Women/Girls

Assessing Student Engagement in Math and Science in Middle School: Classroom, Family, and Peer Effects on Engagement

The project will use a comprehensive mixed methods design to develop theoretically-grounded measures of student engagement in middle school math and science classes that reflect a multidimensional construct within an ethnically and socioeconomically diverse sample of urban youth. The project conceptualizes student engagement as a multidimensional construct including behavioral, emotional, and cognitive components. This multidimensional perspective of student engagement provides a rich characterization of how students act, feel, and think.

Lead Organization(s): 
Partner Organization(s): 
Award Number: 
1315943
Funding Period: 
Sun, 09/01/2013 to Thu, 08/31/2017
Full Description: 

The proposed project uses a comprehensive mixed methods design to develop theoretically-grounded measures of student engagement in middle school math and science classes that reflect a multidimensional construct within an ethnically and socioeconomically diverse sample of urban youth. The project conceptualizes student engagement as a multidimensional construct including behavioral, emotional, and cognitive components. This multidimensional perspective of student engagement provides a rich characterization of how students act, feel, and think. The project has three aims which are to 1) develop reliable and valid measures of student engagement in middle school math and science classes for the use of teachers and researchers; 2) field test and validate these measures of student engagement in math and science classes; and 3) test a) whether classroom, peer, and family characteristics predict student engagement in math and science classes, which in turn, predicts their course enrollment patterns, academic achievement, and educational and career aspirations in math and science and b) whether these associations differ by gender, race, and socioeconomic status.

To meet these goals, the proposed project includes two studies. In study 1, twenty-five middle school students and 10 math and 10 science teachers participate in focus groups and individual interviews to inform the development of survey instruments in fulfillment of Aim 1. In study 2, 450 middle school students and their teachers and parents participate in a field study to test the psychometric quality of the newly developed instruments in fulfillment of Aims 2 and 3. The sample is recruited from four middle schools located in a socioeconomically and ethnically diverse community. Data to be collected includes information on math and science course enrollment, performance, educational and career aspirations, student engagement in math and science, and support from teachers, peers, and parents.

This project develops easily-administered and psychometrically sound instruments for teachers and researchers to assess student engagement in math and science classes, so they can identify groups of students who are at risk for disengagement and potentially turning away from STEM careers as a first step towards designing appropriate school interventions. It is anticipated that the project findings provide research-based solutions to some of the specific behaviors that influence youth motivation in math and science. Specifically, the project identifies family, peer, and classroom predictors and educational outcomes of student engagement in math and science classes that are amenable to future interventions, as well as examines differences in the relations between context, engagement, and educational outcomes by gender, race, and socioeconomic status. The study also yields information that can directly and immediately support teachers in the partner school districts to enhance the quality of math and science education. As findings are disseminated to math and science teachers, they are able to develop effective strategies to promote student engagement in math and science. This multidimensional approach will advance current scholarship and practice concerning middle school students' pursuit of math and science related fields.

Climate Change Narrative Game Education (CHANGE)

This exploratory project helps high school students learn complex Global Climate Change (GCC) science by making it personally relevant and understandable. CHANGE creates a prototype curriculum, and integrates it into elective Marine Sciences high school courses. Research will examine the project's impact on student learning of climate science, student attitude toward science, and teacher instruction of climate science.

Lead Organization(s): 
Partner Organization(s): 
Award Number: 
1316782
Funding Period: 
Sun, 09/15/2013 to Wed, 08/31/2016
Full Description: 

This exploratory project helps high school students learn complex Global Climate Change (GCC) science by making it personally relevant and understandable. CHANGE creates a prototype curriculum, and integrates it into elective Marine Sciences high school courses. Research will examine the project's impact on student learning of climate science, student attitude toward science, and teacher instruction of climate science. The goal of this project is to develop a place-based futuristic gaming simulation model that can easily extend to the other locales in other states, based on local climate change effects, local stakeholders, local economic and social effects to motivate the high school students in that area. CHANGE uses: (a) scientifically realistic text narratives about future Florida residents (text stories with local Florida characters, many years in the future based on GCC), (b) local, place-based approach grounded in west-central Florida Gulf Coast using scientific data, (c) a focus on the built environment, (d) simulations & games based on scientific data to help students learn principles of GCC so students can experience and try to cope with the potential long term effect of GCC via role-play and science-based simulation, and (e) a web-based eBook narrative where sections of narrative text alternate with simulations/computer games. The proposed project will work with 25 high school Marine Science teachers in 25 schools in Hillsborough County, Florida. The project delivers new research for instructional technologists and serious game developers regarding effective interface and usability design of intermedia narrative gaming-simulations for education.

