This is great exploring properties of magnetism science lab for young scientists. It is meant to be an experiential precursor before covering topics of magnetism. It could easily be adapted for older children.

In this Night Sky Activity, students use a simple indoor Earth-Moon-Sun model to explore and learn about Moon phases and eclipses. Many children (and adults) have misconceptions about what causes the phases of the Moon, and helping them confront those misconceptions with evidence makes this activity pretty enthralling. While it’s pretty easy to see the phases of the Moon in the sky, it’s not possible from our perspective to observe the entire system, which often leads to inaccurate explanations of what’s going on, most commonly that Moon phases are caused by Earth’s shadow. It’s a perfect situation to use a scientific model. Students are challenged to use the model to struggle to figure out, develop understanding of, and explain the phases of the Moon, discuss ideas with others, then adjust their ideas based on evidence from the model. This activity usually includes a lot of big, “aha’s!” as participants encounter evidence while using the model that often contradicts what they previously thought was going on.

An adaptable exploratory and reflective activity that works with all ages and uses the Next Generation Science Standards (NGSS*), Asking Question and Defining Problems Practice and one of several possible Crosscutting Concepts to explore students’ awareness, prior knowledge and cultural experiences related to a phenomenon or Disciplinary Core Idea .

Quantum mechanics–even in the ordinary, non-relativistic, “particle” formulation that will be the primary focus of this course–has been a staggeringly successful physical theory, surely one of the crowning achievements of 20th century science. It’s also rather bizarre–bizarre enough to lead very intelligent and otherwise sensible people to make such claims as that the universe is perpetually splitting into many copies of itself, that conscious minds have the power to make physical systems “jump” in unpredictable ways, that classical logic stands in need of fundamental revision, and much, much more. In this course, we intelligent and sensible people will attempt to take a sober look at these and other alleged implications of quantum mechanics, as well as certain stubborn problems that continue to trouble its foundations.
Along the way, we will take plenty of time out to discuss philosophical questions about science that quantum mechanics raises in new and interesting ways: e.g., what it means to attribute probabilities to physical events, what the aims of scientific inquiry are (does it aim at something true, or merely at something useful?), what the role of observation is in constructing a scientific theory, what it means to say that there is an “objective” physical world, whether something as basic as logic can be viewed as an empirical discipline, whether there can be meaningful scientific questions whose answers cannot possibly be settled by experiment, and more.

to enable students to explore the air element using the stem and 5 E plan to guide them to create new products with engineering

This seminar is intended to help students in the MIT/Woods Hole Oceanographic Institution Joint Program develop a broader perspective on their thesis research by considering some aspects of science in the large. The first part of the course challenges students to develop a thoughtful view towards major questions in science that can be incorporated in their own research process, and that will help them articulate research findings. The second part of the course emphasizes science as a social process and the important roles of written and oral communication.
This course is offered through The MIT/WHOI Joint Program. The MIT/WHOI Joint Program is one of the premier marine science graduate programs in the world. It draws on the complementary strengths and approaches of two great institutions: the Massachusetts Institute of Technology (MIT) and the Woods Hole Oceanographic Institution (WHOI).

This professional development course is a series of Next Generation Science Standards-focused workshops developed by IslandWood with funding from the OSPI ClimeTime Grant. A PowerPoint slide deck and accompanying handouts are available to supplent the course outline.

This is a 50 minute lesson where preschool to kindergarten-aged students explore using their five senses several different station of materials

The purpose of this resource is to investigate the center pixel of a homogeneous land Cover Site in order to understand that individual land areas are part of a larger land system.

This inquiry lab activity involves students working to understand that sound is made from vibrations.

Many students are squeamish about spiders. But when you spray spider webs with a water mister, they are easy to see and gorgeous, and just about anyone can get caught up in exploring them! After this activity, students will probably notice and appreciate spider webs everywhere, including when they return home. They will also probably be more careful to avoid knocking webs down while walking around. In this activity, students notice spider webs as they walk. When students arrive at an exploration site, pairs search for different kinds of webs in the area, mist them with water, then regroup to discuss their observations and think about how different types of webs help spiders catch different kinds of prey. Students learn about different web types, then return to the field to use a key to identify different kinds of webs. They also make explanations about how the structures of the webs they find function to catch prey.

