Why hands-on learning matters in science

A knowledge board, a child examining a geode, and a hand holding a geode in front of colorful geode art illustrate personalized learning through hands-on science exploration.

Science should be more than just reading about concepts—it should be something students can see, touch, and explore. When students actively engage with science through hands-on activities, technology, and even literature connections, they develop not only essential science skills, but also deeper understanding and lasting curiosity.

Bringing science to life: Hands-on activities

Perhaps the most effective way to engage students in science is to combine a high-quality curriculum with an interactive teaching style to make it experiential. In my classroom, we use the Amplify CKLA Geology unit to dive into earth science concepts. While these strategies can be applied across grade levels and scientific topics, the following is an example from my fourth-grade classroom’s geology lessons:

  • Examining geodes: Students predict what they will find inside before breaking geodes open. Then they analyze the crystal structures, connecting their observations to Amplify CKLA’s science concepts.
  • Writing about Earth’s layers: After learning about the Earth’s structure, students reinforce their understanding by writing creative descriptions or short stories from the perspective of different layers.
  • Diagramming volcanoes and the rock cycle: Drawing detailed diagrams, students visualize how rocks change over time and how volcanic eruptions shape the Earth’s surface.

Connecting literacy skills to science skills

Incorporating literature deepens students’ understanding of science. I use a mix of trade books and digital resources to bring concepts to life through storytelling and informational texts. These books help students connect scientific ideas with real-world applications, fostering both literacy and science skills.

Literacy skills like reading comprehension and critical thinking are key to understanding complex scientific ideas. When students dive into science-related materials, they practice making sense of data, thinking critically about evidence, and building arguments. These practices boost students’ overall literacy, expanding their vocabulary, sparking their curiosity, and developing their media literacy.

Digital resources for students: Exploring science with Google Earth

To further engage students, I integrate Google Earth into our lesson plans. This allows them to explore real-world scientific phenomena—such as geological formations, ecosystems, and weather patterns—making abstract concepts more tangible. Students love zooming in on famous landscapes, discussing how they were formed, and identifying scientific features. This interactive approach using relevant digital tools helps make science feel relevant and exciting.

Final thoughts: The power of engagement in science

By combining hands-on activities, literature, and technology, I’ve helped my students develop a genuine curiosity about science. As the school year progresses, they ask more questions, make deeper connections, and take ownership of their learning.

Engaging students in science doesn’t have to be complicated—it just has to be meaningful. By making learning interactive, Amplify (through Amplify CKLA and Amplify Science) helps students connect with scientific concepts in meaningful ways. I encourage other educators to bring Amplify’s lessons to life with interactive approaches that spark wonder and excitement in young scientists.

Explore more

  • Let’s keep the conversation going! Join the discussion in our Amplify learning communities.
  • Looking for inspiration? Watch Teacher Connections, a video series featuring practical advice and tools straight from fellow educators—our very own Amplify Ambassadors.
  • Dive into our podcast hub to hear from top thought leaders and educators and uncover cross-disciplinary insights to support your instruction.

The importance of risk-taking in the science classroom

Hear from science educator Valeria Rodriguez on our Science Connections podcast

In this episode of Science Connections: The Podcast, host Eric Cross sits down with Valeria Rodriguez, a Miami-based science educator, instructional technologist, and illustrator.

During the episode, Rodriguez describes how she uses real-world projects to make lessons more meaningful, and why teaching students to sketchnote—a way of creating visual summaries of ideas—helps them take risks they can learn from and increases their conceptual understanding in science. 

Read on for a peek at the episode, where you’ll learn more about the role of creativity in science and the importance of risk-taking in the classroom. 

Risk aversion among students today

Valeria is a science educator, instructional technologist, and illustrator (not to mention former college athlete and Peace Corps member). She also combines her science and art expertise to work as a graphic facilitator, which is her role on a STEAM team teaching third through fifth graders in Miami, FL. 

One thing Valeria has noticed in her classrooms is that her students often seem wary of taking risks and getting things wrong. How does she try to challenge and change this? Art. 

Valeria works with her students to use drawing as a form of note-taking. In the process, she says, “I mess up all the time. I scratch things out because my students in general are risk-averse. They don’t want to make mistakes. And drawing is one of those things that taught me that it’s okay to make mistakes.” 

Eric Cross says he sees the same risk aversion with his 7th graders. “When I ask them to give me a hypothesis about a phenomenon that I’m going to teach, I say, ‘It’s okay to be wrong’—but I see them drift to the Chromebook and want to Google it.”

Creativity in science versus “getting it right” 

Sometimes risks lead to mistakes. But mistakes are not dead ends, these educators say. Mistakes are opportunities. They present opportunities not only for academic learning, but also for personal growth.  

Of course, taking a risk may still deliver an expected or intended result. But even when it doesn’t, that result can be valuable. 

Eric describes an activity where his students walk around the school campus swabbing various items to see what would grow in Petri dishes. “Some things grew and some things didn’t.  Some of the experiments didn’t yield the cool results,” he says. 

But that is exactly what gave the class the chance to speculate and learn about what factors—temperature, a pathogen, the swabbing technique—might have prevented growth. 

Risk-taking also supports students’ personal growth, often in ways that prepare them to learn even more. 

For one thing, taking risks helps students practice tolerating uncertainty. 

“Sometimes my kids are frustrated because I don’t have yes or no answers,” says Valeria, citing the example of an activity with a weather balloon. “We don’t know how high it’s gonna go. Is the GPS tracker gonna work? We don’t know, but we have to do all the steps and find out. I have to say, ‘It’s okay to be frustrated.’” 

Taking risks can also lead to results that are less measurable, but equally valuable. When she does art and sketchnoting with her students, “Some people will say they ‘messed up’ the drawing,” Valeria says. “But you know what? They gave it character.”

How teachers can model risk-taking

“Part of our job is also taking risks,” says Valeria, describing the time her class wound up having to do a tethered weather balloon launch because they couldn’t get approval in time to launch the balloon in their location near an airport.  

“A parent said, ‘Oh, you’re not releasing the balloon,’” she recalls. “I was like, ‘Well, this is a lot of work, too, and I went back to my class and I was like, “You know what? I took a risk to do this project. I could have played it safe with a handout of a weather balloon,” she laughs, “or, you know, a YouTube video. But we are continuing to push.” 

She adds: “I want to thank the teachers who keep trying to do the hard things that aren’t tried and tested.” 

Eric agrees. “There aren’t a lot of opportunities for students to see adults in positions of authority or that they respect or admire model failure,” he says. 