This project employs and researches innovative models for delivering high school GCC education. GCC is a complex topic involving numerous factors and uncertainties making teaching this extremely important topic very difficult. The pioneering techniques proposed for this project will advance science education of GCC. It also will deliver new research for instructional technologists and serious game developers regarding effective interface and usability design of intermedia narrative gaming-simulations for education. Effective education is probably the most crucial part in our ability to cope with climate change. CHANGE will educate underserved low SES and minority high school students in Hillsborough County, and later elsewhere, with a model making GCC personally relevant to them.

ITEAMS Longitudinal Study

The objective of this study is to examine the impact of ITEAMS intervention strategies on student persistence in high school STEM course-taking and career expectations, and the value that students place on STEM careers.

Lead Organization(s): 
Award Number: 
1355323
Funding Period: 
Sun, 09/15/2013 to Wed, 04/30/2014
Full Description: 

The objective of this study at Harvard University is to examine the impact of ITEAMS (Innovative Technology-Enabled Astronomy for Middle Schools) intervention strategies on student persistence in high school STEM course-taking and career expectations, and the value that students place on STEM careers. The central research questions are: 1) does ITEAMS participation boost students' STEM course-taking and their interest in, and valuation of, STEM careers throughout their high school years; 2) to what extent did students' ITEAMS experiences, in terms of knowledge and disposition, have an effect; and 3) which ITEAMS strategies or attributes have been most effective in bringing about positive outcomes? Special focus is on the predictors of persistence for girls and minority students.

The project utilizes a mix of interviews and surveys with current high school students who in previous years participated in ITEAMS (DRL-0833378) as middle-school students, and who are now juniors and seniors. The project surveys a randomly selected cohort of 75 former ITEAMS participants who were enrolled in ITEAMS for two or three years. The project-specific survey instrument includes pertinent demographic questions. The random selection of up to 15 surveyed ITEAMS students for in-depth interviews is also included.

Evaluation of the Sustainability and Effectiveness of Inquiry-Based Advanced Placement Science Courses: Evidence From an In-Depth Formative Evaluation and Randomized Controlled Study

This study examines the impact of the newly revised Advanced Placement (AP) Biology and Chemistry courses on students' understanding of and ability to utilize scientific inquiry, on students' confidence in engaging in college-level material, and on students’ enrollment and persistence in college STEM majors. The project provides estimates of the impact of students' AP-course taking on their progress into postsecondary educational experiences and their intent to continue to prepare to be future engineers and scientists.

Award Number: 
1220092
Funding Period: 
Sat, 09/15/2012 to Wed, 08/31/2016
Full Description: 

This study examines the impact of the newly revised Advanced Placement (AP) Biology and Chemistry courses on students' understanding of and ability to apply scientific inquiry, on students' confidence in successfully engaging in college-level material, and on students enrollment and persistence in college STEM majors. AP Biology and Chemistry courses represent an important educational program that operates at a large scale across the country. The extent to which the AP curricula vary in implementation across the schools in the study is also examined to determine the range of students' opportunity to learn the disciplinary content and the knowledge and skills necessary to engage in inquiry in science. Schools that are newly implementing AP courses are participants in this research and the challenges and successes that they experience are also a component of the research plan. Researchers at the University of Washington, George Washington University and SRI International are conducting the study.

The research design for this study includes both formative components and a randomized control experiment. Formative elements include observations, interviews and surveys of teachers and students in the AP courses studied. The experimental design includes the random assignment of students to the AP offered and follows the performances of the treatment and control students in two cohorts into their matriculation into postsecondary educational experiences. Surveys measure students' experiences in the AP courses, their motivations to study AP science, the level of stress they experience in their high school coursework and their scientific inquiry skills and depth of disciplinary knowledge. The study examines the majors chosen by those students who enter into colleges and universities to ascertain the extent to which they continue in science and engineering.

This project informs educators about the challenges and successes schools encounter when they expand access to AP courses. The experiences of the teachers who will be teaching students with variable preparation inform future needs for professional development and support. The project provides estimates of the impact of students' AP-course taking on their progress into postsecondary educational experiences and their intent to continue to prepare to be future engineers and scientists. It informs policy efforts to improve the access to more rigorous advanced courses in STEM and provides strong experimental evidence of the impact of AP course taking. The project has the potential to demonstrate to educational researchers how to study an educational program that operates at scale.

