This project augmenting the traditional professional development model with an online professional development platform—the Active Physics Teacher Community—that provides just-in-time support for teachers as they are enacting targeted units of the Active Physics curriculum. Teachers are helped in preparing lessons by providing them with formal instruction related to the lessons they are teaching in the classroom. In addition, teachers can participate in a moderated forum where they can share experiences.
This project is carrying out a research and development initiative to increase the success rates of our most at-risk high school students—ninth-grade students enrolled in algebra classes but significantly underprepared for high school mathematics. It will also result in new understandings about effective approaches for teaching mathematics to struggling students and about effective ways for implementing these approaches at scale, particularly in urban school districts.
Intensified Algebra I, a comprehensive program used in an extended-time algebra class, helps students who are one to two years behind in mathematics become successful in algebra. It is a research and development initiative of the Charles A. Dana Center at The University of Texas at Austin, the Learning Sciences Research Institute at the University of Illinois at Chicago, and Agile Mind, that transforms the teaching of algebra to students who struggle in mathematics. Central to the program is the idea that struggling students need a powerful combination of a challenging curriculum, cohesive, targeted supports, and additional well-structured classroom time. Intensified Algebra I seeks to addresses the need for a robust Algebra I curriculum with embedded, efficient review and repair of foundational mathematical skills and concepts. It aims to address multiple dimensions of learning mathematics, including social, affective, linguistic, and cognitive. Intensified Algebra I uses an asset-based approach that builds on students’ strengths and helps students to develop academic skills and identities by engaging them in the learning experience. The program is designed to help struggling students succeed in catching up to their peers, equipping them to be successful in Algebra I and their future mathematics and science courses.
This project is implementing a program of professional development for teachers and web interface that links scientists with urban classrooms. Scientist mentors work with students and teachers through the web to carry out an original "authentic" inquiry project in plant science. The classroom intervention involves high school biology students working in assigned teams to generate their own research questions in plant science centered on core biology concepts from the National Science Education Standards.
Project Publications and Presentations:
Hemingway, Claire & Packard, Carol (2011, April). Seeds of Wonder and Discovery. Science Scope, v. 34 (8), p. 38.
This project addresses biology teachers and students at the high school level, responding to the exponential increases occurring in biology knowledge today and the need for students to understand the experimental basis behind biology concepts. The project studies the feasibility of engaging students in an environment where they can learn firsthand how science knowledge develops in the fields of bioinformatics and DNA science by performing collaborative, simulated experiments to solve open-ended problems.
This project is refining and testing two case study units on contemporary issues in ecology for urban middle and high school students underserved in their connection to nature. The case studies are based on two Science Bulletins, digital media stories about current science produced by the American Museum of Natural History (AMNH), which use current scientific data to link ecological principles to real-world environmental issues, and to link issues to human daily life.
We developed and tested two ecology case study units for urban high school students underserved in their connection to nature. The case studies, based on digital media stories about current science produced by the American Museum of Natural History, use current scientific data to link ecological principles to daily life and environmental issues. Preliminary testing results show that treatment students made significantly higher gains than the control students on the project's major learning goals.
We have refined and tested wo case study units on contemporary issues in ecology for urban middle and high school students underserved in their connection to nature. The case studies are based on two Science Bulletins, digital media stories about current science produced by the American Museum of Natural History (AMNH), which use current scientific data to link ecological principles to real-world environmental issues, and to link issues to human daily life. One unit asks the question, ‘How might snowy and icy roads affect Baltimore’s water supply?’ The other asks the question, ’How might being able to drive between Los Angeles and Las Vegas in just four hours put local bighorn sheep at risk?’ The units provide source material and real data for students to investigate these questions, video profiles of scientists that engage students in the science and the research, and the Museum Science Bulletins media for students to analyze and connect the questions to broader ecological principles and issues. We are using these modules to research the question, “Can curricular units that link environmental issues to ecological principles through analysis of real data from published research on the environmental impacts of familiar everyday activities improve student learning of ecological principles, personal and human environmental impacts and the nature of scientific activity?”
