IES Blog

Institute of Education Sciences

IES Makes Three New Awards to Accelerate Breakthroughs in the Education Field

Through the Transformative Research in the Education Sciences Grants program (ALN 84.305T), IES  invests in innovative research that has the potential to make dramatic advances towards solving seemingly intractable problems and challenges in the education field, as well as to accelerate the pace of conducting education research to facilitate major breakthroughs. In the most recent FY 2024 competition for this program, IES invited applications from partnerships between researchers, product developers, and education agencies to propose transformative solutions to major education problems that leverage advances in technology combined with research insights from the learning sciences.

IES is thrilled to announce that three grants have been awarded in the FY 2024 competition. Building on 20 years of IES research funding to lay the groundwork for advances, these three projects focus on exploring potentially transformative uses of generative artificial intelligence (AI) to deliver solutions that can scale in the education marketplace if they demonstrate positive impacts on education outcomes. The three grants are:

Active Learning at Scale (Active L@S): Transforming Teaching and Learning via Large-Scale Learning Science and Generative AI

Awardee: Arizona State University (ASU; PI: Danielle McNamara)

The project team aims to solve the challenge that postsecondary learners need access to course materials and high-quality just-in-time generative learning activities flexibly and on-the-go.  The solution will be a mobile technology that uses interactive, research-informed, and engaging learning activities created on the fly, customized to any course content with large language models (LLMs). The project team will leverage two digital learning platforms from the SEERNet networkTerracotta and ASU Learning@Scale – to conduct research and will include over 100,000 diverse students at ASU, with replication studies taking place at Indiana University (IU). IES funding has supported a large portion of the research used to identify the generative learning activities the team will integrate into the system—note-taking, self-explanation, summarization, and question answering (also known as retrieval practice). The ASU team includes in-house technology developers and researchers, and they are partnering with researchers at IU and developers at INFLO and Clevent AI Technology LLC. The ASU and IU teams will have the educator perspective represented on their teams, as these universities provide postsecondary education to large and diverse student populations.

Talking Math: Improving Math Performance and Engagement Through AI-Enabled Conversational Tutoring

Awardee: Worcester Polytechnic Institute (PI: Neil Heffernan)

The project team aims to provide a comprehensive strategy to address persistent achievement gaps in math by supporting students during their out-of-school time. The team will combine an evidence-based learning system with advances in generative AI to develop a conversational AI tutor (CAIT– pronounced as “Kate”) to support independent math practice for middle school students who struggle with math, and otherwise, may not have access to after-school tutoring. CAIT will be integrated into ASSISTments, a freely available, evidence-based online math platform with widely used homework assignments from open education resources (OER). This solution aims to dramatically improve engagement and math learning during independent math problem-solving time. The team will conduct research throughout the product development process to ensure that CAIT is effective in supporting math problem solving and is engaging and supportive for all students. ASSISTments has been used by over 1 million students and 30,000 teachers, and IES has supported its development and efficacy since 2003. The project team includes researchers and developers at Worcester Polytechnic Institute and the ASSISTments Foundation, researchers from WestEd, educator representation from Greater Commonwealth Virtual School, and a teacher design team.

Scenario-Based Assessment in the age of generative AI: Making space in the education market for alternative assessment paradigm

Awardee: University of Memphis (PI: John Sabatini)

Educators face many challenges building high-quality assessments aligned to course content, and traditional assessment practices often lack applicability to real world scenarios. To transform postsecondary education, there needs to be a shift in how knowledge and skills are assessed to better emphasize critical thinking, complex reasoning, and problem solving in practical contexts. Supported in large part by numerous IES-funded projects, including as part of the Reading for Understanding Initiative, the project team has developed a framework for scenario-based assessments (SBAs). SBAs place knowledge and skills into a practical context and provide students with the opportunity to apply their content knowledge and critical thinking skills. The project team will leverage generative AI along with their framework for SBAs to create a system for postsecondary educators to design and administer discipline-specific SBAs with personalized feedback to students, high levels of adaptivity, and rich diagnostic information with little additional instructor effort. The project team includes researchers, developers, and educators at University of Memphis and Georgia State University, researchers and developers at Educational Testing Service (ETS), and developers from multiple small businesses including Capti/Charmtech, MindTrust, Caimber/AMI, and Workbay who will participate as part of a technical advisory group.

We are excited by the transformative potential of these projects and look forward to seeing what these interdisciplinary teams can accomplish together. While we are hopeful the solutions they create will make a big impact on learners across the nation, we will also share lessons learned with the field about how to build interdisciplinary partnerships to conduct transformative research and development.