Learning Trajectories to Support the Growth of Measurement Knowledge: Pre-K Through Middle School

This project is studying measurement practices from pre-K to Grade 8, as a coordination of the STEM disciplines of mathematics and science. This research project tests, revises and extends learning trajectories for children's knowledge of geometric measurement across a ten-year span of human development. The goal will be to validate all components of each learning trajectory, goal, developmental progression, and instruction tasks, as well as revising each LT to reflect the outcomes of the experiments.

Lead Organization(s): 
Partner Organization(s): 
Award Number: 
1222944
Funding Period: 
Wed, 08/01/2012 to Tue, 07/31/2018
Full Description: 

This project is studying measurement practices from pre-K to Grade 8, as a coordination of the STEM disciplines of mathematics and science. This four-year, mixed methods research project tests, revises and extends learning trajectories (LTs) for children's knowledge of geometric measurement across a ten-year span of human development. Specifically, research teams from Illinois State University and the University at Denver are working with children in urban and suburban schools to (1) validate and extend prior findings from previous NSF-funded research developing measurement learning trajectories with children in pre-K to Grade 5, and (2) generate and extend portions of trajectories for geometric measurement for Grades 6-8.

The project employs a form of microgenetic studies with 24-50 children per grade from pre-K through Grade 5 representing a stratified random sample from a specific set of suburban schools. These studies will test the validity, replicability and generalizability of the LTs for length, area, and volume. The goal will be to validate all components of each learning trajectory, goal, developmental progression, and instruction tasks, as well as revising each LT to reflect the outcomes of the experiments. Analysis of variance measures with pre/post assessments in an experimental/control design will complement the repeated sessions method of microgenetic analysis.

To explore and extend LTs for children in Grade 6-8, the project employs teaching experiments. This design is used to generate and extend portions of trajectories for geometric measurement, and to explore critical aspects of measurement in clinical and classroom contexts. This work is coordinated with the teaching and learning standards issued by the Council of Chief State School Officials/National Governors Association, the National Council of Teachers of Mathematics, the National Science Teachers Association, the American Association of the Advancement of Science, and the National Research Council with cognitive and mathematics/science education literature. Emerging constructs for the hypothetical LT levels in relation to relevant frameworks generated by other researchers and those implied by standards documents to establish ongoing sequences of the experimental interventions for grades 6-8 are being compared, critiqued and evaluated.

This project provides a longitudinal account of pre-K to Grade 8 children's ways of thinking and understanding mathematical and scientific concepts of measurement based upon empirical analysis. The resulting learning trajectory will represent state of the art integrated, interdisciplinary, theoretically- and empirically-based descriptions of increasingly sophisticated and complex levels of thinking in the domain of measurement (albeit, more tentative for Grades 6-8). This account will be used to verify and/or modify existing accounts of children's development of reasoning from short-term analyses of learning or cross-sectional studies. There are not yet integrative longitudinal studies describing this cognitive domain for area or volume measurement. This trajectory-based analysis of development and instruction supports the design and testing of integrative, formative assessment of individuals and groups of children. Such learning trajectories will be useful in implementing the standard-focused curriculum described in the Common Core State Standards Mathematics and in supporting the multiple large assessment projects currently underway

SimScientists Assessments: Physical Science Links

The goal of this project is to develop and validate a middle school physical science assessment strand composed of four suites of simulation-based assessments for integrating into balanced (use of multiple measures), large-scale accountability science testing systems. It builds on the design templates, technical infrastructure, and evidence of the technical quality, feasibility, and instructional utility of the NSF-funded Calipers II project. The evaluation plan addresses both formative and summative aspects.

Lead Organization(s): 
Award Number: 
1221614
Funding Period: 
Mon, 10/01/2012 to Fri, 09/30/2016
Full Description: 

The goal of this project is to develop and validate a middle school physical science assessment strand composed of four suites of simulation-based assessments for integrating into balanced (use of multiple measures), large-scale accountability science testing systems. It builds on the design templates, technical infrastructure, and evidence of the technical quality, feasibility, and instructional utility of the NSF-funded Calipers II project. The assessment strand consists of multilevel (increased thinking levels) assessment designs grounded on evidence-centered principles that target practices and key disciplinary conceptual schemes, such as matter, motion, energy, and waves identified in the National Research Council report "A Framework for K-12 Science Education: Practices, Crosscutting Knowledge, and Core Ideas". The assessment model vertically links simulations (interactive with feedback to students, coaching, and reflection); curriculum-embedded assessments for formative use; unit benchmark assessment for interim summative purposes; and a set of "signature tasks" (short-term simulations on recurring problem types). Members of the Advisory Board and an Assessment Review Panel actively participate in the development and implementation of this effort. Heller Research Associates is the external evaluator. The evaluation plan addresses both formative and summative aspects.

