In prior research and development, the project team developed PocketLab, a set of web-based hands-on science simulations for middle school classrooms. With this Phase I funding, the team will develop and test a prototype of CloudLab, a classroom management platform to extend the functionality of PocketLab. The prototype will include a portal so that a class of students can collaborate on experiments, a lab notebook to analyze experimental data with graphing tools, and a teacher dashboard to monitor student progress in real time. In the Phase I pilot research, with six middle school teachers and 150 students, the project team will examine whether the prototype functions as planned, whether teachers are able to integrate it within the classroom environment, and whether students are engaged while using the prototype.
The U.S. Education system is becoming more and more diverse and educators must adapt to continue to be effective. Educators must embrace the diversity of language, color, and history that comprises the typical classroom; this means becoming culturally competent. In doing so, comes with it the prospect of using culture to enhance the learning experience for students and the educator. Although the process of becoming culturally competent can be outlined, the realization of a culturally competent educator depends on changing one’s own perceptions and beliefs. The need for cultural competency and
Students in the U.S. educational system are increasingly diverse, and this diversity is reflected in science, technology, engineering, and mathematics (STEM) fields. Diversity in education encompasses students from many races, genders, and socioeconomic backgrounds; students who speak a variety of languages; and students from many cultures. For instance, ethnic diversity increased by 5% across primary and secondary public schools from 2000 to 2007 (Aud, Fox, & KewalRamani, 2010). Diversity is also evident in the socioeconomic make-up of students, with almost half of 4th graders in public
Learn how to create opportunities for young people from low-income, ethnically diverse communities to learn about growing food, doing science, and how science can help them contribute to their community in positive ways. The authors developed a program that integrates hydroponics (a method of growing plants indoors without soil) into both in-school and out-of-school educational settings.
The Common Core's higher academic standards are forcing schools into a false dichotomy of reducing playtime in favor of more time to learn math and literacy. But play can deepen learning even in core content areas.
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
Produced by the Climate Change Education Partnership (CCEP) Alliance, the "Climate Change Education: Effective Practices for Working with Educators, Scientists, Decision Makers and the Public" guide provides recommendations for effective education and communication practices when working with different types of audiences. While effective education has been traditionally defined as the acquisition of knowledge, Alliance programs maintain a broader definition of “effective” to include the acquisition and use of climate change knowledge to inform decision-making.
The CCEP Alliance is supported
Students can present their classroom work in a number of ways. One popular approach is an open house at the school. Such events often feature booths where parents and students can participate in various learning activities. Because these open houses usually only cater to the students and families associated with that particular school, the impact is limited to those people, and the wider local community is not engaged in students’ learning. Additionally, in rural areas, these types of events are sometimes difficult for families to attend during weekdays or weeknights, due to distance and work
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TEAM MEMBERS:
Robin CooperKim ZeidlerDiane JohnsonJennifer Wilson
The Science Museum of Minnesota (SMM) leverages a professional educator team (“instructors”) comprised of about two dozen individuals who facilitate both formal and informal educational programming in the museum, in K–12 classrooms, and at community-based sites. The experienced instructors of SMM’s Lifelong Learning Group bring innovative programs to both students and their teachers. Recognizing that long-term experiences can have a profound impact on students and teachers, SMM works to develop multiyear relationships based on collaboration. This article focuses primarily on SMM’s well
This project will advance efforts of the Innovative Technology Experiences for Students and Teachers (ITEST) program to better understand and promote practices that increase students' motivations and capacities to pursue careers in fields of science, technology, engineering, or mathematics (STEM) by producing empirical findings and/or research tools that contribute to knowledge about which models and interventions with K-12 students and teachers are most likely to increase capacity in the STEM and STEM cognate intensive workforce of the future.
The LinCT (Linking Educators, Youth, and Learners in Computational Thinking) project at the Science Museum of Minnesota (SMM) will engage female teachers-in-training and youth from underrepresented demographics in immersive technology experiences and STEM education. LinCT will guide teachers to develop their understanding and use of technology in the classroom, as well as prepare youth for a future where technology plays a key role in a wide range of professional opportunities. The project aims to inspire teachers and youth to see the possibilities of technological competencies, as well as why the incorporation of technology can build meaningful learning experiences and opportunities for all learners. The LinCT program model offers learning and application experiences for participating teachers and youth and provides an introduction of technological tools used in SMM educational programs and professional development on approaches for engaging all learners in STEM. Both groups will provide instruction in SMM technology-based Summer Camps, reaching 1,000 young people every year. In each following school year, project educators will develop and deliver technology-based programs to nearly 1,000 under-served and underrepresented elementary students. The project will allow teachers and youth to deliver exciting and engaging technology-based programs to nearly 4,000 diverse young learners. As a result, all participants in this project will be better equipped to incorporate technology in their future careers.
The LinCT project will investigate effective approaches for broadening the participation of underrepresented populations by providing female pre-service teachers and female youth with opportunities to lead programming at the Science Museum of Minnesota (SMM). Over three years, the LinCT project will employ 8-12 female teachers-in-training [Teacher Tech Cadres (TTC)] and 12-24 female youth [Youth Teaching Tech Crews (Y-TTC)] from demographics that are underrepresented in STEM fields. The integration of these groups will result in relationships fostered within an educational program, where all participants are learners and teachers, mentors and mentees. The results of this unique program model will be assessed through the experiences of this focused professional learning and teaching community. The LinCT research study will focus on three aspects of the project. First, it will seek to understand how the teachers-in-training and youth experience the project model's varied learning environments. Next, the study will explore how the TTC's and the Y-TTC's motivation, confidence, and self-efficacy with integrating technology across educational settings change because of the program. Finally, the study will seek to understand the lasting aspects of culture, training, and community building on SMM's internal teams and LinCT partner institutions (University of St. Catherine's National Center for STEM Elementary Education and Metropolitan State University's School of Urban Education).
Have you ever been to a professional development (PD) session where you sat and listened to someone speak for hours—and likely got a bit bored? As teachers, we know that best practice is to encourage hands-on learning, but we forget to implement this strategy when creating PD experiences. Exploration Place (EP), the Sedgwick County Science and Discovery Center in Wichita, Kansas, partnered with eight rural school districts in neighboring Sumner County, threw out the traditional sage-on-a-stage paradigm, and tried something new.
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TEAM MEMBERS:
Jan LuthKimberly McDowellLaurel Zhang
Stephanie Spiris is a 12-year veteran teacher at George Washington High School in Denver, teaching courses in biomedical science (Figure 1). Last year, Spiris spent four weeks in a summer internship at Terumo BCT, a medical device company that focuses on blood processing for medical treatment and care. Decked in full lab gear and ready to learn, Spiris worked in a sterile lab, conducting projects that allowed her firsthand experience with tasks such as separating t-cells from blood and freeze-drying plasma.