As an introduction to sound and vibration, the authors wanted their first-grade students to plan and conduct their own investigations. In this article, the authors share a series of investigations to help students explore the relationship between sound and vibration. By planning, creating, testing, adapting, and reflecting on the outcomes of the…

Throughout the country, there are many bodies of fresh water affected by algal blooms. By focusing on a water source near their school, students can become scientists, too. Situating science content in real and meaningful learning experiences encourages students to be invested in their own learning, construct deeper understandings, and apply those…

When exploring and introducing sound, students need to understand that there are multiple aspects that work together to create sound. In this single class lesson, students work through an inquiry-based challenge to discover how sound can be manipulated and altered through these elements. By investigating how to manipulate sound, students are able…

Although the "Next Generation Science Standards" (NGSS) have three dimensions, the crosscutting concepts are often the forgotten dimension. One reason teachers may not emphasize the crosscutting concepts might be because they are broad, domain-general constructs that can be difficult to conceptualize in a meaningful way. Yet, when taught…

Observing children tossing a ball in a game of catch or pumping their legs to move a swing, it is obvious that they have already experienced and learned to control the basics of pushes and pulls. Through everyday experiences as simple as rolling a ball across the floor, to more complex activities like team sports, children are building a…

This article describes a lesson rooted in "tinkering," an approach to learning that encourages the use of authentic, hands-on experience to develop an understanding of content and physical materials. There were several desired outcomes for this lesson. First, the authors felt that tinkering was an appropriate approach to investigating…

By bringing everyday phenomena into the classroom, teachers can more readily engage students in authentic scientific inquiry. When working with young children, the best phenomena are those that students can directly experience and investigate. Meaningful phenomena can be identified by watching children at play, listening to the conversations they…

As part of the "Next Generation Science Standards" (K-LS1-1), students are expected to develop an understanding of what living things need in order to live and grow. The lessons provided in this article help students understand the difference between living and nonliving things, and help them acquire important background knowledge to…

This column presents ideas and techniques to enhance your science teaching. This month's issue shares information about trying (again) to engineer an egg package. Engineering is an essential part of science education, as emphasized in the "Next Generation Science Standards" (NGSS Lead States 2013). Engineering practices and performance…

By the age of five, there is already a science achievement gap among young children in the United States. Educators have worked to address this gap between upper elementary and middle school children for many years. However, little attention has been placed on preventing the gap by focusing on the youngest learners. This article describes how to…

Using cross-grade peer mentoring as an integral component to field trip experiences can help educators realize the learning potential of nature-based experiences. When young students are paired with older students, Socratic peer dialogue deepens interest, investment, and ultimately ownership of new learning. Using peer-supported inquiry…

Students with disabilities spend the majority of their day in the general education classroom (U.S. Department of Education 2017). However, these students consistently underperform in science. This highlights the importance of using effective differentiated instruction. According to Mastropieri and colleagues (2006), differentiated instruction…

Teachers have the daunting task of preparing students for a future that they cannot predict. In an age of information where students have the world quite literally at their fingertips, and with the ever-growing momentum of integrated science, technology, engineering, and mathematics (STEM), it is not enough that students experience STEM subjects…

This article describes an activity designed to foster an authentic way for students to learn about the biodiversity in their community. The activity is a half year scaffolding sequence to explore the living environment right outside the classroom. In using the outdoors just outside the window as a classroom, an inquiry based activity accomplished…

Picture this: a PhD chemist, PhD science educator, and a preservice Latina elementary educator walk into an aftercare program for primary and intermediate students from a rural school. These students are identified as low income and at risk and therefore eligible to participate in this school-provided aftercare. While across the state, these same…