors question how and what practices were supported or emerged and how they became resources for youth engagement in the space.

The overall methodology was design research. Through interpretive analysis, it uses an example of four Black girls participating in the camp as they build a computer-controlled DJ battle station.

Through a close examination of youth interactions in the designed environment – looking at their communication, spatial arrangements, choices and uses of materials and tools during collaborative project work – the authors show how a learning ecology, designed based on hip-hop and computational practices and shaped by the history and practices of the dance center where the program was held, provided access to ideational, relational, spatial and material resources that became relevant to learning through computational making. The authors also show how youth engagement in the hip-hop computational making learning ecology allowed practices to emerge that led to expansive learning experiences that redefine what it means to engage in computing.

Implications include how such ecologies might arrange relations of ideas, tools, materials, space and people to support learning and positive identity development.

Supporting culturally sustaining computational STEM pedagogies, the article argues two original points in informal youth learning 1) an expanded definition of computing based on making grammars and the cultural practices of hip-hop, and 2) attention to cultural ecologies in designing and understanding computational STEM learning environments.

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.

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.

In distinguishing the education of adults from the education of children, a gray area lies on where to classify gifted and honors students. The purpose of this study was to determine if the attitudes of students at an honors STEM summer camp paralleled the educational needs of adults, namely self-directed learning.

Researchers analyzed survey responses through an exploratory factor analysis and five t tests.

The interpretation of the effect sizes showed that after engaging in a self-directed learning experience, students expressed more positive self-efficacy and intrinsic motivation, experienced reduced extrinsic motivation and anxiety, and were less task-completion oriented.

The results suggest that gifted and honors students may have a propensity to learn that is more similar to that of adults rather than their same-age peers.