The science education community is buzzing about STEM learning ecosystems, ecologies of learning, and ecological perspectives on learning. You may not know it, but if your teaching involves building on young people’s prior knowledge or making connections between the science curriculum and science in the broader world, your work may already reflect aspects of ecological learning theories. At the heart of an ecological perspective on learning is the need to make connections across formal, informal, and everyday learning. So, what are STEM learning ecologies all about, and how can science
Connected Science Learning is a journal around which all science, technology, engineering, and math (STEM) educators can gather. The National Science Teachers Association (NSTA) and the Association of Science-Technology Centers (ASTC) have partnered on this National Science Foundation (NSF)–funded project to leverage our extensive combined reach across the formal and informal STEM educator communities. NSTA represents about 50,000 K–12 science educators, while ASTC member science centers and museums are in communities across the globe, reaching 100 million visitors per year, many of whom are
My dream—many would call it a fantasy—is that someday, science will be as pervasive in society as sports. We already have professional science, but imagine the day that we have extensive programs that feature intramural science, after-school science, and that pick-up science activity at the local park. Passionate amateur scientists will exist in abundance: more amateur geologist rock collectors, more amateur paleontologist fossil collectors, more amateur astronomers who write research papers with professional astrophysicists, and more citizen science projects that provide critical data to
In this article, we invite you to expand your vision of what it means to work at the intersections of formal and informal science and literacy education by describing how educators have collaborated to create programs that blend science and literacy in schools, in museums, and across these two spaces. In 2012, K–12 teachers from the National Writing Project (NWP) began working with the Association of Science-Technology Centers (ASTC) and science museum educators in the National Science Foundation–funded Intersections project, which is being evaluated by Inverness Research. NWP is a network
The connections among neuroscience, educational research, and teaching practice have historically been tenuous (Cameron and Chudler 2003; Devonshire and Dommett 2010). This is particularly true in public schools, where so many issues are competing for attention—state testing, school politics, financial constraints, lack of time, and demands from parents and the surrounding community. Teachers and administrators often struggle to make use of advances in educational research to impact teaching and learning (Hardiman and Denckla 2009; Devonshire and Dommett 2010). At the Franklin Institute, we
Omaha’s Henry Doorly Zoo and Aquarium has been a strong and active partner in education for over 40 years, educating 1.7 million visitors annually. The zoo has become a leader in both informal and formal education by pioneering many science, technology, engineering, and mathematics (STEM) initiatives. In 1996 the zoo moved from being a partner with others to becoming a true collaborator with a diverse group of education institutions. The zoo discovered that a successful partnership requires multiple organizations to come together and share resources for a cause. In partnering with school
Imagine two seventh-grade students from communities of color and low socioeconomic backgrounds, of whom at least one is an English-language learner1 (ELL). Both are likely disenfranchised from avenues to success and the ability to see themselves as capable of great things. These students attend school in the largest school districts in Colorado. As part of their seventh-grade science class, they participate in a program called Urban Advantage Metro Denver (UA Denver), which provides them the opportunity to work on a self-selected science project. Their projects are inspired by field trips to
The Exhibit Designs for Girls’ Engagement (EDGE) project is a three-year Exploratorium-run, NSF-funded, research study aiming to identify the most important design attributes for engaging girls at STEM exhibits. We identified nearly 100 exhibit design attributes that had the potential for better engaging girls. To test those 100 attributes and their relationship to girls’ engagement, we studied more than 300 physics, engineering, math, and perception exhibits at the Exploratorium, the Science Museum of Minnesota, and the Arizona Science Center. The purpose of the EDGE research was to winnow
“The activity where we collected organisms was a good influence ’cause I could see myself as a scientist. I got to do the actual thing.” These words from Celeste, a girl who participated in the Coastal Ecology program at the Chincoteague Bay Field Station on the Eastern Shore of Virginia, are not unique. Other girls who participated in the program offered similar input, suggesting that engaging in science in this out-of-school time (OST) setting enhanced their identity and sense of self as learners of science. OST programs like the Coastal Ecology science camp can positively influence science
Commonly described as youth-led or youth-driven, the youth-adult partnership (Y-AP) model has gained increasing popularity in out-of-school time (OST) programs in the past two decades (Larson, Walker, & Pearce, 2005; Zeldin, Christens, & Powers, 2013). The Y-AP model is defined as “the practice of (a) multiple youth and multiple adults deliberating and acting together (b) in a collective (democratic) fashion (c) over a sustained period of time (d) through shared work (e) intended to promote social justice, strengthen an organization and/or affirmatively address a community issue” (Zeldin et al
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Heng-Chieh Jamie WuMariah KornbluhJohn WeissLori Roddy
Young adulthood, typically defined as between the ages of 18 and 25, is a critical period of growth during which young people acquire the education and training that serve as the basis for their later occupations and income (Arnett, 2000). The successful transition from adolescence to early adulthood requires youth to have the skills and resources to graduate high school and then go to college or enter the workforce (Fuligni & Hardway, 2004; Lippman, Atienza, Rivers, & Keith, 2008). To accomplish these tasks in advanced urban societies, young adults need a wide range of social, cognitive
One day, as I was working with a student after school on a problem involving division with decimals, I told him which number goes in the “division house.” Suddenly the student blurted out, “That is not what my teacher told me, and I hate math!” I knew I had not yet found the key to helping this student. Was I addressing how he felt about math? Should I put the problem away and start over with the beauty of decimals, those smaller-than-one numbers that enable us to measure the speed of an Olympic athlete, the diameter of a pinhead, or the exact length of a ladybug? Teaching afterschool allows