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The power of high-quality instructional materials for K–8 science

A teacher helps two young students with a classroom activity involving small craft sticks at a table, demonstrating how to teach reading comprehension using engaging hands-on methods ideal for k-5 reading comprehension.

Simply put, quality teaching means quality learning. But there is another key part of the equation: quality curriculum.

Research confirms that the instructional materials used in classrooms play a powerful role in shaping how teachers teach, and how students learn.

Shifting from low-quality or pieced-together materials to well-designed, high-quality instructional materials can significantly improve student achievement. This growing evidence—sometimes described as “the curriculum effect”—is one reason that states and districts across the country are paying closer attention to the quality of the materials they adopt.

So what does high-quality instructional materials actually mean? And what does it look like in a real science classroom?

What does HQIM mean in science education?

High-quality instructional materials (often called HQIM) are curriculum materials intentionally designed to support student learning: aligned to rigorous standards, grounded in research, and built to support teachers.

High-quality instructional materials work alongside teachers, shaping instructional practices in ways that reduce guesswork, support consistency, and free up time and energy. This lets teachers do what they do best: interact with students. HQIM provide a coherent system that supports both teaching and learning over time.

And high-quality science curriculum materials go the extra mile, clearly articulating learning goals, providing guidance for facilitation and discussion, and including embedded opportunities to check for understanding. They also support a range of learners by offering scaffolds, differentiation strategies, and multiple ways for students to engage with content.

How HQIM align with NGSS science standards

The Next Generation Science Standards (NGSS) define what students should know and be able to do in science. At their core, these academic standards emphasize three-dimensional learning, integrating science practices, core ideas, and crosscutting concepts.

In science, HQIM are designed for three-dimensional learning: where students don’t just learn about science, but actively figure out how the natural world works. Three-dimensional learning integrates:

  • Science and engineering practices (what scientists do).
  • Disciplinary core ideas (what scientists know).
  • Crosscutting concepts (how scientific ideas connect).

HQIM are designed from the ground up to weave these dimensions together, rather than adding them on as an afterthought. That coherence helps students build understanding over time, and helps teachers see how each lesson fits into a larger learning story.

What do HQIM look like in a science classroom?

One of the best ways to recognize high-quality instructional content is to look not only at the materials, but also at the students using them.

Instead of memorizing disconnected facts, students taught with HQIM are engaged in the kinds of practices scientists use every day.

In classrooms using HQIM for science, you’ll often see students:

  • Investigating real-world phenomena that spark curiosity.
  • Asking questions, analyzing data, and building explanations.
  • Using evidence from multiple sources—texts, simulations, discussions, and investigations.
  • Revisiting ideas over time to deepen understanding.

“It is so encouraging to hear students engaged in conversation and building their ideas off of one another,” says classroom teacher Sarah Loessl of Big Hollow School District 38 in Illinois. “Students finding the confidence to challenge one another and use evidence to support their thinking is so much fun to watch.”

How HQIM support teachers

A key feature of high-quality instructional materials is that they’re designed by teachers, with teachers in mind.

This means materials that:

  • Clearly articulate learning goals.
  • Provide guidance for facilitation and discussion.
  • Include embedded formative assessment opportunities.
  • Support a range of learners, including multilingual/English learners and students who need additional scaffolds or challenges.

When materials shoulder this heavy lifting, teachers can spend less time creating from scratch and more time engaging with students.

How can teachers start engaging with HQIM?

Even if curriculum adoption decisions happen at the district level, teachers play a critical role in bringing HQIM to life.

Getting familiar with high-quality instructional materials can start with questions like:

  • What are students expected to figure out in this lesson?
  • How does this activity connect to a larger phenomenon or question?
  • Where are students using evidence to explain their thinking?
  • How does the curriculum support discussion, sense-making, and revision of ideas?

Developing a shared understanding of what high-quality science instruction looks like helps everyone—teachers, coaches, and leaders—move in the same direction.

Where does Amplify Science fit in?

Amplify Science is an example of high-quality instructional materials designed specifically for K–8 science and aligned to NGSS science standards.