Teachers can model risk-taking and “failure” outside of what they’re teaching—by just being who they are. “I cycle and I have scars everywhere. The image in my head is ‘I’m a cyclist,’ not ‘I’m banged up,’” she says. “They give me character and I keep riding.” 

Listen to the whole podcast episode here and subscribe to Science Connections: The Podcast here

About Amplify’s Science Connections: The Podcast

Science is changing before our eyes, now more than ever. So how do we help kids figure that out? How are we preparing students to be the next generation of 21st-century scientists?

Join host Eric Cross as he sits down with educators, scientists, and knowledge experts to discuss how we can best support students in science classrooms. Listen to hear how you can inspire kids across the country to love learning science, and bring that magic into your classroom for your students.

4 ways to weather educational change

The landscape of education is constantly shifting. That’s always been true, because the world is constantly changing. But at no time in recent memory has the landscape of education been forced to change in as many ways as it has over the past few years.

How can teachers navigate the seismic changes in the education system in their day-to-day lives?

In this recent episode of Science Connections: The Podcast, host Eric Cross talks about managing educational change with veteran educator and former Miami-Dade County Public Schools (M-DCPS) Middle School Science Teacher of the Year Marilyn Dieppa.

Below, we’ve outlined four tips for weathering shifts. The bottom line? It’s important for teachers to be able to change with the times, while remaining a steady, solid presence for students.

1. Embrace change—it’s good for kids, too.

“I always change my labs. I don’t like to do the same thing over and over again,” says Dieppa. And when she tries something new, she tells her students she’s experimenting. (After all, it’s science!)

“They’re afraid of trying something new and failing,” Dieppa says—so she tries to model taking on the unknown, learning, and adjusting as needed. This is part of cultivating a growth mindset for kids. “It’s for them not to be fearful. That gives kids a foundation they need.”

2. Have an open-door policy.

The pandemic has exacerbated challenges in kids’ lives that can make it tough for them to learn. Some even say we’re in a youth mental health crisis. Now more than ever, it’s important that “you become more than just a science teacher,” says Cross. “You’re a mentor. You’re an encourager. Sometimes you’re a counselor.”

It’s impossible to be everything to every student, but it’s important to let them know you see them.

“I always say, I’m not there to really be your friend, but I’m there to help you,’” says Dieppa. “And you gotta tell ’em, you know, ‘if you need to talk, come talk to me’. Because so much of what we’re doing is like life coaching in addition, and that connects to their success in the classroom.”

3. Measure wins in lots of ways.

What keeps Dieppa going? “Whether [students] have struggled all year and they’ve had that one piece of success, or they come back and tell you they didn’t realize what they got out of middle school science until they got to high school, those are my moments of success.”

4. Remember—you’re still learning, too.

Yes, you’re the teacher, but “you don’t have to be the expert in everything,” says Cross. “Teachers tend to be more risk-taking and innovative when they’re willing to say, ‘I don’t have to know everything in order to do something.’”

Whenever it feels like you can’t do something or don’t know something, remember: You can’t do it yet. You don’t know it yet. Growth mindset phrases for students apply to your growth, too.

Listen to the whole podcast episode here and subscribe to Science Connections: The Podcast here

About Amplify’s Science Connections: The Podcast

Science is changing before our eyes, now more than ever. So how do we help kids figure that out? How are we preparing students to be the next generation of 21st-century scientists?

Join host Eric Cross as he sits down with educators, scientists, and knowledge experts to discuss how we can best support students in science classrooms. Listen to hear how you can inspire kids across the country to love learning science, and bring that magic into your classroom for your students.

Inquiry-based learning: 3 tips for science teachers

Which practice is at the top of the eight NGSS Science and Engineering Practices? Good question! It’s asking questions and defining problems.

And why is asking questions so important? (Also a good question.) 

Because science isn’t just facts. Science is a process of finding answers—a process that starts with questions. That’s why students learn like scientists best in a science classroom defined by phenomena-based learning, also known as inquiry-based learning.  

How can science educators bring this approach into the classroom? 

That’s one question host Eric Cross and science educator and professional development facilitator Jessica Kesler address in the latest episode of Amplify’s Science Connections: The Podcast.

The power of questions

Kesler’s mission at TGR Foundation, a Tiger Woods charity, is to empower educators to create engaging classrooms that foster future leaders.

“We train teachers on STEM competencies and the pedagogical tools and strategies to implement the STEM we’re doing in our learning labs,” she says. “Then they can implement it in the classroom and have this multiplicative effect that can help us reach millions of kids and prepare them for careers.”

Those pedagogical approaches include student-centered learning practices. Using those practices, teachers spend less time delivering facts and more time asking questions, while developing students’ ability to do the same.

That’s how we shift science from, as the NGSS frames it, “learning about” to “figuring out.”

Per the NGSS: “The point of using phenomena to drive instruction is to help students engage in practices to develop the knowledge necessary to explain or predict the phenomena. Therefore, the focus is not just on the phenomenon itself. It is the phenomenon plus the student-generated questions about the phenomenon that guides the learning and teaching. The practice of asking questions or identifying problems becomes a critical part of trying to figure something out.”

Inquiry-based learning examples and approaches

Kesler recognizes that a shift to inquiry-based learning can’t be made overnight, or all at once. “We never suggest overhauling your classroom…add a little bit here and there and see how it impacts your students.”

Here are some strategies Kesler suggests for empowering educators to deliver inquiry-based science learning.

  1. Cultivate an inquiry mindset. We live in a world where answers to pretty much everything are right on our phones, right in our pockets. That ease and accessibility can dampen student curiosity. But when teachers start shifting focus from asking students for answers to asking them to develop smart questions, students can grow that mental inquiry muscle.
  2. Make inquiry visible. No need to be sneaky—you can be explicit with students about what you’re doing, and what you’re inviting them to do. Think: “What are tools and strategies you can use so that students can illuminate their thinking for themselves and for you and their peers?” Kesler says. “So the students get to see their own thinking as they progress, and you get to tell the story of how their minds have evolved.” Paying attention to student questions also enables you to observe where students are making mistakes, where misconceptions come up, and where you should target your next lesson, Kesler adds. “So it makes you more responsive in the moment.”
  3. Build an inquiry environment. Asks Kesler: “What are the things that you can embed into your physical space and develop in a student’s intellectual space that will help you create a holistic inquiry environment?” There’s no one right answer, but a shift in environment can support a shift in intellectual approach. (Consider the opposite: “If you take someone out of an old habit or space and tell them, ‘We are gonna change your minds and teach inquiry,’ but put them back in the same environment, they’re going to be conflicted,” Kesler says. You could create displays that present questions rather than facts, or arrange the room to support conversation rather than lecture—whatever makes sense for your space.

