High School

Sonified Interactive Simulations for Accessible Middle School STEM

For this project, researchers will iteratively develop simulations to include sonifications, non-speech sounds that represent visual information, aimed at enhancing accessibility for all learners, but particularly for those with visual impairments to produce sonified simulations, professional development resources, design guidelines and exemplars, and publications.

Lead Organization(s): 
Award Number: 
1621363
Funding Period: 
Sat, 10/01/2016 to Mon, 09/30/2019
Full Description: 

Students with disabilities often have fewer opportunities for experiential learning, an important component of quality STEM education. Computer based simulations in science can provide valuable opportunities for these students to experience and manipulate natural phenomena related to critical STEM ideas. However, existing simulations remain largely inaccessible to students with visual impairments in particular. Recent advances in technology related to sonification use with simulations can make it possible for these students to have a more complete and authentic experience. Sonification is the use of non-speech sounds, such as musical tones, to represent visual information including data. Such sounds can be manipulated temporally and spatially and can also vary by amplitude and frequency to convey information that is more traditionally displayed visually. 

Researchers will iteratively develop five middle school physical science simulations to include sonifications aimed at enhancing accessibility for all learners, but particularly for those with visual impairments. Data collection activities will include focus groups and interviews with students and teachers focused on engagement. The end products of this project will include sonified simulations, professional development resources, design guidelines and exemplars, and publications.

Analysis of Effective Science Coaching: What, Why and How

This project will conduct an in-depth analysis of instructional coaching by analyzing archived video-recorded coaching sessions with middle and high school science teachers. The goal of the project is to analyzing the videos and previously collected quantitative outcome data to create descriptive profiles of instructional coaching and identify which key coaching elements lead to desired teacher and student outcomes.

Lead Organization(s): 
Award Number: 
1621308
Funding Period: 
Sat, 10/01/2016 to Mon, 09/30/2019
Full Description: 

This Exploratory project will conduct an in-depth analysis of instructional coaching by analyzing 520 hours of archived video-recorded coaching sessions with 75 middle and high school science teachers in grades 6-12 collected in a U.S. Department of Education IES-funded coaching research study. The goal of the project is to "unpack" the coaching intervention by analyzing the videos and previously collected quantitative outcome data to (a) create descriptive profiles of instructional coaching and (b) identify which key coaching elements ("active ingredients") lead to desired teacher and student outcomes.

Following a design-based research approach, relying on iterative feedback and using data saturation process to analyze data, the project will translate theorized, conceptual characteristics of coaching into empirical models to guide future coaching research and practical guidance through identification of critical elements needed for coaching to work.

InquirySpace 2: Broadening Access to Integrated Science Practices

This project will create technology-enhanced classroom activities and resources that increase student learning of science practices in high school biology, chemistry, and physics. InquirySpace will incorporate several innovative technological and pedagogical features that will enable students to undertake scientific experimentation that closely mirrors current science research and learn what it means to be a scientist.

Lead Organization(s): 
Partner Organization(s): 
Award Number: 
1621301
Funding Period: 
Thu, 09/15/2016 to Tue, 08/31/2021
Full Description: 

This project will create technology-enhanced classroom activities and resources that increase student learning of science practices in high school biology, chemistry, and physics courses. The project addresses the urgent national priority to improve science education as envisioned in the Next Generation Science Standards (NGSS) by focusing less on learning facts and equations and instead providing students with the time, skills, and resources to experience the conduct of science and what it means to be a scientist. This project builds on prior work that created a sequence of physics activities that significantly improved students' abilities to undertake data-based experiments and led to productive independent investigations. The goal of the InquirySpace project is to improve this physics sequence, extend the approach to biology and chemistry, and adapt the materials to the needs of diverse students by integrating tailored formative feedback in real time. The result will be student and teacher materials that any school can use to allow students to experience the excitement and essence of scientific investigations as an integral part of science instruction. The project plans to create and iteratively revise learning materials and technologies, and will be tested in 48 diverse classroom settings. The educational impact of the project's approach will be compared with that of business-as-usual approaches used by teachers to investigate to what extent it empowers students to undertake self-directed experiments. To facilitate the widest possible use of the project, a complete set of materials, software, teacher professional development resources, and curriculum design documents will be available online at the project website, an online teacher professional development course, and teacher community sites. The Discovery Research K-12 program (DRK-12) seeks to significantly enhance the learning and teaching of science, technology, engineering and mathematics (STEM) by preK-12 students and teachers, through research and development of innovative resources, models and tools (RMTs). Projects in the DRK-12 program build on fundamental research in STEM education and prior research and development efforts that provide theoretical and empirical justification for proposed projects.