The project's theory of action is based on model-based learning and evidence-centered design reflective of the notion that the construct of science is multidimensional, requiring (a) understanding how the components of a science conceptual system interact to produce behaviors of the system; and (b) the use of inquiry practices to investigate the dynamic behaviors and underlying components' interactions of the system. A total of eight research and development questions guide the scope of work. The questions focus on: (a) validity (substantive and technical quality) of the individual simulation assessments; and (b) classroom implementation (feasibility, fidelity, utility). The methodology for test construction and revision follows the testing standards of major professional organizations (i.e., American Educational Research Association, American Psychological Association, and National Council of Measurement in Education) through three development phases. Phase I (Assessment Development) focuses on the alignment, quality, and prototype testing, including leverage and modification of prior work, and design of new assessment suites and signature tasks. Phase II (Pilot and Validation Studies) deals with the testing of all assessments, research instruments, and study methods. Phase III (Cross-Validation Studies) substantiates the multilevel integration assessment model, cross-validates the assessments piloted in Phase II, and establishes a reliable argument that the assessments measure the intended content and inquiry practices suitable for use in district and state-level assessment systems.

Expected outcomes are: (1) a research-informed and field-tested physical science simulations-based assessment model with high potential for extended use in middle school grades; and (2) a policy brief that provides recommendations for integrating assessments into districts and state large-scale, multi-level, balanced science assessments.

CAREER: Supporting Computational Algorithmic Thinking (SCAT)—Exploring the Development of Computational Algorithmic Thinking Capabilities in African-American Middle School Girls

The project at Spelman College includes activities that develop computational thinking and encourage middle school, African-American girls to consider careers in computer science. Over a three-year period, the girls attend summer camp sessions of two weeks where they learn to design interactive games. Experts in Computational Algorithmic Thinking as well as undergraduate, computer science majors at Spelman College guide the middle-school students in their design of games and exploration of related STEM careers.

Lead Organization(s): 
Partner Organization(s): 
Award Number: 
1737442
Funding Period: 
Sun, 07/15/2012 to Sun, 06/30/2019
Full Description: 

The Supporting Computational Algorithmic Thinking (SCAT) project at Spelman College includes activities that develop computational thinking and encourage middle school, African-American girls to consider careers in computer science. Over a three-year period, the girls attend summer camp sessions of two weeks where they learn to design interactive games. They participate in workshops, field trips, and game-design competitions. Experts in Computational Algorithmic Thinking as well as undergraduate, computer science majors at Spelman College guide the middle-school students in their design of games and exploration of related STEM careers.

Research on the development of Computational Algorithmic Thinking is an integral part of the project. The researcher is investigating how middle-school girls develop computational thinking and problem solving skills. Game design has been shown to be an area that is attractive to adolescents and it requires extensive problem solving and computational algorithmic thinking. Within the context of designing games individually and within groups, the researcher is assessing how the girls develop computational algorithmic thinking, and what difficulties they experience. Researchers are also assessing how the project experiences influence the students' self-perceptions of themselves as problem solvers. At the same time, the girls engaged in educational experiences where they are expected to gain knowledge in mathematics, programming, and reasoning, as well as game design. Research data consists of artifacts that the students have created, observations, participant journals, and interviews.

Computational Algorithmic Thinking is an essential skill for most STEM careers. African-American women are underrepresented in many STEM fields and especially in computer science. The goals of the project are to prepare girls with these essential skills and to increase their confidence in participating in STEM education. The project is also exposing participating girls to a wide variety of STEM careers. In addition, the materials, lesson plans, and activities generated in the project are available to be used, without charge, by other groups interested in designing similar programs.

This project was previously funded under award #1150098.

An Examination of Science and Technology Teachers' Conceptual Learning Through Concept-Based Engineering Professional Development

This project will determine the viability of an engineering concept-based approach to teacher professional development for secondary school science teachers in life science and in physical science. The project refines the conceptual base for engineering at the secondary level learning to increase the understanding of engineering concepts by the science teachers. The hypothesis is that when teachers and students engage with engineering design activities their understanding of science concepts and inquiry are also enhanced.