Definitely test, explore, experiment—even take risks—and ask your own questions. After all, the inquiry mindset is for you, too!

Learn more

Explore how Amplify Science supports inquiry-based learning.

Listen to all of Season 1, Episode 10, Empowering the science educator: Jessica Kesler, and find more episodes and strategies from Amplify’s Science Connections: The Podcast.

New professional development series for science educators

New year’s resolutions generally don’t work—unless, experts say, they’re specific, measurable, and backed by science (like … getting more sleep so you feel more rested). So if you’ve resolved (or at least planned) to do more science professional development this year, we got you.

Our new, free, on-demand professional development webinars are ready to be added to your calendar. Designed for the era of NGSS, they offer research-based ways for you to engage your students deeply in science this year. (But we hope you’ll find a way to get more sleep, too!)

Phenomena-based science learning for next-level engagement

The Next Generation Science Standards (NGSS) are designed to deliver this key shift: Students go from learning about to figuring out. Instead of delivering information, teachers invite students to explore the power of phenomena-based learning in science. By focusing first on real-life scenarios and thoughtful questions over abstract correct answers, this approach cultivates students’ voices and curiosity. It gets them to the right answers—but in a way that helps them think, read, write, and argue like real scientists and engineers.

The NGSS also deliver three-dimensional science instruction. This means that each standard includes the following three dimensions:

  1. Science and Engineering Practices: the actual behaviors that scientists and engineers engage in as they investigate and create.
  2. Cross-cutting Concepts: concepts that appear across and link various domains of science. They include: Patterns, similarity, and diversity; cause and effect; scale, proportion, and quantity; systems and system models; energy and matter; structure and function; and stability and change.
  3. Disciplinary Core Ideas: The fundamental scientific ideas that make up the core content of the NGSS.

A look at our webinars

Featuring curriculum experts from UC Berkeley’s Lawrence Hall of Science, our webinars will  show you what these approaches look like in real classrooms.

COURSE 1

Establishing a Culture of Figuring Out in Your Next Generation Science Classroom

Explore ways to cultivate curiosity and value student voices while utilizing the structures and content from phenomena-based, literacy-rich science curricula designed for the Next Generation Science Standards.

COURSE 2

Lead with Phenomena and the Three Dimensions Will Follow

Reframe your K–8 science instruction by focusing on phenomena. Learn about the shift in science teaching and classroom practices toward one where students are figuring out, not learning about.

COURSE 3

Leveraging Science to Accelerate Learning

Learn about an approach to teaching and learning science that not only meets state science standards, but can also be used to support accelerated student learning across all subject areas.

Learn more and sign up. You will also earn a certificate for each course you complete.

Also:

Tune into Science Connections:The Podcast.
Learn more about the NGSS.
Explore more Amplify webinars.
Have a phenomenal 2023 in science!

Bringing joy to learning in the science classroom

As we prepare for an exciting new season of Science Connections: The Podcast, we’re looking back at past seasons and sharing some of the amazing conversations we’ve had so far.

We’re so grateful to our 15 guests whose insight, expertise, and generosity have made our podcast (if we may!) one of the best science podcasts out there.

If you’re new here, welcome! In Amplify’s Science Connections: The Podcast, host Eric Cross talks to educators, scientists, and subject matter experts about ways to best support and inspire the next generation of 21st-century scientists.

Get ready for season 3, with all-new topics and speakers, premiering in March!

Our first featured throwback episode, Bringing community and joy to the learning process in K–8 science instruction, features physicist Dr. Desiré Whitmore!

First, meet Dr. Whitmore

Dr. Whitmore has nicknamed herself “Laserchick.” It’s a reference to the focus of her postdoc work at UC Berkeley, where she designed and built attosecond lasers. (These laser pulses, which emit x-ray light, are the fastest ever measured).

She later became a professor of laser and photonics technology at Irvine Valley College, as well as a science curriculum specialist for Amplify. She’s now senior physics educator in the Teacher Institute at the ExplOratorium in San Francisco.

There, she works to support middle and high school science teachers in teaching through inquiry. On a given day, she says, her role may include “making fudge or blowing darts with marshmallows across the room.”

But it all began with bubbles—the ones she’d blow as a child with her beloved great-grandmother. She was also the kind of kid who would do experiments in the microwave or take apart the vacuum cleaner. “I was always asking questions,” she says.

“Everything we do is science”—and more.

Here are some key takeaways from Dr. Whitmore’s conversation with Eric Cross.

  • Let students do their thing. Whitmore and Cross talked about students who didn’t hew to the letter of the assignment—and actually went beyond. That’s more than okay.

I think it’s amazing when we can realize as teachers that no, our job is not to just enforce rules on our students. Our job is to help students achieve more learning.

—Dr. Desiré Whitmore
  • Representation truly matters. Dr. Whitmore, who is Black, recalls a chemistry teacher she had in high school who was also Black. “He looked like me and spoke the way I spoke,” she says. He also recognized that she knew a lot about chemistry, and half-jokingly encouraged her to teach the class sometimes. In Whitmore’s experience, representation like that can supersede content knowledge.
  • Science is everything and everywhere. “Science is something that everyone in the world should and does do,” says Whitmore. She sees part of her job as “helping people understand that everything we do is science.”
  • Show scientists as real people. Whitmore recalls a time when an eighth-grader she’d known growing up was thrilled to recognize her in an Amplify Science video. The student knew her as a “regular human” who likes “Star Trek” and “Star Wars,” but now also sees her as a scientist. “That really brought home for me the importance of my work,” she says.
  • Put teachers in students’ shoes. As part of professional development, Cross and Whitmore agree that it’s important for teachers to remember how it feels to have a question—to not know. “That helps me be in the position of my students emotionally,” says Cross.

Perhaps that’s the most powerful way for teachers to connect with their future scientists: “To experience science as a learner,” says Whitmore.

Additional resources

Inquiry-based learning: 3 tips for science teachers
New professional development series for science educators
Celebrate student scientists with classroom posters, activities, and a special giveaway!

Integrating literacy in the science classroom

What do science classrooms and ELA classrooms have in common?

Literacy.

As science students build their scientific literacy, they also build their literacy literacy—as in,their capacity to read, write, and think across all disciplines. In a sense, all teachers are teachers of literacy, as students read to learn in essentially every subject.

An ELA teacher can help students learn to read and interpret certain types of non-fiction and science-related texts, while a science teacher is uniquely positioned to integrate a science curriculum with a focus on literacy goals. ELA teachers are the experts on what the average person considers literacy; however, science teachers are the true experts on science literacy.

In this post, we’ll take a look at what it means for science teachers to support literacy growth in their students.

