DiscoverE hired Concord Evaluation Group (CEG) to conduct an independent evaluation of the Future City program. Future City has been operating since 1992. According to DiscoverE, the Future City program is “a national, project-based learning experience where students in 6th, 7th, and 8th grade imagine, design, and build cities of the future. Students work as a team with an educator and engineer mentor to plan cities using SimCityTM software; research and write solutions to an engineering problem; build tabletop scale models with recycled materials; and present their ideas before judges at
Computational Thinking (CT) is a relatively new educational focus and a clear need for learners as a 21st century skill. This proposal tackles this challenging new area for young learners, an area greatly in need of research and learning materials. The Principal Investigators will develop and implement integrated STEM+C museum exhibits and integrate CT in their existing engineering design based PictureSTEM curriculum for K-2 students. They will also pilot assessments of the CT components of the PictureSTEM curriculum. This work will make a unique contribution to the available STEM+C learning materials and assessments. There are few such materials for the kindergarten to second grade (K-2) population they will work with. They will research the effects of the curriculum and the exhibits with a mixed methods approach. First, they will collect observational data and conduct case studies to discover the important elements of an integrated STEM+C experience in both the formal in-school setting with the curriculum and in the informal out-of-school setting with families interacting with the museum exhibits. This work will provide a novel way to understand the important question of how in- and out-of-school experiences contribute to the development of STEM and CT thinking and learning. Finally, they will collect data from all participants to discover the ways that their activities lead to increases in STEM+C knowledge and interest.
The Principal Investigators will build on an integrated STEM curriculum by integrating CT and develop integrated museum exhibits. They base both activities on engineering design implemented through challenge based programming activities. They will research and/or develop assessments of both STEM+C integrated thinking and CT. Their research strategy combines Design Based Research and quantitative assessment of the effectiveness of the materials for learning CT. In the first two years of their study, they will engage in iterations on the design of the curriculum and the exhibits based on observation and case-study data. There will be 16 cases that draw from each grade level and involve data collection for the case student in both schools and museums. They will also use this work to illuminate what integrated STEM+C thinking and learning looks like across formal and informal learning environments. Based in some part on what they discover in this first phase, they will conduct the quantitative assessments with all (or at least most) students participating in the study
Techbridge Girls’ mission is to help girls discover a passion for science, engineering, and technology (SET). In August 2013, Techbridge Girls was awarded a five-year National Science Foundation grant to scale up its after-school program from the San Francisco Bay Area to multiple new locations around the United States. Techbridge Girls began offering after-school programming at elementary and middle schools in Greater Seattle in 2014, and in Washington, DC in 2015.
Education Development Center is conducting the formative and summative evaluation of the project. To assess the
Techbridge Girls’ mission is to help girls discover a passion for science, engineering, and technology (SET). In August 2013, Techbridge Girls was awarded a five-year National Science Foundation grant to scale up its after-school program from the San Francisco Bay Area to multiple new locations around the United States. Techbridge Girls began offering after-school programming at elementary and middle schools in Greater Seattle in 2014, and in Washington, DC in 2015.
Education Development Center is conducting the formative and summative evaluation of the project. To assess the
Community colleges play a vital role in educating undergraduate students. These higher education institutions educate nearly half of the nation's undergraduate students, particularly among low-income and first-generation students and students of color. Because of the rich diversity that currently exists at these institutional-types, there are immense opportunities to broadening participation throughout the engineering enterprise. To this end, the investigator outlines a joint collaboration with five community colleges, three school systems, two college career academies, and a state partner in Georgia - referred as the Georgia Science, Technology, and Engineering Partnerships for Success (GA STEPS) - to provide dual enrollment classes in career pathways for Georgia high school students in grades 9-12, thereby allowing secondary students to earn college credit. The Georgia STEPS program proposes to leverage mechatronics engineering as a means for broadening engineering participation for community colleges and underserved, underrepresented populations in 48 rural counties to increase engineering awareness, skills training and college and career readiness. The project builds on an existing collaboration that has developed successful engineering opportunities at the community college level, by including a wider regional network of rural Georgia counties and high schools. Further, this project has immense potential to transform engineering education and course-taking for students at the secondary and postsecondary level in Georgia and beyond. It has potential great potential to be scaled and replicated at other placed around the United States.
The project's intellectual merit and innovation is that it leverages a successful mechatronics engineering curriculum that supports engineering skills that support local industry as well as supporting innovations in the mechatronics field. The project includes a collective impact framework, involving various stakeholders and aligning quantitative and qualitative metrics and measurable objectives. The broader impacts of this project is that it increases the engineering knowledge and skills of underserved, underrepresented students that are enrolled in community colleges. Also, the impact to rural communities in Georgia support the fact that this project would meet broader groups that can be positively impacted by this type of collaborative. The ability to provide different parts of this engineering discipline across broad audiences in community colleges - that support underrepresented groups understanding of mechatronics engineering - is broadly useful to the field of engineering.