Project Email: 
Award Number: 
1158615
Funding Period: 
Thu, 09/01/2011 to Mon, 10/31/2011
Project Evaluator: 
Karen Peterman
Full Description: 

Technology educators from Black Hills State University and Purdue University partner with science educators from the University of Massachusetts at Boston and Stevens Institute of Technology to determine the viability of an engineering concept-based approach to teacher professional development for secondary school science teachers in life science and in physical science. The project refines the conceptual base for engineering at the secondary level learning (previously developed by the PIs) to increase the understanding of engineering concepts by the science teachers. In a pilot test of two weeks of professional development with ten teachers from each discipline, teachers become familiar with engineering concepts and study the process of infusing engineering concepts into science curricula so that they can develop modules in their discipline to be taught during the following in the school year. The following summer the teachers debrief the process and develop additional modules for their discipline. The process is revised and repeated with 22 teachers from each discipline. Teachers are explicitly provided strategies to help them meet the needs of diverse learners. The outputs of this project include: 1) a preliminary framework for secondary level engineering education to be published in both research and practitioner journals; 2) a pilot tested and validated Engineering Concept Assessment; 3) engineering-infused curriculum modules in life and physical science; and 4) a professional development model to prepare science teachers to infuse engineering in their teaching.

The project compares student learning when particular concepts in physics and biology are taught through engineering design with learning the same concepts taught an earlier group of students with present reform techniques used in the discipline. The hypothesis is that when teachers and students engage with engineering design activities their understanding of science concepts and inquiry are also enhanced. The research component of the project employs an iterative design with the design of activities followed by development and implementation. An engineering concept assessment is developed and tested to examine teacher learning and to determine how engineering concepts can be infused into the science curricula for life and physical science. Other quantitative and qualitative instruments are developed to assess the teachers? understandings of the engineering concepts and their pedagogical implications.

There is increasing emphasis on integrative STEM education. New national and international assessments are developing engineering strands and emphasizing non-routine problem solving. The framework for the Next Generation Science Standards includes engineering as one of four strands. Stand alone engineering course are not likely to be widely used. This project develops engineering infused science units and determines the professional development needed to use them effectively.

Designing an Integrated Framework for Genetics Education to Develop Innovative Curricula and Assessments

This project is developing a model for integrating best practices in technology-supported instructional design and formative assessment for genetics instruction in upper elementary, middle and high school. Using the Web-based Inquiry Science Environment platform, the project is developing school curriculum that scaffold and model scientific practices, enable students to interface with real-world problems, provide opportunities for students to make connections between visible phenomena and underlying genetic processes, and promote student monitoring and reflection on learning.

Lead Organization(s): 
Partner Organization(s): 
Award Number: 
1119055
Funding Period: 
Mon, 08/15/2011 to Tue, 07/31/2012
Full Description: 

Michigan State University is developing a model for integrating best practices in technology-supported instructional design and formative assessment for genetics instruction in upper elementary, middle and high school. The project partners with an urban school district in Texas and a suburban school district in Michigan. The objectives are: (1) to articulate a detailed standards- and research-base conceptual framework for describing students' conceptions of genetics and how students develop a full understanding of genetics across grade spans (upper elementary, middle and high school); (2) to develop innovative instructional materials and embedded assessments that provide richer information about students' conceptual understanding of genetics and help practitioners make decisions about what to do next in instruction; and (3) to examine the implementation of these instructional materials and assessments to investigate students' understanding of genetics concepts.

Using the Web-based Inquiry Science Environment (WISE) 4.0 platform (a technology-rich learning environment), the project is developing a 5-week elementary, middle, and secondary school curriculum models that scaffold and model scientific practices, enable students to interface with real-world problems, provide opportunities for students to make connections between visible phenomena and underlying genetic processes, and promote student monitoring and reflection on their learning. Each module will include animation- and stimulation-based contexts in WISE to provide rich occasions to press for building and developing reasoning and explanations. To promote teachers' use of student responses in formative ways, the materials will offer clear guidance about how to make evidence-based instructional decisions as well as provide options for contingent instruction activities that can be used to address persistent or common non-normative ways of reasoning.

