The Next Generation Science Standards (NGSS) represent a dramatic shift in expectations for K–12 science education, particularly in its inclusion of engineering design. To understand the shifts that schools may need to make, Moore, Tank, Glancy, and Kersten examine the ways in which state K–12 science standards, prior to the adoption of NGSS, included engineering.
How can technology be used to support inquiry in the classroom? In this study, Rehmat and Bailey probe the effects of a science methods course for preservice elementary teachers that explicitly includes technology integration. The preservice teachers in this course broadened their definition of classroom technology, increased their technology use, and gained a more positive outlook on technology integration.
Current science education reforms emphasize the ways in which students’ scientific practices, such as experimenting, collecting data, and interpreting results, develop over time. Bricker and Bell suggest that practices develop not only over time, but also across multiple settings and opportunities. Their study shows how, over several years, one youth’s identification with science was shaped by many everyday moments, social configurations, and collaborators.
Researchers examined whether engineering activities and lessons can help students apply science and math content in real-world contexts and gain insights into the professional activities and goals of engineers.
The new standards posit that “scientific argumentation,” in which students use data to argue from evidence, is a key practice for student science learning. However, a mismatch in expectations about the purpose of classroom discussions can inhibit productive forms of argumentation. Berland and Hammer compare forms of class discussions to identify how best to support students’ engagement in argumentation.
For over a decade, science educators have lamented the ways in which testing in reading and mathematics has reduced time for science instruction. Blank used 20 years of national teacher and student data to understand how time allocated to science instruction combines with student demographics to shape test scores. The study found a small but significant positive relationship between time on science instruction and performance.
Although computer science drives innovations that directly affect our everyday lives, few K–12 students have access to engaging and rigorous computer science learning. This article describes an effort to democratize access to computer science education through a program based on inquiry, culturally relevant curriculum, and equity-oriented pedagogy.
Bathgate, Schunn, and Correnti investigate students’ motivation toward science across three dimensions: the context or setting, the way in which students interact with science materials or ideas, and the activity topic. Findings point to the importance of understanding children’s perceptions of specific science topics, not just science in general.
Flying Higher will develop a permanent hands-on exhibit that conveys the fundamentals of flight, technology, materials science, and NASA’s role in aeronautics for learners ages 3-12 years and their parents/caregivers and teachers. The exhibit, public programs, school and teacher programs, and teacher professional development will develop a pipeline of skilled workers to support community workforce needs and communicate NASA’s contributions to the nation and world. An innovative partnership with Claflin University (an historically black college) and Columbia College (a women’s liberal arts college) will provide undergraduate coursework in informal science education to support pre-service learning opportunities and paid employment for students seeking careers in education and/or STEM fields. The projects goals are:
1) To educate multi-generational family audiences about the principles and the future of aeronautics; provide hands-on, accessible, and immersive opportunities to explore state-of-the-art NASA technology; and demonstrate the cultural impact of flight in our global community.
2) To provide educational standards-based programming to teachers and students in grades K–8 on NASA-driven research topics, giving the students opportunities to explore these topics and gain exposure to science careers at NASA; and to offer teachers support in presenting STEM topics.
3) To create and implement a professional development program to engage pre-service teachers in presenting museum-based programs focused on aeronautics and engineering. This program will provide undergraduate degree credits, service learning, and paid employment to students that supports STEM instruction in the classroom, explores the benefits of informal science education, and encourages post-graduate opportunities in STEM fields.
Moving Beyond Earth Programming: “STEM in 30” Webcasts. The Smithsonian’s National Air and Space Museum (NASM) will develop nine “STEM in 30” webcasts which will be made available to teachers and students in grades 5-8 classrooms across the country. The primary goal of this program is to increase interest and engagement in STEM for students. Formative and summative evaluations will assess the outcomes for the program, which include the following:
Increased interest in STEM and STEM careers, Increased understanding of science, technology, engineering and mathematics (STEM), Increased awareness and importance of current and future human space exploration, and Increased learning in the content areas.
This series of live 30-minute webcasts from the National Air and Space Museum and partner sites focus on STEM subjects that integrate all four areas. The webcasts will feature NASA and NASM curators, scientists, and educators exploring STEM subjects using museum and NASA collections, galleries, and activities. During the 30-minute broadcasts, students will engage with museum experts through experiments and activities, ask the experts questions, and answer interactive poll questions. After the live broadcasts, NASM will also archive the webcasts in an interactive “STEM in 30” Gallery.
This research oriented project integrates the informal and formal science education sectors, bringing their combined resources to bear on the critical need for well-prepared and diverse urban science teachers. It represents a partnership among The City College of New York (CCNY), the New York Hall of Science (NYHOS), and the City University of New York Center for Advanced Study in Education (CUNY-CASE). It integrates the Science Career Ladder, a sustained program of informal science teaching training and employment at the NYHOS, with the CCNY science teacher preparation program. The longitudinal and comparative research study being conducted is designed to examine and document the effect of this integrated program on the production of urban science teachers. Outcomes from this study include a new body of research related to the impact of internships in science centers on improving classroom science teaching in urban high schools. Results are being disseminated to both the informal science education community (through the Association for Science and Technology Centers and the Center for Informal Learning in Schools, an NSF supported Center for Learning and Teaching situated at the San Francisco Exploratorium) and the formal education community (through the National Science Teachers Association and the American Educational Research Association).
The Science Career Ladder program engages undergraduates as inquiry-based interpreters (Explainers) for visitors to the NY Hall of Science. Integrating this experience with a formal teacher certification program enables participants to coordinate experiences in the science center, college science and education classes, and K-12 classrooms. Participants receive a license to teach science upon graduating. The approach has its theoretical underpinnings in the concept of situated learning as noted by Kirshner and Whitson (1997, Situated Cognition: Social, Semiotic and Psychological Perspectives, Mahwah, NJ: Erlbaum). Through apprenticeship experiences, situated learning recreates the complexity and ambiguity of situations that learners will face in the real world. Science centers provide a potentially ideal setting for situational learning by future teachers, allowing them to develop, exercise and refine their science teaching and learning skills as noted by Gardner (1991, The Unschooled Mind, New York: Basic Books).
There is a well-documented shortage of science teachers in urban school districts. The causes of this shortage relate to all phases of the teacher professional continuum, from recruitment through training and retention. At the same time, the demographic composition of American teachers is increasingly out of synch with the demographics of the student population, raising concerns that a critical shortage of role models may be at hand, contributing to a worsening situation in urban schools. In the face of these challenges many innovative teacher recruitment and teacher preparation programs have been developed to augment traditional pathways to teaching. These programs range from high school academies for students expressing an interest in teaching to the recruitment and training of individuals making mid-life career changes. The CLUSTER program described above represents a new alternative. There are more than 250 science centers in the United States. Many of these have extensive youth internship programs and collaborative relationships with local colleges. Therefore, the proposed model is widely applicable.
The Boston Schools Environmental Initiative (BSEI) program worked with several Boston Public schools to foster “hands-on, minds-on” science and environmental awareness. The overall finding from this evaluation, conducted over four academic years, was that the longer a school participated in the BSEI program, the more the culture and operations of the school changed in the direction of the intended BSEI outcomes. BSEI is a program of Mass Audubon’s Boston Nature Center (BNC), which places a teacher naturalist part time in each school, and provides ongoing professional development and project