The Frank Lloyd Wright Home and Studio will expand its professional development program for educators in Chicago Public Schools and surrounding suburbs with low-income populations. The Teaching by Design program integrates design-based inquiry and problem-solving into K-12 curricula. It connects Wright's design philosophy to contemporary issues in STEAM subjects. Following a multi-year pilot, the trust will bring the project to scale by delivering 12 professional development seminars, developing 100 new lesson plans, enhancing the program's online platform, evaluating the project's short- and long-term impact, and cultivating a sustainable Teaching by Design learning community. The seminars will provide educators with a fully immersive artmaking and design experience that can be replicated in the classroom and connected to cross-curricular themes and learning standards. The project aims to reach 90 educators in at least 40 schools, 9,000 students, and an estimated 3,000 website users.
In partnership with early childhood service providers and elementary school systems, the Children's Museum of the Lowcountry will expand the reach of its programming to share its hands-on, play-based approach to STEM education with targeted children and educators. The museum will create a Power of Play curriculum with lesson plans that reflect best practices and focus on play-based activities to teach STEM concepts tied to grade level and state standards. The museum will train and support 40 teachers and educators from ten Head Start/First Steps early childhood centers and ten Title I elementary schools, and provide them with free Pop Up Tinker Shop (a museum on wheels) outreach visits. The trainings will build teacher confidence, promote best practices for play-based learning, support a community of practice, and enhance young learners' engagement, fascination, and attitude towards STEM. The Power of Play Curriculum will be published as a bound resource and shared with other children's museums and service providers.
For nearly 20 years, the UAB Center for Community OutReach Development (CORD) has conducted SEPA funded research that has greatly enhanced the number of minority students entering the pipeline to college and biomedical careers, e.g., nearly all of CORD’s Summer Research Interns since 1998 (>300) have completed/are completing college and most of them are continuing on to graduate biomedical research and/or clinical training and careers. CORD’s programs that focused on high and middle school students have drawn many minority students into biomedical careers, but a low percentage of minority students benefit from these programs because far too many are already left behind academically in grades 4-6, due, at least in part, to a significant drop in science grades between grades 4 and 6, a drop from which most students never recover. A major contributor to this effect is that most grade 4-6 teachers in predominantly minority schools lack significant formal training in science and often are not fully aware of the great opportunities offered by biomedical careers.
In SEEC II, CORD will deliver intensive inquiry-based science training to grade 4-6 teachers, providing them with science content and hands-on science experiences that will afford their student both content and skills that will make them excited about, and competitive for, the advanced courses needed to move into biomedical research careers. SEEC II will also link teachers together across the elementary/middle school divide and bring the teachers together with administrators and parents, who will experience firsthand the excitement that inquiry learning brings and the significant advancement it provides in science and in reading and math. At monthly meetings and large annual celebrations, the parents, teachers and administrators will learn about the opportunities that biomedical careers can provide for the student who is well prepared. They will also consider the financial and educational steps required to ensure that students have the ability to reach these professions.
SEEC II will also expand CORD’s middle school LabWorks and Summer Science Camps to include grade 4-5 students and provide the teachers with professional learning in informal settings. During summer training, in small groups, the teachers will expand one of the inquiry-based science activities that they complete in the training, and they will use these in their classrooms and communicate with the others in their group to perfect these experiences in the school year. Finally, the teachers and grade 4-5 students will develop science and engineering fair-type research projects with which they will compete both on the school level and at the annual meeting. Thus, the students will share with their parents the excitement that science brings. The Intellectual Merit of SEEC II will be to test a model to enhance grade 4-6 teacher development and vertical alignment, providing science content, exposure to biomedical scientists and training in participatory science experiments, thus positioning teachers to succeed. The Broader Impacts will include the translation and testing of a science education model to assist minority students to avoid the middle school plunge and reach biomedical careers.
The employment demands in STEM fields grew twice as fast as employment in non-STEM fields in the last decade, making it a matter of national importance to educate the next generation about science, engineering and the scientific process. The need to educate students about STEM is particularly pronounced in low-income, rural communities where: i) students may perceive that STEM learning has little relevance to their lives; ii) there are little, if any, STEM-related resources and infrastructure available at their schools or in their immediate areas; and iii) STEM teachers, usually one per school, often teach out of their area expertise, and lack a network from which they can learn and with which they can share experiences. Through the proposed project, middle school teachers in low-income, rural communities will partner with Dartmouth faculty and graduate students and professional science educators at the Montshire Museum of Science to develop sustainable STEM curricular units for their schools. These crosscutting units will include a series of hands-on, investigative, active learning, and standards-aligned lessons based in part on engineering design principles that may be used annually for the betterment of student learning. Once developed and tested in a classroom setting in our four pilot schools, the units will be made available to other partner schools in NH and VT and finally to any school wishing to adopt them. In addition, A STEM rural educator network, through which crosscutting units may be disseminated and teachers may share and support each other, will be created to enhance the teachers’ ability to network, seek advice, share information, etc.
“Tinkering EU: Building Science Capital for All” aims to develop activities and resources that support a learner-centred culture, improve science education and develop 21st century skills - all of which are fundamental for active citizenship, employability, and social inclusion. To do this, it adopts ‘Tinkering’, an innovative pedagogy developed in the USA, which is used by museums, and has proven able to create a lifelong engagement with science for everyone. Tinkering works particularly well for people who argue that “they are not good at science” or are disaffected from any formal teaching and learning process. It can be a powerful tool to tackle disadvantage. The project integrates Tinkering into the school curriculum to develop the science capital of disadvantaged youth through the use of museums. It addresses students from 8 to 14 years old (primary and junior high schools).
Coordinator: National Museum of Science and Technology Leonardo da Vinci
Partners:
University of Cambridge – UK
NEMO Science Museum – The Netherlands
Science Gallery Dublin – Ireland
CosmoCaixa – Spain
Science Center Network – Austria
NOESIS – Greece
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds innovative research, approaches and resources for use in a variety of settings. Blind youth are generally excluded from STEM learning and careers because materials for their education are often composed for sighted individuals. In this proposed Innovations in Development project, the PIs suggest that spatial acuity is an important element in order for blind persons to understand physical and mental structures. Thus, in this investigation, efforts will be made to educated blind youth in the discipline of engineering. A total of 200 blind students, ages 12-20 along with 30 informal STEM educators will participate in the program. This effort is shared with the National Federation of the Blind, Utah State University, the Science Museum of Minnesota, and the Lifelong Learning Group.
The National Federation of the Blind, in partnership with scholars from Utah State University and educators from the Science Museum of Minnesota will develop a five-year Innovations in Development project in order to broaden the participation of blind students in STEM fields through the development of instruction and accessible tools that assess and improve the spatial ability of blind youth. The partnership with the Science Museum will facilitate the creation of informal science content for students and professional development opportunities for informal educators. Evaluation will be conducted by Lifelong Learning Group of the Columbus Center of Science and Industry. Activities will begin in year one with a week-long, engineering design program for thirty blind high-school students at the Federation of the blind headquarters in Baltimore. Year two will feature two similarly sized programs, taking place at the Science Museum. While spatial ability is linked to performance in science, research has not been pursued as to how that ability can be assessed, developed, and improved in blind youth. Further, educators are often unaware of ways to deliver science concepts to blind students in a spatially enhanced manner, and students do not know how to advocate for these accommodations, leading blind youth to abandon science directions. Literature on the influences of a community of practice on youth with disabilities, as well as nonvisual tools for experiencing engineering, is lacking. This project will advance understanding of how blind people can participate in science, and how spatial ability can be developed and bolstered through informal engineering activities and an existing community of practice.