The research offers generalizable approaches on the principled design of embedded assessments in WISE 4.0 and on using these assessments formatively. A quasi-experimental study employing a cross-sectional and longitudinal comparison design will investigate the development of students' understanding of genetics-related ideas from upper elementary to the high school years.

Multiple Instrumental Case Studies of Inclusive STEM-Focused High Schools: Opportunity Structures for Preparation and Inspiration (OSPrl)

The aim of this project is to examine opportunity structures provided to students by inclusive STEM-focused high schools, with an emphasis on studying schools that serve students from underrepresented groups. The project is studying inclusive STEM-focused high schools across the United States to determine what defines them. The research team initially identified ten candidate critical components that define STEM-focused high schools and is refining and further clarifying the critical components through the research study.

Lead Organization(s): 
Award Number: 
1118851
Funding Period: 
Thu, 09/01/2011 to Mon, 08/31/2015
Full Description: 

The aim of this project is to examine opportunity structures provided to students by inclusive STEM-focused high schools, with an emphasis on studying schools that serve students from underrepresented groups. In contrast to highly selective STEM-focused schools that target students who are already identified as gifted and talented in STEM, inclusive STEM-focused high schools aim to develop new sources of STEM talent, particularly among underrepresented minority students, to improve workforce development and prepare STEM professionals. A new NRC report, Successful K-12 STEM Education (2011), identifies areas in which research on STEM-focused schools is most needed. The NRC report points out the importance of providing opportunities for groups that are underrepresented in the sciences, especially Blacks, Hispanics, and low-income students who disproportionately fall out of the high-achieving group in K-12 education. This project responds specifically to the call for research in the NRC report and provides systematic data to define and clarify the nature of such schools. 

The project is studying inclusive STEM-focused high schools across the United States to determine what defines them. The research team initially identified ten candidate critical components that define STEM-focused high schools and is refining and further clarifying the critical components through the research study. The first phase of the study is focusing on 12 well-established and carefully planned schools with good reputations and strong community and business support, in order to capture the critical components as intended and implemented. Case studies of these high-functioning schools and a cross-case analysis using a set of instruments for gauging STEM design and implementation are contributing toward building a theory of action for such schools that can be applied more generally to STEM education. The second phase of the study involves selecting four school models for further study, focusing on student-level experiences and comparing student outcomes against comprehensive schools in the same district. Research questions being studied include: 1) Is there a core set of likely critical components shared by well-established, promising inclusive STEM-focused high schools? Do other components emerge from the study? 2) How are the critical components implemented in each school? 3) What are the contextual affordances and constraints that influence schools' designs, their implementation, and student outcomes? 4) How do student STEM outcomes in these schools compare with school district and state averages? 5) How do four promising such schools compare with matched comprehensive high schools within their respective school districts, and how are the critical components displayed? 6) From the points of view of students underrepresented in STEM fields, how do education experiences at the schools and their matched counterparts compare? And 7) How do student outcomes compare?

The research uses a multiple instrumental case study design in order to describe and compare similar phenomena. Schools as critical cases are being selected through a nomination process by experts, followed by screening and categorization according to key design dimensions. Data sources include school documents and public database information; a survey, followed by telephone interviews that probe for elaborated information, to provide a systematic overview of the candidate components; on-site visitations to each school provide data on classroom observations at the schools; interviews with students, teachers and administrators in focus groups; and discussions with critical members of the school community that provide unique opportunities to learn such as mentors, business leaders, and members of higher education community that provide outside of school learning experiences. The project is also gathering data on a variety of school-level student outcome indicators, and is tracking the likely STEM course trajectories for students, graduation rates, and college admission rates for students in the inclusive STEM-focused schools, as compared to other schools in the same jurisdiction. Analysis of the first phase of the study aims to develop rich descriptions that showcase characteristics of the schools, using axial and open coding, to determine a theory of action that illustrates interconnections among context, design, implementation, and outcome elements. Analysis of the second phase of the study involves similar processes on four levels: school, student, databases, and a synthesis of the three. Evaluation of the project consists of an internal advisory board and an external advisory board, both of which provide primarily formative feedback on research procedures.

Research findings, as well as case studies, records of instrument and rubric development and use, annual reports, and conference proposals and papers are being provided on a website, in order to provide an immediate and ongoing resource for education leaders, researchers and policymakers to learn about research on these schools and particular models. An effort is also being made to give voice to the experiences of high school students from the four pairs of high schools studied in the second phase of the study. Findings are also being disseminated by more traditional means, such as papers in peer-reviewed journals and conference presentations.

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