In considering the integration of technology in the classroom it is necessary to factor in the ways in which teachers design for their use. Makerspaces and their use of digitally-based rapid prototyping tools such as laser cutters and 3D printers are serving as new models for technology integration in learning environments. While there has been some research on the educational affordances of such technologies little research has been done to understand their use in the traditional classroom environment by teachers. This paper explores the design of curricular and instructional activities by
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TEAM MEMBERS:
Christian McKayTarrence BanksScott Wallace
As a leader in the science museum field, the New York Hall of Science (NYSCI) is a destination for hands-on, interactive exhibitions and innovative programs. NYSCI’s Design-Make-Play (DMP) pedagogical approach to STEM learning recognizes that what is essential is not only the content—what is being taught—but how teaching and learning are imagined through the curriculum. This commitment to practice builds off of interest-based learning research, which emphasizes that all learners should feel a sense of efficacy and possibility. The hallmarks of this approach include deep personal engagement
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TEAM MEMBERS:
Amanda SolarshGina TesorieroMichaela LabrioleTara Chudoba
This project will coordinate and focus existing educational elements with the common goal of increasing the participation of underrepresented minorities in STEM degree programs and the STEM workforce. This goal will help the US maintain its leadership in science and engineering innovation while supporting the expansion of the talent pool needed to fuel economic growth in technical areas. The program will feature an assessment system that addresses both social influence factors and the transfer of STEM skills with the aim of identifying the reasons that underrepresented minorities leave the STEM pipeline. By including both curricular and extracurricular elements of the STEM pipeline, ranging from middle school through college, the program will be able to respond quickly to findings from the assessment component and take proactive steps to retain STEM students and maintain their self perception as future scientists or engineers.
The program proposes to assess, unite and coordinate elements in the New Mexico STEM pipeline with the ultimate goal of increasing the participation of underrepresented groups in the STEM workforce. The need to grow a diverse science, technology, engineering and mathematics (STEM) workforce is recognized throughout the State of New Mexico, and beyond, by both the public and private sectors. The project develops a crosscutting assessment system that addresses both social influence factors and the skills component of STEM education. The project develops a collective impact framework aimed at increasing the participation of underrepresented minorities in the STEM workforce and implements a common assessment system for students in the 6-20+ STEM pipeline. This assessment system will address both social influence factors and the transfer of STEM related skills with the aim of building a research base to investigate why students from underrepresented minorities leave the STEM pipeline. The output from this research will drive the development of a set of best practices for increasing retention and a scheme for improving the integration of minority students into the STEM community. The retention model developed as part of the program will be shared with the STEM partners through a series of workshops with the goal of developing a more coordinated approach to the retention of underrepresented minorities. The program focuses on a small set of STEM programs with existing connections to the College of Engineering.
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TEAM MEMBERS:
Steven StochajPatricia SullivanLuis Vazquez
resourceprojectProfessional Development, Conferences, and Networks
Jobs are growing most rapidly in areas that require STEM knowledge, causing business leaders to seek skilled American workers now and in the near future. Increase in the number of students pursuing engineering degrees is taking place but the percentages of underrepresented students in the engineering pipeline remains low. To address the challenge of increasing the participation of underrepresented groups in engineering, the National Society of Black Engineers, the American Indian Science and Engineering Society, the Society of Hispanic Professional Engineers, and the Society of Women Engineers have formed the 50K Coalition, a collaborative of over 40 organizations committed to increasing the number of bachelors degrees awarded to women and minorities from 30,000 annually to 50,000 by 2025, a 66% increase. The 50K Coalition is using the Collective Impact framework to develop an evidence-based approach that drives management decision-making, improvements, sharing of information, and collective action to achieve success. The first convening of the 50K Coalition in April, 2016, brought together 83 leaders of the engineering community representing 13 professional societies with over 700,000 members, deans of engineering, minority engineering and women in engineering administrators from 11 leading colleges of engineering, and corporate partners representing six global industries. Consensus was reached on the following Common Agenda items: 1.) Undergraduate support and retention; 2.) Public awareness and marketing; 3.) K-12 support; 4.) Community College linkages; 5.) Culture and climate. The Coalition will encourage member organizations to develop new programs and scale existing programs to reach the goal.
