CISIP is a professional development program that enables English and science teachers to help students to learn content and communicate scientifically. The CISIP program: Translates How Students Learn Science in the Classroom and Common Core State Standards for student success; targets learning within a classroom discourse community that focuses on argumentation; and takes a team of science and English teachers at schools from middle level through university who collaborate.
This project enhances and expands video-based instruction to help prospective and practicing teachers analyze the development of children's mathematical thinking. It trains teachers to: (a) understand from a cognitive developmental psychology perspective how children learn and think about mathematics; (b) assess children's mathematical knowledge and plan instructional activities accordingly; (c) develop an evidence-based understanding of effective and developmentally appropriate teaching methods and curricula; and (d) develop a basic understanding of key mathematical concepts.
This project is developing a series of print and web resource guides in science and mathematics based on curriculum topic study (CTS), an approach developed and tested successfully. CTS is used to provide a systematic way of intellectually engaging K-12 mathematics and science teachers with national standards and cognitive research. It is used to engage teachers in thought and discussion about both content and appropriate ways of teaching that content.
Project staff are examining and improving elementary school teachers’ knowledge, beliefs, and practices involving their teaching of science to English language learners (ELL) within the policy context of high-stakes testing and accountability in science. The four major research and development areas are (1) teachers’ initial knowledge, beliefs, and practices; (2) professional development intervention; (3) policy contexts; and (4) change over time in teachers and ELL students.
This project is producing a model for a Professional Learning Community (PLC) for pre-calculus teachers in secondary schools. It generates research knowledge from cycles of (1) defining, (2) studying and (3) refining the model and its components. The project leadership team are then be able to describe the support structure, group processes and tools needed to assist secondary pre-calculus teachers in providing high quality instruction for their students.
This project develops video-case modules for use in pre-service teacher preparation programs. Modules target specific grade bands (K-3, 4-5, 6-8) and address standards-based content domains, to help future teachers deepen their content knowledge, pedagogic skills and ability to analyze student thinking. The cases illustrate reform classroom practices and more traditional instruction, include interviews with teachers and students, and incorporate a set of analytic tasks that promote users' critical observations of the cases.
This is a project to develop a learning community model that spans the educational continuum. It connects teacher research participation experience (TRE) projects and science, technology, and mathematics (STM) industry and university scientists/professionals to research the factors that contribute to the success of such a model. It will mine both the Principal Investigator's and TRE projects, education and industry partnership immersion projects, and provide new education/workplace experiences for STM participants.
Project staff are developing modular instructional materials for students. The materials are designed to increase the awareness of and interest in career opportunities in engineering and technology. The modules use authentic, real-world engineering applications and hands-on experiences to build problem-solving skills and contribute to the technological literacy of secondary students. The modules specifically target the ITEA Content Standards for Technological Literacy and related benchmarks.
Project staff are developing a two-year integrated science course for grades 9–10. The Science and Global Issues course includes a complete year of new material, along with a major revision to the Science and Sustainability high school course. This two-year sequence will complete the SEPUP sequence for grades 6–10. When these courses are published, they will provide the equivalent of a year-long biology course and a semester each of chemistry and physics.
This project is developing a bank of mathematics and science assessment items and related tools aligned with state and national content standards that will be available to test developers, curriculum developers, researchers, teachers, teacher educators, parents and students. Specific tools will include a bank of about 300 test items, assessment maps and the inclusion of materials that target students with English as a second language.
This project will advance the research base and leadership capacity supporting K-12 mathematics curriculum design, analysis, implementation and evaluation. It will serve the K-12 educational community by focusing scholarly inquiry and professional development around the issues of mathematics curriculum, examining and characterizing their role and influence on both teaching and student learning. The Center will test strategies and produce new knowledge about the impact of curriculum materials on student and teacher learning.
This project is developing a three-year science program for grades 9, 10, and 11. This program presents the core concepts in physical science, life science, earth-space science, and inquiry as articulated in the National Science Education Standards. The program also engages students in integration across the disciplines in relevant, social contexts to address other standards, and provides high school students and teachers nationwide with a coherent alternative to the traditional sequence of biology, chemistry, and physics.