InquirySpace will incorporate several innovative technological and pedagogical features that will enable students to undertake scientific experimentation that closely mirrors current science research. These features will include (1) educational games to teach data analysis and interpretation skills needed in the approach, (2) reduced dependence on reading and writing through the use of screencast instructions and reports, (3) increased reliance on graphical analysis that can make equations unnecessary, and (4) extensive use of formative feedback generated from student logs. The project uses an overarching framework called Parameter Space Reasoning (PSR) to scaffold students through a type of experimentation applicable to a very large class of experiments. PSR involves an integrated set of science practices related to a question that can be answered with a series of data collection runs for different values of independent variables. Data can be collected from sensors attached to the computer, analysis of videos, scientific databases, or computational models. A variety of visual analytic tools will be provided to reveal patterns in the graphs. Research will be conducted in three phases: design and development of technology-enhanced learning materials through design-based research, estimation of educational impact using a quasi-experimental design, and feasibility testing across diverse classroom settings. The project will use two analytical algorithms to diagnose students' learning of data analysis and interpretation practices so that teachers and students can modify their actions based on formative feedback in real time. These algorithms use computationally optimized calculations to model the growth of student thinking and investigation patterns and provide actionable information to teachers and students almost instantly. Because formative feedback can improve instruction in any field, this is a major development that has wide potential.

Zoom In! Learning Science with Data

This project will address the need for high quality evidence-based models, practices, and tools for high school teachers and the development of students' problem solving and analytical skills by leveraging novel research and design approaches using digital tools and two well-established online instructional platforms: Zoom In and Common Online Data Analysis Platform.            

Award Number: 
1621289
Funding Period: 
Thu, 09/15/2016 to Sat, 08/31/2019
Full Description: 

This project will expand the DRK-12 portfolio by contributing to a limited program portfolio on data science, and also by being responsive to a broader, national discourse on data science, exemplified in the data-dependent scientific practices emphasis in the Next Generation Science Standards (NGSS). With the impetus toward data literacy, an acute need has emerged for high quality evidence-based models, practices, and tools to better prepare high school teachers to teach data skills and for students to develop the problem solving and analytical skills needed to interpret and understand data, particularly in the sciences. This project will address these challenges by leveraging novel research and design approaches, using digital tools and two well-established online instructional platforms; Zoom In and Common Online Data Analysis Platform.

With a user base of over 27,000 teachers and students, the existing Zoom In platform has proven successful in fostering evidence-based inquiry among social studies teachers. This project will test the feasibility of the platform to facilitate data-focused inquiry and skill development among high school science teachers and their students. In Year 1, two NGSS-aligned digital curriculum modules and supporting materials focused on scientific phenomena and problems in biology and earth science will be developed for high school science teachers and embedded in a modified iteration of Zoom In. The Common Online Data Analysis Platform (CODAP) will be integrated into the modules to make hierarchical data structures, modeling, visualizations, and dynamic linking possible within Zoom In. A pilot and usability test will be conducted with 16 teachers and 100 students from diverse New York City public high schools. Two teacher focus groups and think-aloud sessions with the students will be held. In Year 2, the remaining four modules will be developed. Guided by four research questions, field testing with teachers and students will be done to assess the content, CODAP data tools, Zoom-in student supports, teacher supports, and outcome measures. In Year 3, final revisions to the tools will be completed. A small-scale efficacy test will be conducted to assess aspects of the implementation process, practices, and overall impact of the modules on student learning. For the efficacy study, a two-level cluster-randomized design will be employed to randomly assign schools to the Zoom In intervention. A comparison group will use another existing well-designed data literacy digital instructional platform but without key aspects of Zoom In. Outcome measures will be administered at the beginning and end of the school year to the treatment and comparison groups. Back-end data, observational data, and teacher log data will be collected and analyzed. Qualitative data will be gathered from teacher and student observations and interviews and analyzed. Researchers will analyze the impact on student learning using hierarchical linear models with an effect treatment condition and student-and-class-level covariates. The research findings will be broadly disseminated through the Zoom In platform, conferences, publications, and social media.


Project Videos

2019 STEM for All Video Showcase

Title: Zoom In! Learning Science with Data

Presenter(s): Megan Silander & Bill Tally


Learning Evolution through Human and Non-Human Case Studies

This project will develop and test two curriculum units on the topic of evolution for high school general biology courses, with one unit focusing primarily on human case studies to teach evolution and one unit focusing primarily on case studies of evolution in other species. The two units will be compared to examine how different approaches to teaching evolution affect students and teachers.