It’s built around phenomena-based, three-dimensional learning and developed with educators, researchers, and scientists to support both student learning and teacher practice. The goal is coherence, engagement, and understanding that grows over time.

Ready to learn more?

To support educators and leaders in building a shared understanding of HQIM, we’ve created a free science HQIM resource bundle, including:

  • A classroom look-fors checklist.
  • A three-dimensional learning explainer.
  • An NGSS alignment overview.
  • A closer look at the HQIM student experience.
  • Registration for two upcoming webinars focused on HQIM in science.

Whether you’re new to the concept or ready to deepen your practice, these resources are designed to make high-quality instructional materials highly understandable and accessible to all.

Explore the HQIM bundle and upcoming webinars to learn more.

Navigating the shift to three-dimensional science teaching and learning

Students need science. They need it to succeed in school, and they need it to navigate the world around them—whether interpreting a weather forecast, perfecting a recipe, or troubleshooting the Wi-Fi.

But only 22% of high school students are proficient in science, and students in grades K–5 get an average of just 20 minutes of science instruction each day. For middle and high school students, access to advanced science courses is often limited. We’re not giving students all the tools they need to succeed in a world that’s increasingly shaped by science and technology.

Three-dimensional learning can help us solve that. This approach moves science education into the realm of discovery—where students learn to think and act like scientists.

But unlike hot water melting ice, shifting to this approach won’t happen in an instant! Don’t worry—we’re here to help.

Science learning: a pivotal moment

Many of us were taught science the traditional way: learning about the scientific world and how it works. (And many of us did ok!) But we know now that there’s a better way. Students need to figure out science the way scientists do.

This hands-on, problem-solving, three-dimensional approach (sometimes nicknamed “3D learning”) builds critical thinking, collaboration, and curiosity—all skills that are vital across school subjects and in life.

With content and lesson plans that focus on Science and Engineering Practices, Crosscutting Concepts, and Disciplinary Core Ideas, this model equips students with critical thinking skills and a deep understanding of scientific principles.

This shift started with the 2012 publication of A Framework for K–12 Science Education, which introduced the concept of three-dimensional learning. These principles, now embedded in the Next Generation Science Standards (NGSS), focus on three major changes:

  • Helping students move from simply learning about science to actively figuring it out.
  • Encouraging them to explain natural phenomena.
  • Aligning science learning with English language arts and math goals.

By embracing these changes, educators can help students make meaningful connections across disciplines, setting them up for success in real-world challenges.

Driving and supporting systemic change

Transforming science education isn’t a quick fix—it’s a cultural and systemic change. To make it work and make it last, schools and districts need to focus on three key drivers: processpractice, and people.

  1. Process: Pinpoint challenges, create clear plans, and track progress.
  2. Practice: Build the infrastructure for three-dimensional learning, including aligning curriculum, offering professional development, and updating teaching practices.
  3. People: Communicate effectively, support teachers, and highlight science champions who can inspire others.

Real change takes time and deliberate effort. But with these elements in place, schools can establish lasting improvements and build elementary and middle school programs that benefit every student.

Amplify Science’s playbook to guide you

To help educators navigate this shift, our new Science Change Management Playbook offers practical, evidence-based resources for transitioning over time to three-dimensional learning. Here’s what you’ll find inside:

  • Evidence-based practices: Learn structured approaches to problem-based learning, backed by research that highlights their benefits for students and teachers alike.
  • Practical tips: Explore actionable steps for driving meaningful change, from crafting a shared vision to delivering effective professional learning.
  • Real stories: Read testimonials from students and educators who have experienced the transformative power of curiosity-driven, collaborative learning.

With this playbook, schools can build K–8 and/or middle school science programs that truly engage students, equipping them with skills they’ll use for a lifetime.

The move to three-dimensional science teaching and learning opens the door to deeper understanding, better problem-solving, greater curiosity, and—more and more—a world built by students who know how to think like scientists.

More to explore

  • Dive deeper into the shift to three-dimensional teaching and learning with our Science Change Management Playbook to help you navigate the shift to three-dimensional science teaching and learning.
  • Discover how to be a changemaker for science through additional change management resources.
  • Learn more about Amplify Science.