For questions or to learn more about the Transformative Research in the Education Sciences grant program, please contact Erin Higgins (Erin.Higgins@ed.gov), Program Lead for the Accelerate, Transform, Scale Initiative.

An Example of the Unquantifiable Effect of Research on Practice

At IES, we continue to think about ways to positively impact education practice through research. It is relatively straightforward to count and share the publications and research outputs produced by our grants. A bigger challenge is measuring the impact IES-funded research has on implementing evidence-based practice after the research project is complete. So we were thrilled when we received the following letter from Patrice Bain—a middle school teacher, author, education specialist, speaker, and consultant—who has worked closely with IES for many years.

I used to think of government agencies as impersonal bureaucracies often hidden from the public eye. One agency, IES, not only proved me wrong, it positively changed my life.

In 2006, Drs. Henry Roediger III and Mark McDaniel from Washington University in St. Louis obtained a grant from IES to research how students learn in an authentic classroom. The classroom where this research began was mine. And this is where the life-changing impact began.

The IES grant paid for technology to be used in my school’s classrooms and research assistants to aid our teachers. Heading up the research at my school was Pooja Agarwal, and this began a collaboration lasting over a decade.

In 2007, IES invited me to be the sole K-12 educator to co-author a practice guide. The large organization, to me, now had a face: Elizabeth Albro, who warmly welcomed me. I clearly recall sitting at a large table in Washington, DC, surrounded by my cognitive science superheroes: Drs. Hal Pashler, Mark McDaniel, Brian Bottge, Art Graesser, Janet Metcalfe, and Ken Koedinger. Each talked about important research that would impact learning in classrooms, and I knew my newly-expanded teaching repertoire now would be based in the science of learning. The final result of our meetings became the highly cited practice guide Organizing Instruction and Study to Improve Student Learning. In addition, information from this guide was featured on the website Doing What Works.

As Pooja and I delved into how retrieval, spacing, and metacognition played a role in student learning at my school, I was contacted by REL Mid-Atlantic, a part of IES that offers research-based professional development in Delaware, Washington, DC, New Jersey, Pennsylvania, and Maryland. Touting the benefits of teaching using the seven recommendations in Organizing Instruction and Study, I gave professional development presentations in the Mid-Atlantic regions with Drs. Hal Pashler, Ken Koedinger, and Nate Kornell.

Pooja and I also gave several presentations that included the research happening in my classroom. With IES funding, that research became a multi-year project involving over 1500 middle and high school students. With the passing of each year and research on learning becoming more defined, I was able to develop strategies utilizing retrieval, spacing, and metacognition. Pooja and I continued our collaboration. I was seeing success in the eyes of my students: I wasn’t just teaching content, I was teaching them how to learn.

A wealth of information on the science of learning seemed to be making a mark. Yet learning myths—those based on anecdotes and fads—were still circulating. To combat this, IES and NCER invited me to be on a working task group to tackle Neuromyths vs. Neurotruths. Once again, as I sat around a table in Washington, DC with learning superheroes, we explored how to begin to dispel prevalent myths of learning.

Because of IES and the opportunities I was given, I wanted to shout from a mountaintop that we can transform teaching. I’ve seen it. I’ve done it in my classroom. I realized a book started to brew within me. I’m not sure how the decision occurred, but I knew my collaboration with Pooja Agarwal was worthy of documenting. And so it began. We wanted to write a practical, evidence- and research-based book. Books had been written by cognitive scientists; books had been written by teachers. However, our book would be the first written by a cognitive scientist and an educator.

Powerful Teaching: Unleash the Science of Learning was released in June 2019. The ideas have resonated with educators across the globe. We are transforming education.

And it all started with IES approving a grant.

 

Basic Science of Learning and Development Within Education: The IES Investment

I came to the Institute of Education Sciences (IES) in 2002 to build connections between education and the basic science of learning and development. The weak links between these two fields were surprising to me, given how foundational such science is to the very purpose of education.

IES had just launched the Cognition and Student Learning program[1], and researchers were invited to submit applications to examine whether principles of learning established in basic science were robust when examined in education settings.  Six years later, we launched the Social and Behavioral Context to Support Academic Learning to understand the ways in which the social environment of classrooms and school affected learning. Together, IES has invested over $445M, an investment that has contributed substantially to our foundational knowledge of teaching and learning.

I was surprised by this recent blog by Bob Pianta and Tara Hofkens. While they acknowledge the research that IES has supported to transform education practice, they did not seem to realize our substantial, ongoing investments in the basic science of teaching and learning—both in and out of classrooms.