Lead Organization(s): 
Award Number: 
1621194
Funding Period: 
Thu, 09/15/2016 to Tue, 08/31/2021
Full Description: 

This project aligns with Alabama's College & Career-Ready Standards (CCRS) for biology in grades 9-12 relating to Unity and Diversity. These standards are based on the Next Generation Science Standards (NGSS) and go into effect during the 2016-2017 school year. Building on prior work (DRL-119468), this project will develop and test two curriculum units on the topic of evolution for high school general biology courses, with one unit focusing primarily on human case studies to teach evolution and one unit focusing primarily on case studies of evolution in other species. The two units will be compared to examine how different approaches to teaching evolution affect students and teachers. The project will also develop and field test a Cultural and Religious Sensitivity (CRS) Resource to provide teachers with strategies for creating supportive learning environments where understanding of the scientific account of evolution is aided while also acknowledging the cultural controversy associated with learning about evolution. The impacts on student and teacher outcomes of using the curriculum units and the CRS Resource will be tested in classrooms by comparing the outcomes of the human versus non-human units, and by using or not using classroom strategies from the CRS Resource.

The project will examine student and teacher outcomes of four treatment groups: 1) Curriculum Unit 1, 2) Curriculum Unit 1 with the CRS Resource, 3) Curriculum Unit 2, and 4) Curriculum Unit 2 with the CRS Resource. The research questions are: 1) In what ways does using examples of human versus non-human evolution to teach core evolutionary concepts affect understanding of, acceptance of, and motivation to learn about evolution among high school introductory biology students? 2) In what ways do using teaching strategies that focus on acknowledging the cultural controversy about evolution using a procedural neutrality approach affect high school introductory biology teachers' comfort and confidence with teaching evolution? 3) In what ways does using examples of human versus non-human evolution to teach fundamental evolutionary concepts in conjunction with teaching strategies that focus on acknowledging the cultural controversy about evolution using a procedural neutrality approach affect understanding of, acceptance of, and motivation to learn about evolution among high school introductory biology students? And 4) In what ways does using examples of human versus non-human evolution to teach fundamental evolutionary concepts in conjunction with teaching strategies that focus on acknowledging the cultural controversy about evolution using a procedural neutrality approach affect high school introductory biology teachers' comfort and confidence with teaching evolution? The project will use a 2 X 2 X 2 mixed factorial quasi-experimental research design to answer these questions, and will include a total of 32 teachers, 8 in each treatment group, along with approximately 800 students. Each assessment will be administered as a pretest two weeks prior to starting the curriculum unit and as a posttest immediately after completing the unit. Test scores will be the within-subjects factors, and Curriculum Unit and CRS Resource will be the between-subjects factors.

Geological Models for Explorations of Dynamic Earth (GEODE): Integrating the Power of Geodynamic Models in Middle School Earth Science Curriculum

This project will develop and research the transformational potential of geodynamic models embedded in learning progression-informed online curricula modules for middle school teaching and learning of Earth science. The primary goal of the project is to conduct design-based research to study the development of model-based curriculum modules, assessment instruments, and professional development materials for supporting student learning of (1) plate tectonics and related Earth processes, (2) modeling practices, and (3) uncertainty-infused argumentation practices.

Lead Organization(s): 
Award Number: 
1621176
Funding Period: 
Mon, 08/15/2016 to Fri, 07/31/2020
Full Description: 

This project will contribute to the Earth science education community's understanding of how engaging students with dynamic computer-based systems models supports their learning of complex Earth science concepts regarding Earth's surface phenomena and sub-surface processes. It will also extend the field's understandings of how students develop modeling practices and how models are used to support scientific endeavors. This research will shed light on the role uncertainty plays when students use models to develop scientific arguments with model-based evidence. The GEODE project will directly involve over 4,000 students and 22 teachers from diverse school systems serving students from families with a variety of socioeconomic, cultural, and racial backgrounds. These students will engage with important geoscience concepts that underlie some of the most critical socio-scientific challenges facing humanity at this time. The GEODE project research will also seek to understand how teachers' practices need to change in order to take advantage of these sophisticated geodynamic modeling tools. The materials generated through design and development will be made available for free to all future learners, teachers, and researchers beyond the participants outlined in the project.