Scientific literacy vs. literacy in science

First, let’s define our terms.

Scientific literacy refers to a student’s understanding of scientific concepts, inside and outside the classroom.

Literacy in science refers to the literacy skills that students use to acquire and share scientific knowledge. These skills include reading, writing, speaking, and listening.

Developing students’ literacy in science helps them develop scientific literacy. Science literacy allows students to become critical thinkers, problem solvers, and strategic questioners.

 Insights on integrating science and literacy

Integrating literacy into science is more than making sure students read articles and write lab reports—but the two are still a natural fit.

The standards that guide instruction in grades 6–8 make this integration concrete. Certain Common Core ELA standards intersect with the Next Generation Science Standards (NGSS).

To cite just a few examples, the Common Core requires students to be able to:

  • Cite specific textual evidence to support analysis of science and technical texts. RST.6-8.1
  • Determine the central ideas or conclusions of a text; provide an accurate summary of the text distinct from prior knowledge or opinions. RST.6-8.2
  • Follow precisely a multistep procedure when carrying out experiments, taking measurements, or performing technical tasks. RST.6-8.3
  • Integrate quantitative or technical information expressed in words in a text with a version of that information expressed visually (e.g., in a flowchart, diagram, model, graph, or table). RST.6-8.7
  • Distinguish among facts, reasoned judgment based on research findings, and speculation in a text. RST.6-8.8

What’s required of students is what’s often called disciplinary literacy. That means literacy through the lens of inquiry in a given field. Science has its own set of vocabulary and reading/writing styles students need to learn to understand, decode, and write in.

And when they do, the academic benefits go both ways.

 Integrating literacy into science encourages both science and ELA growth

The scientific method requires students to ask questions, listen to explanations, and present conclusions. And when science teachers use targeted literacy teaching strategies, they can help students understand challenging scientific vocabulary. For example, they can learn the difference between the two meanings of the word “culture.” Those are the same approaches students will use when analyzing with and communicating about texts in ELA.

Also, reading in science can be more than just reading a science textbook or science-related article—teachers can help students learn to read through a scientific lens by encouraging even the youngest students to articulate their questions about a text and understand where they might find answers.

And then there’s writing: “Science and writing standards are really in service of each other,” writes educator Gina Flynn in Literacy Today. “When we present authentic writing opportunities in science, we are not only developing students’ understanding of science concepts but also providing an authentic context for developing writing skills.”

Integrating science into ELA also encourages both science and ELA growth. When students grapple with science-related texts in ELA, they can develop ways of thinking and communicating that support the scientific approach, refine sense-making skills that are key to both disciplines, and get inspired to keep up with the latest scientific discoveries—yet another great reason to read.

More to explore

Science and literacy: You don’t have to choose

Amplify K–5 integrated literacy and science instruction

6–8 literacy elements in Amplify Science

The power of phenomena in the science classroom

In conversation, something “phenomenal” is something exceptional, extraordinary.
But in science, an event does not have to be “phenomenal” for it to be a phenomenon.
In fact, a phenomenon in science can be as ordinary and predictable as gravity.
To qualify as a scientific phenomenon, an event simply has to be observable.
That is, a scientific phenomenon is an observable event that occurs in the universe. It’s something we can use our science knowledge to explain or predict. Examples of science phenomena include the erosion of dunes or soil, or the formation of bubbles or ice.
And you know what else is observable? The positive impact of phenomena-based learning on the science classroom. That’s why phenomena-based learning is baked into the Next Generation Science Standards (NGSS).

Let’s take a look at why the power of science phenomena to deliver engagement and learning is, dare we say, extraordinary!

The power of phenomena-based learning in science

Many of us learned science a different way, by starting with a general or abstract principle then applying it in the real world.

But when you start with phenomena in science, you start with the observable real-world event. You ask questions: Why is brown water coming out of the pipes built for drinking water? Where did all the monarch butterflies go? You help students see why science is relevant, right from the outset of the inquiry.

Even everyday phenomena—like sunburns, or vision loss—can generate real learning opportunities. Explaining phenomena and designing solutions helps students learn in context, leading to deeper and more transferable knowledge.

The challenge of predicting or explaining the phenomenon becomes the motivation for learning. And it has the added benefit of being how real scientists proceed with their work!

The power of phenomena science lies in its capacity to bring real life into the classroom. A phenomena-based science curriculum engages students by starting with the real and relatable rather than the abstract. It also trains students to be inquisitive, expansive, critical thinkers.

When you shift to a phenomena-based approach, you help students shift from learning about to figuring out.

How the NGSS support phenomena-based learning

The NGSS help students make sense of phenomena in the natural world and in human-designed machines and products.

Learning to explain phenomena and solve problems is the main way that students engage in the three dimensions of the NGSS—they use Science and Engineering Practices (SEPs) to develop and apply Disciplinary Core Ideas (DCIs) and Crosscutting Concepts (CCCs).

Phenomena-centered classrooms also help teachers monitor student progress. As students work toward explaining phenomena, three-dimensional formative assessment is easily embedded throughout instruction.

How to bring phenomena into the science classroom

The power of phenomena-based learning lies in real-world relevance. Also, phenomena don’t generate learning all by themselves—student questions about phenomena guide teaching and learning.

That’s why it’s helpful to make sure students can connect to the phenomenon at hand. The following are a few steps you can take to integrate this approach into your classroom:

  • Ask students what they’re curious about. Why do leaves change color? What is lightning? Why do ice cubes stick to my finger?
  • Connect iterations of a given phenomenon to students’ lives. When discussing how sunlight warms the earth, a teacher might use examples of the sun heating sand, or asphalt depending on where students live.
  • Use one broad anchor phenomenon for the focus of a unit, and investigate related phenomena that relate to students’ interests and experiences. For example, exploring what we see in the sky will lead to different investigations depending on whether students live in an urban area or far from city lights.

Note that an engaging phenomenon does not have to be flashy or unexpected. Even if students think they already know why it rains, they may discover that they actually can’t explain it. Pushing students to inquire more will help them go beyond repeating things they’ve read, and go from learning facts to asking questions that reveal more about the world around them.

How Amplify Science can help

Amplify Science employs phenomena-based learning throughout the curriculum, which is itself phenomena-based and designed around the NGSS.

In one example, 6th graders take on the role of medical students in a hospital, working to diagnose a patient and analyze the metabolism of world-class athletes. In another, 8th graders work to explain Australia’s high skin cancer rates by investigating how light works and interacts with the world it shines on.

And what’s more, Amplify Science for grades 6–8 received an all-green rating from EdReports!

Learn more.