In part, this may reflect their perception of what types of work we support under our Exploration goal – which is not limited to “scouring databases” but instead involves all types of research, including small-scale experiments and longitudinal studies. These projects generate foundational knowledge about what factors are associated with learning outcomes and can potentially be changed through education. In fact, the questions that Pianta and Hofkens want answered by the basic science of education are the same questions that some IES grantees have been examining over the course of the last 15 years. 

Here are just a few examples.

  1. What factors regulate children's attention in a classroom setting? Anna Fisher and her team found that cluttered classroom walls in kindergarten led to greater distraction and less learning – a finding that captured the imagination of the nation and the nation’s educators.
  2. What roles do the capabilities of peers play in advancing children's cognitive capabilities? A new study led by Adrienne Nishina is examining how student’s ability to think about situations from different perspectives is related to their day-to-day interactions with peers from diverse backgrounds.
  3. What factors promote or inhibit teachers' responses to children's perceived misbehavior? Teachers’ expertise and teachers’ emotional competencies are two factors that IES-funded researchers have found to relate to their responses to children’s behavior.
  4. What role do social and emotional experiences and affective processes play in fostering learning? Shannon Suldo and her team find that the coping strategies that high school students choose to manage their responses to stressors are linked to learning outcomes.
  5. What are the components of school climate that matter the most for different forms of student success? Two recent projects, one in Cleveland, and one in Virginia, are using survey data to explore the relationship between school climate, social behavioral competencies and academic outcomes. The teams are also exploring how those relationships vary within student subgroups.

Funding the basic science of teaching and learning—in and out of classrooms—has been and will continue to be a cornerstone of the work that IES funds. The IES investment in this area is broad, and is shared in books such as Make It Stick: The Science of Successful Learning, Becoming Brilliant: What Science Tells us About Raising Successful Children, and Educator Stress: An Occupational Health Perspective

Importantly, IES is not the only funder in this area. The National Science Foundation invests substantially in their Science of Learning portfolio, the McDonnell Foundation’s Understanding Human Cognition portfolio includes an explicit request for projects at the intersection of cognition and education, and the Child Development and Behavior Branch of the Eunice Kennedy Shriver National Institute of Child Health and Human Development (NICHD) supports a variety of relevant research programs.  I agree that we need systematic investment in the basic science of teaching and learning. But we must build on what we have already learned.  

We are grateful that Pianta and Hofkens recognize the importance of investing in this area. Perhaps the fact that they did not acknowledge the substantial investments and contributions IES has made in exploring the important questions they pose is an IES problem. While we have invested heavily in the science of learning, we have skimped on brand development and self-promoting. If someone as central to the field such as Pianta, who has received several IES grants, including research training grants, doesn’t know what IES has done, that is a red flag that we will need to attend to.

In the meantime, we hope that this brief glimpse into our investment to date has illustrated some of the questions that the basic science of teaching and learning within education can answer. More importantly here’s where you can seek funding for this type of work.

Elizabeth Albro

Commissioner, National Center for Education Research

 

[1] IES was authorized in November 2002. The Cognition and Student Learning research program was launched by the Office of Educational Research and Improvement, the office from which IES was created.

Resolve to Study Effectively in 2018

Students of all ages want to study more effectively and efficiently, while teachers want to improve their students’ understanding and retention of important concepts. The Institute’s Cognition and Student Learning (CASL) program has invested in several research projects that test the effectiveness of different strategies for improving learning and provide resources for teachers who want to implement these strategies in their classrooms.  Two strategies that are easy for teachers and students to implement and do not require a lot of time or money are retrieval practice and interleaving.

 

Retrieval practice (also known as test-enhanced learning) involves recalling information that has been previously learned. Research has shown that when students actively retrieve information from memory (e.g., through low-stakes quizzes), their ability to retain that information in the future improves when compared to other common study strategies like re-reading and highlighting key concepts while reading class texts.

Interleaving is the process of mixing up different types of problems during practice. Unlike blocking, where a student practices the same type of problem over and over again, interleaved practice involves multiple types of problems that require different strategies to solve. In mathematics, where interleaving and blocking have been studied most, blocking is frequently employed at the end of each chapter in a textbook. With interleaved practice, students must choose a strategy to solve the problem and apply that strategy successfully. Research has shown that students learn more when engaged in interleaved practice relative to blocked practice.