The GEODE project will develop and research the transformational potential of geodynamic models embedded in learning progression-informed online curricula modules for middle school teaching and learning of Earth science. The primary goal of the project is to conduct design-based research to study the development of model-based curriculum modules, assessment instruments, and professional development materials for supporting student learning of (1) plate tectonics and related Earth processes, (2) modeling practices, and (3) uncertainty-infused argumentation practices. The GEODE software will permit students to "program" a series of geologic events into the model, gather evidence from the emergent phenomena that result from the model, revise the model, and use their models to explain the dynamic mechanisms related to plate motion and associated geologic phenomena such as sedimentation, volcanic eruptions, earthquakes, and deformation of strata. The project will also study the types of teacher practices necessary for supporting the use of dynamic computer models of complex phenomena and the use of curriculum that include an explicit focus on uncertainty-infused argumentation.

Development and Empirical Recovery for a Learning Progression-Based Assessment of the Function Concept

The project will design an assessment based on learning progressions for the concept of function - a critical concept for algebra learning and understanding. The goal of the assessment and learning progression design is to specifically incorporate findings about the learning of students traditionally under-served and under-performing in algebra courses.

Lead Organization(s): 
Award Number: 
1621117
Funding Period: 
Thu, 09/15/2016 to Mon, 08/31/2020
Full Description: 

The project will design an assessment based on learning progressions for the concept of function. A learning progression describes how students develop understanding of a topic over time. Function is a critical concept for algebra learning and understanding. The goal of the assessment and learning progression design in this project is to specifically incorporate findings about the learning of students traditionally under-served and under-performing in algebra courses. The project will include accounting for the social and cultural experiences of the middle and high school students when creating assessment tasks. The resources developed should impact mathematics instruction (especially for algebra courses) by creating a learning progression which captures the range of student performance and appropriately places them at distinct levels of performance. The important contribution of the work is the development of a learning progression and related assessment tasks that account for the experiences of students often under-served in mathematics. The Discovery Research K-12 program (DRK-12) seeks to significantly enhance the learning and teaching of science, technology, engineering and mathematics (STEM) by preK-12 students and teachers, through research and development of innovative resources, models and tools (RMTs). Projects in the DRK-12 program build on fundamental research in STEM education and prior research and development efforts that provide theoretical and empirical justification for proposed projects.

The learning progression development will begin by comparing and integrating existing learning progressions and current research on function learning. This project will develop an assessment of student knowledge of function based on learning progressions via empirical recovery (looking for the reconstruction of theoretical levels of the learning theory). Empirical recovery is the process through which data will be collected that reconstruct the various levels, stages, or sequences of said learning progression. The development of tasks and task models will include testing computer-delivered, interactive tasks and rubrics that can be used for human and automated scoring (depending on the task). Item response theory methods will be used to evaluate the assessment tasks' incorporation of the learning progression.


Project Videos

2019 STEM for All Video Showcase

Title: Concept of Function Learning Progression

Presenter(s): Edith Graf, Frank Davis, Chad Milner, Maisha Moses, & Sarah Ohls


Supporting Success in Algebra: A Study of the Implementation of Transition to Algebra

The project will research the implementation of Transition to Algebra, a year-long mathematics course for underprepared ninth grade students taken concurrently with Algebra 1 to provide additional support, and its impact on students' attitudes and achievement in mathematics in combination with teachers' instruction and the types of supports teachers need to successfully implement the intervention.

Partner Organization(s): 
Award Number: 
1621011
Funding Period: 
Sat, 10/01/2016 to Wed, 09/30/2020
Full Description: 

The project will research the impact and implementation of Transition to Algebra, a year-long mathematics course for underprepared ninth grade students taken concurrently with Algebra 1 to provide additional support. Nationally, there is a need for programs that support students' learning of algebra and that provide research-based resources and models particularly for students in need of additional support. The design of the Transition to Algebra curriculum reflects the idea that students underprepared for Algebra 1 can benefit from very specific help in building the logic of algebra by connecting arithmetic pattern and algebraic structure. The materials feature the use of mental mathematics, puzzles, explorations, and student dialogues to connect arithmetic pattern to algebraic structure. These features should encourage students to expect mathematics ideas to make sense, and to build algebraic habits of mind and problem solving stamina. The research will investigate the effects of the curriculum on students' algebra achievement and their attitudes towards mathematics. The Discovery Research PreK-12 program (DRK-12) seeks to significantly enhance the learning and teaching of science, technology, engineering and mathematics (STEM) by preK-12 students and teachers, through research and development of innovative resources, models and tools. Projects in the DRK-12 program build on fundamental research in STEM education and prior research and development efforts that provide theoretical and empirical justification for proposed projects.