Integrating writing skills into science instruction

Teaching students to write like scientists

People tend to think of themselves as either a “science person” or an “arts person.” But for science students today, it doesn’t have to be that way.

Writing and communicating are essential parts of being a scientist, which is why they’re also essential parts of a science curriculum.

A science teacher is uniquely qualified to expose students to science writing skills, which can in turn improve their writing skills overall. It’s a win-win! And even though writing styles may vary across the two disciplines, we bet ELA teachers will notice the improvement in students’ writing abilities.

Integrating science and writing skills

The science classroom and the ELA classroom are partners in developing student literacy. The following five principles can help teachers make the most of that partnership.

  1. Science writing is more than fill-in-the-blank. Science writing involves critical thinking, analysis, and the ability to communicate complex ideas effectively—in research, proposals, and more. To develop those skills, teachers can ask students to create presentations and lab reports, and to read journals and each other’s work.
  2. Technical writing goes beyond the technical. It’s important for students to learn to vary their writing styles for different audiences and purposes. Practicing technical writing (even instructions for making a sandwich) can help students learn to write—in all disciplines—with clarity and precision.
  3. Writing takes phenomena-based learning to the next level. Writing about a phenomenon encourages students to communicate hypotheses, arguments, and opinions. They need to provide detailed evidence for their assertions and explain why they matter—just as they would in an essay for ELA.
  4. The Next Generation Science Standards (NGSS) are designed to support science instruction that’s rich in writing. Here are just a few places where the NGSS connect to common core writing standards: grades K–2 storyline PDFgrades 3–5 storyline PDFmiddle school storyline PDF, and high school storyline PDF.
  5. Integrating writing into science encourages science and ELA growth. The more students practice writing out their thoughts, arguments, and opinions, the more adept they will be at forming arguments both in and out of the science classroom. When science and ELA teachers use similar strategies, they’ll reinforce the learning across classrooms and create even stronger writers.

Learn more

Instructional strategies for integrating literacy into your science classroom

Do you ever feel like science is the underdog in your school or district? You’re not alone.

But it doesn’t have to be that way. In fact, we know that science can overdeliver. That’s especially true when educators successfully integrate it with other subjects.

You can dive into the power of integrating science and literacy with the latest season of Science Connections. Here’s a sneak peek at what we explore in the first few episodes of Season 3 of our podcast.

Rooting for the underdog

In what sense is science seen as an underdog? Just ask Eric Banilower and Courtney Plumley of Horizon Research, a consulting firm that supports educational improvement and policy development. Host Eric Cross interviews them in Season 3, Episode 1.

As you know, an underdog is generally a weaker or less favored person or entity. Banilower and Plumley find that science instruction often fits that mold.

One thing they found: elementary school teachers’ schedules allow for less instruction of science than math and ELA. They also note that when there’s a break in routine—a special assembly or early dismissal—science is often “the first thing to go,” says Plumley.

They also note that instructors (like many others) are often expected to design their own curriculum.

The conversation offers some solutions for shifting these practices, as well as supporting science instructors in general.

“You don’t ask doctors to develop new treatments and tests. Their job is to get to know their patient, assess what’s going on, and then use research-based methods to develop a plan of action. That analogy [suggests] a scalable approach for raising…the quality of science education,” Banilower says.

What is that approach? According to Banilower, “Giving teachers research-based, high-quality instructional materials that they can use to meet the needs of their students would allow them to focus on getting to know their students, seeing their strengths, [finding areas where they have] room for growth, and…help[ing] those students progress.”

The power of integrating science and literacy into the science classroom

Science does not need to stay in a silo. As we illuminate in Episodes 2 and 3, bringing literacy work into the science classroom can supercharge students’ work in both. (We also explore the topic in this blog post.)

“We know we need to dramatically improve literacy rates in this country, and as we’ll show in the coming episodes, science can be a key ally in that goal,” says our host, Eric Cross.

It goes the other way, too. Language development and literacy instruction can support science. “Win-win, folks,” says Cross.

In Episode 2, senior science educator Dr. Susan Gomez Zwiep described how bilingual and multilingual students in her school accelerated their English speaking and learning when they were excited to discuss science phenomena.

Indeed, she notes, the NGSS provides rich linguistic opportunities for students. We used to talk about language in science as all technical, but that’s changed. “Language is now developed through the science learning experiences,” says Gomez Zwiep.

Two key approaches you can use:

  • Think of science lessons as a narrative. Gomez Zwiep suggests you ask yourself, “What’s the story arc of my science lesson? How are the science ideas building over time?”
  • Welcome language that’s comfortable and conversational for your students.  “This expansion of language, including non-standard dialects and even home language, is really important for letting students bring their whole selves into the classroom,” she says.

More ways to enhance literacy in science 

Don’t worry—you don’t need to take a second job. “It’s not that you have to become a reading specialist to integrate literacy into science,” says Douglas Fisher, Ph.D., professor and chair of educational leadership at San Diego State University. “It’s how our brains work.”

It’s also how science works. “Science teachers and scientists do a lot of reading, writing, speaking, and listening and viewing. They use the five literacy processes all the time,” says Fisher, our guest on Episode 3.

Some strategies Fisher offers:

  • Invite multiple aspects of literacy. Think: What role do speaking, listening, reading, writing, and viewing, play in your class? Provide opportunities for students to do those things each time you meet with them.
  • Read challenging texts. “Science is an ideal place to get students reading things that are hard for them. Doses of struggle are good for our brains,” Fisher says. “Complex texts that don’t give up their meanings easily allow students to reread the text, mark it, talk to peers about it, and answer questions with their groups.”
  • Get them writing, even in short bursts. “Writing is thinking,” he says. “While you are writing, your brain cannot do anything else.” So if your students understand a given concept, have them write about it.

And that’s just the beginning. Tune in—and stay tuned—for more strategies for encouraging literacy integration in a science classroom.

More ways to learn

Science professional learning resources for teachers

We hope you’ll take some time to rest and recharge this summer! But we also know how hard you work—even when school’s out—to do the best you can for the students in your science classroom.

Without the constraints of the school schedule, summer can be a great time for teachers to work on professional development! 

That’s why we created this handy list of professional learning resources, mined from our trove of blog posts and webinars, for you to dive into this summer. 

Science and literacy integrations

How should you approach the integration of science and literacy, and why is it important in the first place? Get all the answers in these posts and webinars: 

Next Generation Science Standards

These resources will help you learn about the Next Generation Science standards by grade level—and discover how to make them come alive in your classroom: 

Phenomena in science

What’s phenomena-based learning in science? A method of exploring the everyday and observable that can also deliver extraordinary results. Learn more here: 

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Top 5 back-to-school tips for science teachers

Science teachers: We got you. 