For decades, research has shown the benefits of both retrieval practice and interleaving for learning; however, until this point, there were no easily accessible resources that practitioners could turn to for concrete details and suggestions for how to implement these strategies in their classrooms. Two of the IES CASL research projects that have focused on these study strategies (Developing a Manual for Test-Enhanced Learning in the Classroom, PI: Henry Roediger and Interleaved Mathematics Practice, PI: Douglas Rohrer) resulted in guides for teachers that provide information on how to implement these strategies in their classrooms. These guides are freely available through the website www.retrievalpractice.org (download the Retrieval Practice Guide here and the Interleaving Guide here). With these guides, teachers can learn more about how to use retrieval practice and interleaving to improve their students’ understanding and retention of the concepts they are learning. Happy studying!

By Erin Higgins, NCER Program Officer, Cognition and Student Learning

Building CASL: Improving Education through Cognitive Science Research

(Updated on Oct. 20, 2017)

In its 15 years, the Institute of Education Sciences (IES) has helped build the evidence base in many areas of education. One of the key areas where IES has focused in that time has been on Cognition and Student Learning – or CASL. 

The CASL program was established with the purpose of bringing what we know from laboratory-based cognitive science research to the classroom. In 2002, IES funded eight CASL grants—an investment of about $4.9 million. A lot has changed over 15 years. First, the CASL program has increased significantly in size. To date, CASL has funded 165 projects, representing a total investment of over $200 million. 

Second, the CASL program has expanded its research to cover a wider range of cognitive science topics. In the 2000s, many of the cognitive principles studied in education research came from what we know about how the memory system works. This makes sense, as cognitive scientists who study memory have always been thinking about the kinds of issues that are important in a classroom, such as how students encode, retain and successfully recall information.

More recently, the CASL program has supported research across a range of cognitive science topics, even those that do not seem on the surface to be directly relevant to education practice. For example, cognitive scientists who study attention and perception have made contributions to our understanding of how those processes affect learning and retention. These findings have provided the foundational knowledge necessary to design better textbooks, develop education technologies, and even inform how teachers should decorate their classroom walls.

Through CASL, researchers have developed and fine-tuned the process of working in school settings on complex problems of education practice and have developed effective models for moving back and forth between the laboratory and the classroom to advance both theory and practice. Through the CASL program, we now have many different examples of how cognitive science can improve teaching and learning:

  • Want to see how to use cognitive science principles to transform a curriculum? See the National Research & Development Center on Cognition & Mathematics Instruction’s work on the Connected Math Project (CMP) curriculum;
  • Want to see how small changes to instructional materials can make a big impact on student learning? See Nicole McNeil’s research on how best to teach the meaning of the equals sign, as one of many examples; and
  • Want to think about a completely different model for improving students’ STEM outcomes? See Holly Taylor’s project, where her team is further developing and pilot testing Think 3d!, an origami and pop-up paper engineering curriculum designed to teach spatial skills to students.

Sharing the Research

In 2007, findings from CASL research were included in a set of recommendations for educators to use in the classroom. Organizing Instruction and Study to Improve Student Learning was one of the first Educator’s Practice Guides published by the What Works Clearinghouse (another IES program) and was one of the first attempts to synthesize research from cognitive science in ways that would be useful for practitioners. The guide identified a set of effective learning principles, including:

  • spacing learning over time;
  • interleaving worked examples;
  • combining verbal and visual descriptions of concepts;
  • connecting abstract and concrete representations of concepts;
  • using quizzing to promote learning;
  • helping students allocate study time efficiently; and
  • asking deep, explanatory questions.

While the practice guide was successful in its goal of reaching a broader audience, many policymakers, practitioners, and even education researchers from other fields were still unaware of these principles. However, we have recently seen an uptick in the production of summaries of effective learning principles based in cognitive science for various stakeholders, like teachers, parents, and policymakers. Importantly, these summaries appear to be reaching people outside of the cognitive science and learning sciences communities.

Perhaps most well-known among these is Make It Stick: The Science of Successful Learning, by Peter Brown, Mark McDaniel, and Henry Roediger, a popular book published by Harvard University Press (pictured). The book includes findings from research Roediger and McDaniel conducted through three IES-funded CASL grants. CASL research also informed other publications, including The Science of Learning by Deans for Impact and Learning about Learning by the National Council on Teacher Quality.

CASL has come a long way in 15 years, but there are still many gaps in our understanding of how people learn and in how that knowledge can be applied effectively in the classroom to improve learning outcomes for all students. We look forward to sharing more about what IES-funded researchers are learning over the next 15 years and beyond.

EDITOR'S NOTE: This blog post was updated to reflect the FY 2017 awards , increasing the number of CASL grants to 165. 

Written by Erin Higgins, Program Officer for the Cognition and Student Learning program, National Center for Education Research