In The Nature of Community: SCIENCES, we share the lessons learned from an innovative partnership designed to leverage the strengths of two nonprofit organizations—a large cultural institution and a smaller, deeply-rooted community-based organization, both of which offer informal science education expertise.
You’ll read first-hand reflections of how staff members, community leaders and members, children, and adults experienced this partnership: the expectations, surprises, challenges, successes, and lessons learned. We hope the description of this partnership inspires other organizations to
The Science Fairs Under the 'Scope Study's key findings are summarized here on the topics of:
Models And Elements Of Middle School Science Fairs
Science And Engineering Practices
Cost Of Science Fairs
Parent Involvement In Science Fairs
Science Interest And Identity.
We collected data from middle school science fairs held in schools across the country to understand:
What are the basic models and elements of middle school science fairs;
If and how science fairs increase students’ interest in science, technology, engineering or math (STEM) and/or STEM careers
If and how participation in select models of middle school science fairs enhance students’ mastery of the science and engineering practices; and
What costs and resources are required to implement an effective middle school science fair?
In this article we explore how activity design and learning contexts can influence youth failure mindsets through a case study of five youth who described failure as sometimes a good thing and sometimes a bad thing (a perspective we characterize as Failure as Mosaic, described in the article). These youth and their descriptions of failure-positive and failure-negative experiences offer a unique opportunity to identify how experiences can be designed to support learning and persistence. In order to understand differing views of failure among youth, we researched the following questions:
Seeking to use narrative as a vehicle for getting more young people interested in STEM, the National Science Foundation supported a WETA/PBS NewsHour initiative to adapt their Student Reporting Labs (SRL) curriculum to feature a focus on STEM content in 2015. NewsHour selected Knology to run a four-year evaluation of the project from 2015 to 2019. Building on earlier research about student-led science journalism (e.g. Polman & Hope, 2014; Nicholas, 2017), this project suggests that having students develop and produce narratives about complex STEM topics may make these topics far less
Growing Beyond Earth (GBE) is Fairchild’s NASA-funded classroom science project designed to advance research on growing plants aboard spacecraft. As NASA looks toward a long term human presence beyond Earth orbit, there are specific science, technology, engineering, and math (STEM) challenges related to food production. GBE is addressing those challenges by expanding the diversity and quality of edible plants that can be grown in space. On Earth, GBE is also improving technologies for gardening in urban, indoor, and other resource-limited settings.
GBE is unique in its focus on real
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TEAM MEMBERS:
Marion LitzingerCatherine RaymondCarl LewisAmy Padolf
This essay discusses how gender-focused culture change initiatives developed for science (like Athena SWAN) might offer models for science communication. Such initiatives can seek to mobilise change amongst university departments and practices, but there are also potential pitfalls in such approaches. Using experiences in a department at UWE Bristol as a basis, the article will consider whether such schemes in science offer potential for science communication to reflect on its own gender imbalances.
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TEAM MEMBERS:
Clare Wilkinson
resourceresearchProfessional Development, Conferences, and Networks
There is a significant under-representation of women in STEM which is damaging societal progress for democratic, utilitarian, and equity reasons. However, changing stereotypes in STEM requires a solution denied by the problem — more visible female role models. Science communicators are critical to curate the conditions to bypass this Catch 22. We propose that enhancing self-efficacy for female scientists and engineers to mentor others will generate more supportive workplaces. Similarly, enhancing self-efficacy for public engagement improves the visibility of diverse female role models for
Feminist technoscience theory offers perspectives for science communication that both question common narratives and suggests new narratives. These perspectives emphasize issues of ethics and care often missing from science communication. They focus on questions of what is marginalized or left out of stories about science — and encourage us to make those absences visible.
This commentary introduces feminist standpoint theory and discusses its potential value in science communication. It offers two ways in which feminist standpoints can help in both research and practice. First, science communicators should aim to understand the perspective from which they understand and share scientific knowledge. Second, practitioners and researchers alike should seek insights from marginalized groups to help inform the ways the dominant view of science reflects hegemonic social and cultural norms.
As science communication develops as a field of both practice and research, it needs to address issues of equity, diversity, and inclusion across a wide range, including race, power, class, gender. Doing so will require deeper understanding of conceptual work and practical activities that address those issues. This brief comment introduces a series of commentaries that provide one approach: feminist approaches to science communication.
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.