“Teaching through a pandemic called for so much innovation, resilience, and sacrifice,” says Eric Cross, host of the podcast Science Connections and a K–8 science teacher who’s spent 10 years in the classroom. 

As education continues to evolve with new technologies like artificial intelligence, [teachers] keep rising to meet each moment with wisdom and courage.

 —Eric Cross

And with that innovation in mind, we’re here to get you ready to go back to school. 

From fun classroom activities to professional learning opportunities, our strategies are designed to help you walk back into your science classrooms feeling energized, inspired, and supported by a science community. 

As Cross says: “We’re all in this together.” 

1. First-day fun: Plan interactive classroom activities. How about some Icebreaker Bingo? Create a Bingo card that invites students to find classmates who can answer “yes” to science-related descriptions (e.g., “Has a pet reptile,” “Enjoys stargazing”). Activities like these help students uncover common interests while also providing background knowledge. They can also remind students that science doesn’t just happen in the science classroom—it’s an integral part of their lives and worlds, too.

2. Student success: Work with school colleagues and leadership toward shared goals. Review what systems may already be in place and consider adding more. You might: 

  • Schedule regular team meetings to set and work toward common goals.
  • Establish a professional learning community to share science resources for teachers.
  • Amp up the use of data to inform decisions. Ask your team: What student performance data and assessment results can we use to see where improvements are needed?

Approaches like these will help build a network of support for science learning, and support every educator in taking steps to help students grow.

3. Set the tone for the year: We are scientistsYou might have learned science by starting with a principle and then exploring it in the real world. Today, we know it’s more effective to start by observing a phenomenon, then trying to predict or explain it. In fact, that’s what scientists do. And when your students do that, they become scientists, too. Let students know from day one that that’s who they are to help them start the year motivated and engaged.

4. Cultivate community: Build a science ecosystem. Find ways to involve caregivers in student learning and create a continuum between the classroom and their everyday lives. You might: 

  • Collaborate with students on writing a weekly science newsletter or blog with classroom updates and suggested at-home activities.
  • Organize family science days or nights (IRL or online) for students and caregivers to do some hands-on science together.
  • Create simple but engaging science challenges for students and caregivers to do together. (Paper airplane distance contest, anyone?)

5. Use free professional learning opportunities for teachers from Amplify Science. Explore upcoming Amplify Science webinars, designed to support you—along with your schools and districts—in using collaborative, effective, and engaging science practices in the classroom. You’ll hear from thought leaders in science education, observe real science students in K–5 classrooms, and much more. 

Ready to dive into professional learning right away? Check out our on-demand science webinar library. From quick tips to longer continuing education (CE) credit options, our on-demand webinar library is sure to have just what you need.

Free science resource toolkit 

Our free toolkit of science resources will make it even easier for you to implement all of the tips above while setting science students up for success. These resources aren’t just for teachers—administrators and caregivers can use them, too! A robust science program means giving the right tools to not only those who teach, but everyone who supports students’ science learning. The resources in the toolkit will:

  • Help you craft a dynamic science curriculum during the crucial first weeks of school.
  • Support student engagement and spark new inspiration in your classroom practices and activities.
  • Offer learning opportunities you can access now or on demand whenever you need them.

We hope these resources will serve you and your young scientists all year long! 

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Pseudoscience examples for critical thinking skills

MIRACLE HAIR GROWTH! 

Quantum hair activation technology: This groundbreaking innovation goes beyond conventional science, delving into the realm of quantum energy to stimulate hair growth at the subatomic level. Blended with rare botanicals from ancient civilizations for luster and shine. Limited-time offer: Act now and receive a vial of stardust-infused hair serum!

Effective product…or pseudoscience? We’ll bet you guessed it. (Sorry, no stardust serum for you!)

While this hair product itself sounds like junk, reading about it can be a valuable experience for science students.

Teaching your students to identify pseudoscience in the world around them helps them learn to protect themselves from false claims that can be money-wasting at best, dangerous at worst.

And as they learn to discern, they also develop lifelong critical thinking skills!

We say knowledge is power but it’s not enough to know things, and there’s too much to know. Being able to think and not fall for someone’s bunk is my goal for my students.

—Melanie Trecek-King, biology professor and guest in Science Connections podcast Season 3, Episode 5: Thinking is power

Let’s explore how educators can use examples of pseudoscience to develop critical thinking skills—and incorporate NGSS (Next Generation Science Standards) science and engineering practices into their approach.

What’s the difference between science and pseudoscience?

Science is grounded in empirical evidence, rigorous testing, and the scientific method. Pseudoscience presents itself as scientific but lacks the fundamental elements of genuine scientific inquiry: evidence, peer review, and the capacity to generate accurate predictions.

Though pseudoscience may make vague claims, it has clear characteristics. When something is pseudoscience, it:

  1. Can’t be proven wrong: Makes claims that are unobservable or too vague.
  2. Professes “proof” without presenting actual evidence: Presents only anecdotal evidence, if any.
  3. Uses technobabble: See: “Quantum hair activation technology.”

For more characteristics of pseudoscience, check out Melanie Trecek-King’s episode of Science Connections!

To be sure, not all pseudoscience is harmful—pursuits and activities such as aromatherapy and astrology can be positive experiences in people’s lives—it just should not be defined as or considered science.

How addressing pseudoscience encourages critical thinking

When you teach students to identify pseudoscience, you are teaching them to use an evidence- and research-based approach when analyzing claims. Which is…science!

You are also:

  • Teaching them to engage in thoughtful and educational argument/debate.
  • Encouraging them to use their knowledge of science in the real world.
  • Creating real-world impact.

When students learn to identify pseudoscience—faulty products, myths, and disprovable “discoveries”—they’ll be prepared and informed when making real-world decisions.

Critical thinking exercises inspired by pseudoscience

We’ve talked about “miracle” hair growth treatments, which are more commonly targeted to adults. Students may have more commonly encountered claims about or ads for alkaline water or detox diets, conspiracy theories and instances of science denial, astrology, and more. These examples offer great opportunities to discuss how to determine the difference between science and pseudoscience.

Suggested activities:

  • Pseudoscience Sherlock: Ask students to find examples of pseudoscience in real life via social media, products sold in stores, or on the internet. Tell them to pay close attention to “articles” that are really ads.
  • Pseudoscience lab: Prompt students to back up their claim that a given example represents pseudoscience with evidence: e.g., lack of empirical evidence, controlled experiments, or unbiased sample; absence of peer-reviewed research; reliance on anecdotes; hyperbolic and unprovable claims.
  • Snake oil! Ask students to practice identifying pseudoscience by creating their own advertisements, commercials, or news segments for fake products or scientific “advancements.”
  • Spread the word: Ask students to create flyers, PSAs, or articles on how to identify the characteristics of pseudoscience.

