Video Description:  Discover how NASA's Earth-observing satellites gather data to monitor food growth. Dr. Inbal Becker-Reshef describes how mathematics is used to interpret satellite data and describe vegetation and crop yield. Dr. Hannah Kerner shares how algorithms and models use NASA data to describe and predict food supply and food shortages. This work through NASA Harvest provides tools for farmers and governments to describe and predict food security worldwide. Video Length:  2:09.NASA eClipsTM is a suite of online student-centered, standards-based resources that support instruction by increasing STEM literacy in formal and nonformal settings.  These free digital and downloadable resources inform and engage students through NASA-inspired, real-world connections.NASA eClips Real World segments (grades 6-8) connect classroom mathematics to 21st Century careers and innovations.  They are designed for students to develop an appreciation for mathematics through real-world problem solving.

Looking for a fun way to teach both scientific method and cybersecurity? Well great job, you found it. Students will not only learn 5 characteristics to making a good password but they will also be using all of their 2.1, 3.1, and 4.1 strands to build and rebuild a structure using different materials that are probably inside your classroom right now.  Need a STEM activity for a club day? Need a “Friday and I can’t teach anymore content” lesson? This is for you. Roll up your sleeves and let the students do the work and problem solve in a simple and fun way.

Every line, shape, and color tells a story of fun and learning for your kindergartner in this graphing adventure!

Grab your hard hat and tool belt for this lesson, exploring engineering and computer science with the scientific method.

Do you like to  troubleshoot and solve problems yourself?  This lesson will teach you to solve problems on your technology devices and to create cars by using troubleshooting and problem solving as well.

Delve into a microscopic world working with models that show how electron waves can tunnel through certain types of barriers. Learn about the novel devices and apparatuses that have been invented using this concept. Discover how tunneling makes it possible for computers to run faster and for scientists to look more deeply into the microscopic world.

Why is Engineering a Hot Job? Listen to 3 students from Virginia Commonwealth University's School of Engineering to find out. Learn why these three students went into Computer Engineering, Biomedical Engineering and Electrical Engineering. Presented by Science Matters

Biomechanical engineering is an interdisciplinary field of science that applies the rules and principles of mechanical engineering to biological systems. It combines elements of many disciplines, including biology, engineering, physics, chemistry, and mathematics to better understand how physical forces influence living organisms. A biomechanical engineer may find work in the medical, scientific, industrial or governmental sectors. It is also sometimes considered a subset of Mechanical Engineering or Biomedical Engineering.

In the final lesson of the SDO curriculum, student teams collaborate to design and present their three Solar Module activities as part of their 3-D Solar Exhibit summative assessment.

Use a virtual scanning tunneling microscope (STM) to observe electron behavior in an atomic-scale world. Walk through the principles of this technology step-by-step. First learn how the STM works. Then try it yourself! Use a virtual STM to manipulate individual atoms by scanning for, picking up, and moving electrons. Finally, explore the advantages and disadvantages of the two modes of an STM: the constant-height mode and the constant-current mode.

Semiconductors are the materials that make modern electronics work. Learn about the basic properties of intrinsic and extrinsic or 'doped' semiconductors with several visualizations. Turn a silicon crystal into an insulator or a conductor, create a depletion region between semiconductors, and explore probability waves of an electron in this interactive activity.

In this activity book, your students will study five key stages in the lifecycle of a solar storm, from its emergence on the solar surface to its impact upon some aspect of our lives. The book may be used in its entirety to study solar activity and how it directly affects us, or you may use individual activities of your choice as stand-alone mini lessons as an enrichment for math and physical science courses. The student activities emphasize basic cognitive skills and higher-order processes such as plotting data, searching for patterns and correlations, and interpreting the results. By the end of the activity series, students will understand why we need to pay more attention to solar storms.

Investigate what makes something soluble by exploring the effects of intermolecular attractions and what properties are necessary in a solution to overcome them. Interactive models simulate the process of dissolution, allowing you to experiment with how external factors, such as heat, can affect a substance's solubility.

This collection of activities is based on a weekly series of space science mathematics problems distributed during the 2012-2013 school year. They were intended for students looking for additional challenges in the math and physical science curriculum in grades 5 through 12. The problems were created to be authentic glimpses of modern science and engineering issues, often involving actual research data. The problems were designed to be one-pagers with a Teacher’s Guide and Answer Key as a second page.

This brochure is offered as a tool for science, technology, engineering and mathematics educators who are working with students with disabilities. Some activity descriptions are supplemented with case study examples addressing a particular disability.

Join Joe as he embarks on an exploration of space in this episode of Super Science Show with Joe. Accelerate your way through the planets and take a closer look at our solar system. Learn how to design and build your own rockets at home- straw rockets- and launch them.

What happens when an excited atom emits a photon? What can we deduce about that atom based on the photons it can emit? A series of interactive models allows you to examine how the energy levels the electrons of an atom occupy affect the types of photons that can be emitted. Use a digital spectrometer to record which wavelengths certain atoms will emit, and then use this knowledge to compare and identify types of atoms. Students will be abe to:

This lesson is designed for a high school biology class, as it is dependent on students having some prior knowledge of the structure of DNA. It reviews/teaches the key features of DNA structure by allowing students to use the engineering design process to create their own DNA models, compare/contrast provided models, and then edit/assess their own designs.