Books with title Investigating Forces and Motion Through Modeling

Force and motion are all around us and help us move and do great things! Through a variety of vivid images and stunning facts, readers will explore how forces and motions work. The easy-to-read text and accessible glossary and index ensure that readers have the tools they need to understand such concepts as gravity, equilibrium, acceleration, deceleration, electromagnetic fields, pressure, kinetic energy, and inertia. To gain further insight into how gravity, forces, and motion works, a stimulating lab activity is featured!

Forces and motion are at work all around you—when you kick a ball, ride a bike, or drop a book. But what exactly are forces? And how do they make things move? For thousands of years, scientists have been testing hypotheses about forces and motion and learning from the results of their experiments. These lead to more questions: Why do you speed up when you're biking down a hill? Why are heavier objects harder to pull? Why doesn't the moon float off into space? The answers may surprise you! Find out how forces and motion are at play with everything on Earth and beyond.

Forces and motion are at work all around you―when you kick a ball, ride a bike, or drop a book. But what exactly are forces? And how do they make things move? For thousands of years, scientists have been testing hypotheses about forces and motion and learning from the results of their experiments. These lead to more questions: Why do you speed up when you're biking down a hill? Why are heavier objects harder to pull? Why doesn't the moon float off into space? The answers may surprise you! Find out how forces and motion are at play with everything on Earth and beyond.

Long before astronauts ventured into space, scientists and philosophers used models to develop theories about Earth and what lies beyond it. This experimentation guide shows students how they too can create models to forge a deep understanding of topics like the scale of the solar system, how eclipses occur, and the cyclic patterns that govern life on our planet. Through the creation of models, readers learn how to develop and test hypotheses and how to represent their findings visually in graphs and charts.

Much of human perception is thanks to the transmission of light and sound, from reading a book, to watching television, to walking to school. Explaining deep but foundational topics through modeling, this book helps readers visualize and represent the properties of light and sound, while contextualizing their practical uses. As students experiment with light and sound, they will master key concepts covered in the NextGen Science Standards.

How does water change form? What is the relationship among pure substances, mixtures, and compounds? How do models help scientists understand the physical world? These are just a few of the questions addressed in this science experiment guidebook. From particle theory to forming a hypothesis, readers are guided through activities that make complicated concepts easy to understand and remember.

Everything contains energy, which manifests in ways such as motion, sound, light, heat, or electricity. Give your students the opportunity to create illustrative models that engage head-on with this phenomenon and its manifestations in areas like the food cycle, renewable energy, and kinetic and potential energy. This book provides essential background information about energy that is aligned to the NextGen Science Standards while also prompting readers to ask questions, think creatively, and apply what they've learned.

Long before astronauts ventured into space, scientists and philosophers used models to develop theories about Earth and what lies beyond it. This experimentation guide shows students how they too can create models to forge a deep understanding of topics like the scale of the solar system, how eclipses occur, and the cyclic patterns that govern life on our planet. Through the creation of models, readers learn how to develop and test hypotheses and how to represent their findings visually in graphs and charts.