Randomized control trials in the classrooms of 40 ninth grade NYC public school teachers are being used to evaluate the efficacy of the modules. Assessment items from New York State Regents exams were reviewed and new assessment items were developed, field tested, and analyzed for validity and reliability. Students in the experimental and control classrooms were pre- and post-tested using the assessments. In addition, teachers completed pre-post surveys, and stratified samples of teachers were observed and interviewed. To evaluate the effects of the intervention on student achievement and on instructional practices, descriptive and inferential statistics, including analysis of variance (ANOVA) models are being employed to addressing the core research question about student achievement. ANOVA models are also being used to measure main effects and interactions between the intervention and other variables as they relate to student achievement. Preliminary analysis indicates that treatments students showed signficantly higher gains than control students on learning of three major project learning goals: 1. Understanding of ecological principles in the context of human impact 2. Understanding daily life in the context of human impact 3. Understanding the nature of scientific evidence.
Finally, we will apply our evaluation findings from testing the modules to develop a summative module on oyster fishing in the Chesapeake Bay. Also, in order to disseminate the materials online to a national audience, we will develop an online “kit of parts” of module components to enable teachers to create customized modules that target their students' specific instructional needs.
This project is developing a two-year, intensive professional development model to build middle-grades mathematics teachers’ knowledge and implementation of formative assessment. Using a combination of institutes, classroom practice, and ongoing support through professional learning communities and web-based resources, this model helps teachers internalize and integrate a comprehensive understanding of formative assessment into daily practice.
Formative Assessment in the Mathematics Classroom: Engaging Teachers and Students (FACETS)
This project is submitted as a full research and development project that addresses challenge #3, how can the ability of teachers to provide STEM education be enhanced?
The FACETS project will develop a 2-year, intensive professional development model to build middle grades mathematics teachers’ knowledge and implementation of formative assessment. Using a combination of institutes, classroom practice, and ongoing support through professional learning communities and web-based resources, this model will help teachers internalize and integrate a comprehensive understanding of formative assessment into daily practice. As part of the professional development model, we will create a variety of products:
- a facilitator’s guide describing the components of the professional development model and suggestions for using the model to provide a professional development program,
- cyberlearning products such as interactive forums and a vetted resource library, and
- video and other materials for the professional development activities and resource library.
FACETS includes a formative research component centered on the following questions:
1. How do mathematics teachers’ knowledge and practice of formative assessment change as a result of participation in the proposed professional development?
2. What learning trajectory describes teachers’ learning about formative assessment, and what are common barriers to successful implementation?
Reports of research findings will include journal articles on teachers’ learning trajectory for formative assessment and common barriers to successful implementation faced by teachers.
Intellectual merit: Our field work, supported by existing research, has shown that math teachers have difficulty fully implementing formative assessment in their classroom. Existing professional development programs either present a comprehensive understanding without a focus on mathematics, or focus on mathematics but only emphasize some of the critical aspects needed to bring out the full potential of formative assessment. This project will develop a professional development model that a) presents a comprehensive understanding of formative assessment and b) focuses specifically on mathematics. Furthermore, this project proposes to contribute to the field of mathematics teacher education through a deeper insight into mathematics teachers’ learning and practice of formative assessment. This insight can be used by professional developers and teacher educators in mathematics to make decisions that help teachers progress more effectively in their learning. This project brings together a multi-disciplinary team with expertise in formative assessment, professional development, mathematics, mathematics education, and teacher education research.
Broader impacts: We anticipate that the professional development will have an immediate impact on participating teachers, and on their students, as they learn about and implement formative assessment in their classrooms. Individual districts and schools have expressed an interest in the FACETS professional development program. The New Hampshire State Department of Education also indicates support for statewide implementation. In addition, research results regarding teachers’ learning trajectories for formative assessment will be crucial to inform future professional development and teacher education programs, and to help teachers reflect on, and guide, their own learning. Data regarding the major barriers to teachers’ learning of formative assessment will also impact future professional development by identifying issues needing additional focus, as will data regarding the effect on those barriers of factors such as teaching experience and mathematical knowledge for teaching. Finally, as there is a paucity of video and other examples of formative assessment in mathematics classrooms, the resource library will make widely available a sorely needed resource to teachers grappling with understanding and implementing formative assessment in mathematics classrooms in a practical way.