Observing an organism for an extended period of time can be a rewarding learning experience that helps students develop a meaningful relationship with the natural world. Students often engage more deeply in observing an organism if they’re given some sort of task to focus their observations. In this activity, pairs of students find an organism, then observe and record its structures and behaviors. Students apply the lens of adaptations as they come up with explanations for how their organisms’ structures and behaviors might help it survive in its habitat. In a group discussion, students consider the relationship between organisms’ structures and possible functions, which is a useful science thinking tool that can help them to better understand the natural world. This activity helps students develop a definition of adaptation that includes both behavioral and structural adaptations (adaptations are inheritable structures or behaviors that help a population of organisms survive in their habitat), and gives students the experience applying that definition to an organism in the local ecosystem.

This course explores the diverse ways that people teach and learn—in different countries, in different disciplines, and in different subcultures. We will discuss how theories of learning can be applied to a variety of hands-on, in-class learning activities. We compare schooling to other forms of knowledge transmission from initiation and apprenticeship to recent innovations in online education such as MOOCs. Students will employ a range of qualitative methods in conducting original research on topics of their choice.

Let's practice thinking like a scientist! Check out the video from Dr. Tavis Forrester, Research Wildlife Biologist for the Oregon Department of Fish and Wildlife. Then, in the Discovery Challenge video, we'll unlock mysteries that surround us by using the 3 I's of Scientist - I Notice, I Wonder, It Reminds Me Of. Lesson Credit: BEETLESproject.org.

This lesson introduces NGSS standards, and those standards are listed in the lesson.

Videos are part of the Explore Science Club series, an asynchronous online learning program using YouTube videos that connects elementary and middle school students to STEM professionals through hands-on lessons where students explore science and engineering practices related to the highlighted careers. There is an option to use FlipGrid, an online video recording platform for students to share their discoveries

Students will create a panorama drawing of their own landscape.  They will include landmarks and cardinal directions in their drawings, and use their drawings to plot the movement of the sun in the sky over the course of a day. They may make their observations in one day, or over a period of days or weeks. Once students have created their own panoramas, they will look at panoramas taken in the North and South Poles and compare similarities and differences. They will then explore the “Sun Path Simulator” online. Before beginning these lessons, students should already know: 1) How to find the four, cardinal directions, and 2) That the Earth rotates on its axis, and revolves around the sun. 3) How to tell time.  This unit pairs nicely with the Mystery Science Unit, Spinning Sky. Where indicated, worksheets and videos for lessons can be found on their website. Links to all other worksheets for the entire unit are in the “Overview” Section of my slideshow. Each day’s lesson comes with a worksheet to focus the students and to show evidence of student learning.

Incorporating your schoolyard into your classroom can be a powerful tool for making learning meaningful and engaging for your students. Local and relevant phenomena can engage your student’s prior understandings, better connect to their interests and identities, and help in draw in students who don’t see science, reading or writing connecting to their lives.  This online course is a series of professional development workshops for Early Elementary (K-2) educators, developed by IslandWood with funding from the OSPI ClimeTime Grant. A slide deck and accompanying handouts supplement the course outline for a complete picture. 

In this Adaptation Name Game, students sitting or standing in a circle play a version of tag, with one person in the center. When a person in the circle says another person’s name, the person in the center of the circle tries to touch the person whose name was said, before they can say someone else’s name. Later, students pause to brainstorm strategies to improve their performance, then play some more. Students learn that this was a representation of how certain structures and behaviors help organisms survive in their habitat, and that these are adaptations that species inherit over time. This game helps students learn each other’s names, while “lightly” introducing them to what adaptations are. Note: This activity is only an introduction; to gain any meaningful understanding of the topic, students will need more adaptation-focused activities, such as Adaptations Intro-Live!, Structures & Behaviors, and Related & Different, which engage students more deeply in understanding the concept through interactions with real organisms.

“What lives here?” is a question that students tend to wonder about, and this activity taps into that natural curiosity. Students figure out what lives in an ecosystem by looking for evidence and by using a simple field guide. They deepen their understanding of evidence, both the evidence organisms leave behind and evidence in general. Often, students might see a hair, track, or other piece of evidence and jump to conclusions about what left it behind. They may also treat all evidence as equal, whether it’s actually flimsy or strong. This activity helps them slow down, make observations, and evaluate their evidence as strong, less strong, or weak. Later in the activity, students make ecosystem models from their notes and, through discussion, use them as evidence to try to better understand the ecosystem.

Students will use an inquiry based approach to discover and reinforce how things move. They will discover that a push and a pull are a pair of forces that put things into motion. They will also investigate how friction is a force that slows an object in motion.