The research questions examine the impact of the Transition to Algebra course on students' attitudes and achievement in mathematics in combination with teachers' instruction and the types of supports teachers need to successfully implement the intervention. The project will use a pre-post quasi-experimental design, along with propensity score methods to reduce selection bias threats, to examine the implementation in approximately 35 treatment schools and 35 comparison schools. Qualitative and quantitative data will be collected and analyzed to address research questions. The study will also investigate how teachers use and adapt Transition to Algebra materials, and the supports critical to successful implementation. For example, the study will examine whether and how school and district activities such as common planning time, coaching, and other professional development experiences influence the implementation fidelity of the curriculum. Qualitative data will be collected through interviews and classroom observations. Quantitative data will be collected using student and teacher surveys, an algebra readiness assessment, a standardized end-of-course assessment, and students' scores on state tests.

Supporting Instructional Growth in Mathematics: Enhancing Urban Secondary Teachers' Professional Learning through Formative Feedback

This project will explore the potential of video-based formative feedback to enhance professional development around ambitious instruction for secondary teachers in urban schools.

Lead Organization(s): 
Award Number: 
1620920
Funding Period: 
Thu, 09/15/2016 to Mon, 08/31/2020
Full Description: 

Research continues to show the benefits of ambitious instruction for student learning of mathematics, yet ambitious instruction continues to be rare in U.S. schools, particularly in schools that serve historically marginalized students. Secondary teachers' learning and enactment of ambitious instruction in mathematics requires conceptual change, and their development could benefit from adequate and timely feedback close to classroom instruction. For this reason, the project will explore the potential of video-based formative feedback to enhance professional development. The focus of the partnership between university researchers and a well-regarded professional development organization, Math for America Los Angeles (MfA LA) will be on career-long learning of secondary mathematics teachers in urban schools. Results from this project will provide a theory of mathematics teachers' learning that can inform other instructional improvement efforts, with ecological validity in the critical site of urban schools. The framework and theory will be detailed at the level of specific tools and concrete practices that are learnable by teachers, school leaders, or instructional coaches. This project is funded by the Discovery Research Pre-K-12 Program, which funds research and development of STEM innovations and approaches in assessment, teaching and learning.

The question the project will address is: How can the project use formative feedback to enhance mathematics teachers' professional learning environments that support their development of ambitious instruction in urban schools? Formative feedback refers to tools and processes that ascertain teachers' current understandings and responsively adapt learning activities to better guide them toward their learning goals. Professional learning environments refer to the multiple sites of teachers' learning, from formal professional development activities to their school workplace. Ambitious instruction is defined as teaching approaches that aim to provide all students with ample opportunities to develop conceptual understanding of key mathematical ideas, participate in mathematical argumentation, connect multiple mathematical representations, as well as become fluent with mathematical procedures and processes. The persistence of typical mathematics instruction is framed as, in large part, an issue of teacher learning. Using design-based implementation research and interpretive methods, the project team will co-develop video-based formative assessment processes to guide teachers' evolving classroom practice.

Connected Biology: Three-Dimensional Learning from Molecules to Populations (Collaborative Research: Reichsman)

This project will design, develop, and examine the learning outcomes of a new curriculum unit for biology that embodies the conceptual framework of the Next Generation Science Standards (NGSS). The curriculum materials to be developed by this project will focus on two areas of study that are central to the life sciences: genetics and the processes of evolution by natural selection.

Lead Organization(s): 
Award Number: 
1620910
Funding Period: 
Sat, 10/01/2016 to Wed, 09/30/2020
Full Description: 

This project will contribute to this mission by designing, developing, and examining the learning outcomes of a new curriculum unit for biology that embodies the conceptual framework of the Next Generation Science Standards (NGSS). The curriculum materials to be developed by this project will focus on two areas of study that are central to the life sciences: genetics and the processes of evolution by natural selection. These traditionally separate topics will be interlinked and will be designed to engage students in the disciplinary core ideas, crosscutting concepts, and the science and engineering practices defined by the NGSS. Once developed, the curriculum materials will be available online for use in high school biology courses nationwide.

This project will be guided by two main research questions: 1) How does learning progress when students experience a set of coherent biology learning materials that employ the principles of three-dimensional learning?; and 2) How do students' abilities to transfer understanding about the relationships between molecules, cells, organisms, and evolution change over time and from one biological phenomenon to another? The project will follow an iterative development plan involving cycles of designing, developing, testing and refining elements of the new curricular model. The project team will work with master teachers to design learning sequences that use six case studies to provide examples of how genetic and evolutionary processes are interlinked. An online data exploration environment will extend learning by enabling students to simulate phenomena being studied and explore data from multiple experimental trials as they seek patterns and construct cause-and-effect explanations of phenomena. Student learning will be measured using a variety of assessment tools, including multiple-choice assessment of student understanding, surveys, classroom observations and interviews, and embedded assessments and log files from the online learning environment.

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