Other activities that incorporate the NGSS while also sniffing out pseudoscience:

  • Asking questions: Encourage students to ask probing questions about pseudoscientific claims. How does this claim defy our current understanding of the natural world? What empirical evidence is missing?
  • Developing and using models: Have students create models that illustrate the differences between a pseudoscientific claim and a well-established scientific concept. This visual representation supports understanding and critical analysis.
  • Engaging in argument from evidence: Arrange debates where students argue for or against a pseudoscientific claim using evidence-based reasoning. This practice sharpens their ability to critically evaluate information.
  • Obtaining, evaluating, and communicating information: Ask students to research the history and impact of a specific pseudoscientific belief. Have them present their findings, highlighting how critical thinking could have prevented widespread acceptance of the claim.

Using examples of pseudoscience in your science classroom can help students learn to not only think like scientists, but navigate the real world, too.

Bertha Vasquez, former teacher and current director of education at the Center for Inquiry, has used these approaches with her students. As she shared on Season 3, Episode 6 of Science Connections: “I guarantee you that those students, when they walked into a store with their parents and they saw a product [with] a money-back guarantee [that] cures way too many things, and it’s based on ‘ancient plant wisdom’ and has ‘scientific’ language on the box, they may go, ‘Mom, I think these people are trying to sell you some pseudoscience.’”

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Boost student engagement with Science Seminars

What do you get when you cross a Socratic seminar with Curie, Watson, and Crick?

A Science Seminar.

Though Socratic seminars typically take place in ELA or social studies/humanities classrooms, we also know how strongly scientific and literacy approaches can support each other.

So let’s see what magic can happen when we bring a little Socrates into science!

More than just seminars on science

As you likely know, a Socratic seminar is a method of facilitated discussion that uses open-ended questions, active listening, and collaboration to encourage deep exploration of a text or topic.

Sound perfect for science? That’s because it is!

When a Socratic seminar becomes a Science Seminar, students focus on scientific evidence and work together to answer a question and come to the most convincing explanation of a phenomenon. Ideally, the teacher takes a supporting role, putting students and their ideas at the center of the discussion. In this way, Science Seminars form a powerful part of an NGSS-informed curriculum that teaches students to think, talk, evaluate, and collaborate like scientists.

The benefits of Science Seminars

Like Socratic seminars, Science Seminars:

  • Build critical thinking. They encourage participants to analyze and evaluate information critically, challenging assumptions and exploring multiple perspectives.
  • Provide practice in productive argument. Through structured dialogue, Science Seminars teach students to challenge each other respectfully and engage in constructive disagreements, supporting their ideas with reasoning and evidence.
  • Boost literacy skills. By actively participating in discussions, students practice active listening, oral communication, and analytical thinking—all serving to enrich their comprehension, vocabulary, and overall literacy skills.

And on top of all that, they also connect to key Next Generation Science Standards (NGSS) practices. Specifically:

  • Asking questions and defining problems.
  • Analyzing and interpreting data.
  • Constructing explanations and designing solutions.
  • Engaging in argument from evidence.
  • Obtaining, evaluating, and communicating information.

Tips for strong Science Seminars

Science Seminars are designed to be student-focused and student-led, but the teacher still plays an important role in setting students and seminars up for success. Here are some ways you can help them run smoothly and effectively:

  1. Set clear expectations. What’s the goal of the seminar? Make sure students know precisely what question they’re working to answer, and how they will know when they’ve answered it.
  2. Set ground rules. Before you start, help the students agree on how they will interact. Who has the floor? What words, phrases, and types of communication are helpful or not? What happens when students disagree?
  3. Involve all students. Plan in advance how more quiet students can take part. You might consider supplying conversational prompts to encourage participation.
  4. Take on a supporting role. Once you’ve set it all up, step back. If the conversation stalls, you might ask an open-ended question. You might also take notes—a reminder that the students are in charge and what they’re saying is important.

Free Science Seminar resource collection

We’ve created a free set of materials to help you host a successful Science Seminar. In this collection, you’ll get:

  • A helpful guide that dives deeper into how to get started.
  • Our top 10 Science Seminar tips for teachers.
  • Talk moves for grades K–1, 3–5, and 6–8.

Access your free Science Seminar resources here.

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Integrating AI in the science classroom

image of Science Connections podcast and host Eric Cross

How can you create new science lesson plans, adjust assessments, and design labs using only objects kids have at home?

Just ask—ChatGPT, that is.

In this recent Science Connections webinarScience Connections podcast host Eric Cross tackles the topic of ChatGPT for teachers, along with other specific AI tools that (when used with your existing standards-aligned curriculum) can help make teaching more efficient, targeted, and interactive.

AI for science can save teachers time, deepen student engagement, and inspire collaboration and creativity all around, says Science Connections podcast host Eric Cross.

Eric describes some of the many ways science teachers can use AI in the classroom—as both shortcut and partner. “We can use it for personalized learning,” he begins. “We can generate questions and give instant feedback. We can differentiate. We can support our students with special learning needs. And that’s just a start. The more you use it to collaborate with other educators, the more fun it becomes.”

Generative artificial intelligence 101

There are a lot of AI tools out there, but the new one is generative AI. As Eric explains, the difference is that generative AI—unlike, say, AI that gives you driving directions—creates something that didn’t exist before: text, images, music, and, yes, new science experiences for the classroom.

As with any technology, the practically infinite uses and applications of AI raise important questions about accuracy, equity, biases, and more. In this webinar, though, we focus only on AI’s practical uses for science teachers.

Generative AI relies on and responds to prompts.

You’re telling it to do something and it communicates back to you in human language. The way you craft your prompts determines your output, so the better your prompt is, the better your output.

– Eric Cross
Host, Science Connections; Adjunct Professor of Learning and Technology, University of San Diego

Let’s see what AI has produced for Eric as a science educator, and the kind of prompts he’s used to get there.

How science teachers can use AI to prepare and engage

Teachers can use generative AI to create personalized learning materials, generate more practice questions, and explain topics at any level and depth.

In this webinar, Eric focuses on the AI tools that have given him the most mileage as an educator and that he thinks can provide the most value for others.

