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Highlighting the role engineers have in solving community and global challenges has been shown to positively affect students' engineering identity development. Poor water quality and water scarcity have been recognized as a critical global issue by many organizations, including the United Nations. Students of all ages can relate to the importance of having drinkable water through their experiences with thirst, drought, floods, news stories, or just accidentally swallowing salt water while on holiday at a beach. This talk describes the development and implementation of a series of engineering education activities focused on water quality. These activities ranged from three-minute activities for community outreach events to week-long lessons for engineering freshmen. Younger students were able to readily recognize how using different types of filters and natural media can increase the clarity of water with particulate or color contamination. Middle and high school students were able to design and test filter set-ups and learn about the role of nanotechnology in water purification. They also developed analytical and data analysis skills through qualitative and quantitative water quality measurements. Freshman engineering students learned about the water industry, local and global water issues, and performed water quality sampling around their campuses using portable meters that log data via a cell phone app. The activities and results were then used to meet university-course outcomes related to the societal impacts of engineering, statistical analysis, plotting data, and written communication. By centering learning on a tangible and important engineering challenge, this work provides a flexible framework for learning and problem solving that can be tailored to the needs of students from different age groups and for different learning outcomes. 

Engineering‐oriented bridge programs and camps are popular strategies for broadening participation. The students who often serve as counselors and mentors in these programs are integral to their success.

Predicated on the belief that mentoring contributes to positive outcomes for the mentors themselves, we sought to understand how undergraduate student mentors approached and experienced their work with a 6‐day overnight, NSF‐sponsored youth engineering camp (YEC). This study was guided by the question: How did YEC camp counselors approach and experience their roles as mentors?

We conducted an exploratory qualitative study of four Black undergraduate engineering students' experiences with and approaches to near‐peer mentorship in the YEC program. Data consisted of transcripts from two post‐program interviews and one written reflection from each participant. We analyzed data through abductive coding and the funds of knowledge framework.

Through subsequent interpretation of code categories, we found YEC mentors: (1) engaged in altruistic motivations as YEC mentors, (2) leveraged previous experiences to guide their approaches to mentorship, and (3) engaged in self‐directed learning and development.

This study highlights the knowledge and strategies that YEC mentors drew upon in their roles, and how they sought and achieved various personal, academic, and professional benefits. Insights from this study illustrate how near‐peer mentors can support their and others' engineering aspirations.

 

Rural schools, especially smaller ones, offer enormous opportunities for teachers to get to know their students and to cultivate their academic talents. However, students with potential in science, technology, engineering, and mathematics (STEM) face specific obstacles to having their talents fully realized in rural schools. Joni Lakin, Tamra Stambaugh, Lori Ihrig, Duhita Mahatmya, and Susan G. Assouline describe the STEM Excellence and Leadership project from the University of Iowa, which seeks to equip rural teachers in grades 5-8 with the skills and knowledge to recognize and grow STEM talent in rural areas. Examples of success and lessons learned are shared.