The Coalition will use shared metrics to track progress: AP® Calculus completion and high school graduation rates; undergraduate freshmen retention rates; community college transfer rates and number of engineering degrees awarded. The 50K Coalition will develop the other elements of the Collective Impact framework: Infrastructure and effective decision-making processes that will become the backbone organization with a focus on data management, communications and dissemination; a system of continuous communication including Basecamp, website, the annual Engineering Scorecard, WebEx hosted meetings and convenings; and mutually reinforcing activities such as programs, courses, seminars, webinars, workshops, promotional campaigns, policy initiatives, and institutional capacity building efforts. The National Academy of Sciences study, Expanding Underrepresented Minority Participation: America's Science and Technology Talent at the Crossroads recommended that professional associations make recruitment and retention of underrepresented groups an organizational goal and implement programs designed to reach that goal by working with their membership, academic institutions and funding agencies on new initiatives. While these types of organizations work together now in a variety of ways, the relationships are one-on-one. The 50K Coalition brings together, for the first time professional societies, engineering schools, and industry to consider what mutually reinforcing activities can most effectively encourage students from underrepresented groups to complete calculus and graduate from 4-year engineering programs.
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TEAM MEMBERS:
Karl ReidBarry CorderoSarah EcohawkKaren Horting
The Morgan State University INCLUDES project will build on an existing regional partnership of four Historically Black Colleges and Universities that are working together to improve STEM outcomes for middle school minority male students that are local to Morgan State in Baltimore, North Carolina A&T in Greensboro, Jackson State in Mississippi, and Kentucky State in Frankfort. Additional partners include SRI International, the National CARES Mentoring Network, and the Verizon Foundation. Using the collective impact-style approaches such as planning and implementing a Network Improvement Community (NIC), developing a shared agenda and implementing mutually reinforcing activities, these partners will address two common goals: (1) Broaden the participation of underrepresented minority males in science and engineering through educational experiences that prepare them for careers in STEM fields; and (2) Create a Network Improvement Community focused on STEM achievement in minority males. Program elements include high-quality instruction in STEM content, mentoring, and professional development. The project will expand to include eight additional partners (six HBCUs and two Hispanic-Serving Institutions) and schools and districts in communities local to their campuses. The INCLUDES pilot will help scale innovations that target impacting minorities in STEM.
The project will develop STEM learning pathways for middle school minority males by harnessing the collective impact of 12 university partners, local K-12 schools and districts with which they partner, and surrounding community organizations and businesses with a vested interest in achieving common goals. Products will include a roadmap for addressing the problem through a Network Improvement Community, a website that will contribute to the knowledge base regarding effective strategies for enhancing STEM educational opportunities for minority males, and common metrics, assessments, and shared measurement systems that will be used to measure the collective impact of the Network Improvement Community.
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TEAM MEMBERS:
Jumoke Ladeji-OsiasCindy ZikerGeneva HaertelKamal AliAyanna GillDerrick GilmoreClay Gloster
This project will make synthetic biology activities accessible to high school students and teachers by providing them with an authentic but safe context to learn. These activities will also broaden their understanding and perspectives about how synthetic biology and bioengineering is used in personal, health, and food production contexts as well as raise their interest in STEM. The design of bioMAKERlab will generate an educational version of an existing professional-grade lab for synthetic biology to promote safe production, accessibility, and affordability for high schools and community colleges interested in integrating such wetlab activities into their curriculum.
Most current efforts to broaden access to maker activities for K-12 students have focused on developing collaborative fabrication workspaces (fablabs) involving 3D printers, laser cutters, and other digital and traditional tools. This project will develop and implement bioMAKERlab, an innovative wetlab starter kit and activities that will enable high school students and teachers to engage in synthetic biology by building genetic circuits that let microorganisms change color, smell, and shape. In synthetic biology, participants make their own DNA--gene by gene--and then grow their designs into real applications by inserting them into microorganisms to develop different traits and characteristics provided by the genes. The project will involve students from a Philadelphia public high school and young people participating in weekend workshops at The Franklin Institute, a Philadelphia-based science museum.
This project is a part of NSF's Maker Dear Colleague Letter portfolio (NSF 15-086), a collaborative investment of Directorates for Computer & Information Science & Engineering, Education and Human Resources, and Engineering.
This poster was presented at the 2016 Advancing Informal STEM Learning (AISL) PI Meeting held in Bethesda, MD on February 29-March 2. Makerspaces are social spaces with tools, where individuals and groups conceptualize, design, and make things using new and old technologies. Literacy practices are the ways people use representational texts to navigate and make sense of their worlds. They are used in particular contexts with particular goals. By “representational texts” we mean written words, talk, photographs, diagrams, videos, schematics, computer code, electrical circuit diagrams