These include:

  1. Modifying assessments when students have used all the ones that a curriculum provides. A sample prompt: “You are a science teacher creating an assessment for middle school students. I will upload an assessment. Please recreate it in a similar tone and voice as the original with a similar level of rigor.” Response: Brand-new multiple-choice and written questions on the same topics, all adhering to the same NGSS. With a little more back and forth, Eric will have the exact number, style, and focus of questions that he needs—along with an answer key.
  2. Creating relevant, accessible lab ideas. Eric prompts AI for lab and hands-on project ideas to fit exact specs: topic, grade level, desired outcome, and objects found in a typical classroom or home. Result: Hands-on activity ideas students can do at home, like exploring lung capacity with a balloon and a ruler (delivered by AI complete with full supply lists, instructions, and more).
  3. Helping students connect. To support a student who’s stuck, you might prompt the AI by saying: “I’m a fifth grader and my teacher is talking about claim evidence reasoning and I don’t really understand it. Can you explain it to me in a way that would help me? And then: “Now can you help me explain it to my mom, but in Spanish?”

Eric also uses AI to interpret graphs, collate student data, build graphic organizers, create science games, and more.

Is everything AI provides him flawless and 100% accurate? No, says Eric. “You have to vet, and it helps to have a high-quality curriculum already in place. But it gets me 80 to 90% there—and that’s pretty good.”

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Accelerating learning in science with the Science of Reading

The Science of Reading: it’s not just for Language Arts.

As host Eric Cross and expert guest Susan Lambert discuss in this Science Connections webinar, the Science of Reading also provides a powerful foundation for science learning.

Here’s what they had to say about bringing evidence-based literacy strategies into the science classroom.

The role of literacy in science literacy

Strictly speaking, the Science of Reading refers to the vast body of research we now have—and put into practice—on the systematic, explicit, and cumulative instruction required for students to learn to read.

There is a misconception that when we’re talking about the Science of Reading, we’re just talking about reading.

—Susan Lambert, Amplify’s Chief Academic Officer for Elementary Humanities

In fact, we’re talking about comprehensive literacy, which encompasses all the essential—and interdependent—components of literacy, including background knowledge, vocabulary, and both comprehension and expression.

In other words, it’s the listening, speaking, reading, and writing that scientists do in the real world—and that students do to engage with and connect to science learning. As we discussed in this post, developing students’ literacy in science helps them develop scientific literacy. And science literacy allows students to become critical thinkers, problem solvers, and strategic questioners—in science and beyond.

Integrating science and literacy in the classroom

What do these literacy strategies look like in practice? Eric puts them to use regularly—and here’s how you can, too.

  1. Use phenomena to activate and gauge prior knowledge. The more you know, the better you comprehend text and the faster you learn—so exploring familiar observable events (frying eggs, seeing your breath on a cold day) can engage students and accelerate their comprehension from the jump.
  2. Provide multilingual resources. “Being intentional about providing access to resources in the languages our students speak is critical,” said Eric. “The data shows that the more proficient students become in their native language, the more proficient they become in a new one.”
  3. Get students writing (and speaking, and editing). Eric has his students document their experiments and observations in (digital) notebooks and online portfolios. They also share with and present to each other, he said, “so they’re seeing other students’ writing styles and syntax and what details they include, and they can go back and update their own.” And, since it’s a year-long process, “by the time they’re done, they have this beautiful website that showcases their work.” (Amplify Science’s Student Investigation Notebooks also fit the bill!)
  4. Work across subjects. The Common Core recommends that, by 4th grade, 50% of texts read should be non-fiction. That’s why Eric coordinates with ELA teachers to read one text about metabolism, for example, each examining it through different lenses. “When you’re able to work together with another content teacher, it’s like magic,” he said. (And in elementary school, you’re the other content teacher!)
  5. Run science seminars. Students use evidence to explain their thinking. “For students who need extra support, you can have pre-written sentence frames so that they’re able to participate,” Eric said. “Even when they’re listening to other students speaking, that’s helping them develop language skills. You watch them be able to listen, speak, engage in debate, and disagree without being disagreeable, which we know as adults is a valuable skill.”

For more of Eric’s strategies, watch the webinar: Science Connections: Accelerating Learning in Science with the Science of Reading.

Even more to explore

Webinars:

Curriculum: Amplify Science

Amplify blog:

Making the most of a science education conference

A typical science education conference such as NSTA may offer hundreds of booths, sessions, and new people to meet—and, most of the time, a typical science educator can’t do it all! So how can you maximize these opportunities to learn even more about teaching science … without maxing out? Middle-school educator and Science Connections podcast host Eric Cross is here to offer his tips. Here’s what he shared with us: 

Proven tips for capitalizing on science education conferences

  • Fuel up: Good food and good coffee are essential for me. Before you arrive, do some pre-trip research into local coffee shops and restaurants near the conference center. Avoid the long lines and overpriced food at the conference venue; instead, support local businesses to keep your energy levels up. Also important: comfy shoes, a reusable water bottle, and extra snacks.
  • Make a plan: Once registered, head to the conference website to build your agenda. Phone apps are handy, but I often find the desktop version works better for planning.
  • Narrow it down: NSTA, as just one example, offers more than 1,132 sessions! So it’s crucial to zero in on your options. Use a session schedule filter to focus on the sessions most relevant to your interests and needs.
  • Go where you’re fed: If you’re torn between sessions, go to one to collect resources, then move onto the other. Usually presenters list their session resources on the schedule or in the beginning of their session. Don’t hesitate to leave a session if it’s not meeting your needs, either—you’re there on behalf of your students. Presenters get it.
  • Divide and conquer: If you’re attending with a team, collaborate on a shared document for session notes and resource links. This way, everyone in your department and administration can benefit from the resources gathered at the conference.
  • Visit the expo hall: I recommend visiting right when it opens. You’ll find the booths fully stocked and the energy levels high.
  • Embrace downtime: Remember, conference venues are huge, and you’ll be on your feet quite a bit. Make sure to schedule 30–45 minutes of downtime. Use this break for a bit of mindless relaxation or to catch up on emails and reflect on earlier sessions. This brief pause can be a game changer for your overall conference experience.
  • Revisit next-day plans: Schedules can shift at the last minute. After dinner, I like to give the lineup a fresh look for any speaker or time changes. Being prepared allows me to have a game plan, but flexibility is also key.
  • Network: I especially find value in connecting with educators who teach content or student populations similar to my own and learning about their best practices in science instruction. Sometimes, these new connections can be just as enriching as the sessions themselves.

Note: Amplify will be at NSTA (March 20–23) at Booth #713. Stop by to experience real Amplify Science lessons; gain access to exciting, free resources and activities; and pick up fun swag. You’ll also hear from product experts and real educators about how they use Amplify Science to benefit all students.

Can’t wait? Check out our Amplify Science success stories to see how our K–8 curriculum is helping students everywhere read, think, and talk like scientists.

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