The purpose of this resource is to measure and classify the plant life at a Land Cover Site to help determine the MUC classification.

The purpose of this resource is to measure and classify the plant life at a Land Cover Site to help determine the MUC classification.

Students use ultrasonic sensors and LEGO© MINDSTORMS© NXT robots to emulate how bats use echolocation to detect obstacles. They measure the robot's reaction times as it senses objects at two distances and with different sensor threshold values, and again after making adjustments to optimize its effectiveness. Like engineers, they gather and graph data to analyze a given design (from the tutorial) and make modifications to the sensor placement and/or threshold values in order to improve the robot's performance (iterative design). Students see how problem solving with biomimicry design is directly related to understanding and making observations of nature.

This is a long-term inquiry activity in which students investigate locations they believe harbor cellulose-digesting microbes, collect samples, isolate them on selective media, and screen them for cellulase activity. These novel microbes may be useful for the production of cellulosic ethanol. In the process they learn about plating techniques, serial dilutions, symbiotic relationships and enzyme specificity. Two methods are provided, one focusing on isolation of pure microbial strains, the other focusing on finding symbiotic communities of microbes. The companion activity is here: https://www.glbrc.org/outreach/educational-materials/bioprospecting-cellulose-degrading-microbes-filter-paper-assay

By studying key processes in the carbon cycle, such as photosynthesis, composting and anaerobic digestion, students learn how nature and engineers "biorecycle" carbon. Students are exposed to examples of how microbes play many roles in various systems to recycle organic materials and also learn how the carbon cycle can be used to make or release energy.

How can you tell if harmful bacteria are in your food or water that might make you sick? What you eat or drink can be contaminated with bacteria, viruses, parasites and toxins—pathogens that can be harmful or even fatal. Students learn which contaminants have the greatest health risks and how they enter the food supply. While food supply contaminants can be identified from cultures grown in labs, bioengineers are creating technologies to make the detection of contaminated food quicker, easier and more effective.

This lesson begins with a demonstration prompting students to consider how current generates a magnetic field and the direction of the field that is generated. Through formal lecture, students learn Biot-Savart's law in order to calculate, most simply, the magnetic field produced in the center of a circular current carrying loop. For applications, students find it is necessary to integrate the field produced over all small segments in an actual current carrying wire.

This materials have been compiled to support an introductory Biotechnology course for high school students.

This five-part lesson plan for middle school science classrooms is designed for exploration and learning about the impacts of light pollution on migratory birds in Connecticut. Light pollution negatively affects many species of migratory birds that fly through Connecticut, especially migratory songbirds.

The learning module equips learners with the necessary skills and knowledge to extend their understanding of light pollution and its effects on migratory bird populations as an unintended consequence of human development. It identifies specific learning goals, objectives, and activities for students, providing both direction and pace for the learning process. It also serves as a roadmap for educators with sequential learning objectives and thoughtful handout materials.

This curriculum was designed by Catherine Ferreri, a sixth-grade science teacher at Coleytown Middle School, in Westport, CT, who has a background in biology and the environment. Meredith Barges, a bird-friendly building expert and co-chair of Lights Out Connecticut, collaborated on the development and design of the project. The project was funded by the Hartford Audubon Society and individual donors to Lights Out Connecticut.

Educators who wish to adapt the curriculum for their students and classroom goals are encouraged to download the PDF as a word-processing document and make modifications directly to the main document and handout materials.

It is hoped that by increasing learning and engagement by young people about bird migration—and the challenges migratory birds face as a result of light pollution—will inspire greater care for migratory birds and meaningful, lasting change.

In this activity, students construct "flying birds" (pollution collectors) from paper and wire hangers. Students hang up their birds to see how they react to air pollution, and compare and make observations about the differences in the birds.

This sequence of instruction was developed to help elementary teachers who were working remotely.  We developed a short storyline that ties together a few sessions to help explore a specific concept.  We tried to include some activities that honored and included the student’s family and experience, and some that included the potential for ELA learning goals.Students make observations of the behaviors while watching short videos of Bald Eagles and Hummingbirds.  They then make observations of birds in their own neighborhood or school grounds.  They use these observations to explore th knees of these organisms and behaviors used to meet these needs.It is part of Clime Time - a collaboration among all nine Educational Service Districts (ESDs) in Washington and many Community Partners to provide programs for science teacher training around Next Generation Science Standards (NGSS) and climate science, thanks to grant money made available to the Office of the Superintendent of Public Instruction (OSPI) by Governor Inslee. 

In this series of activities students investigate the effects of black carbon on snow and ice melt in the Arctic. The lesson begins with an activity that introduces students to the concept of thermal energy and how light and dark surfaces reflect and absorb radiant energy differently. To help quantify the relationship between carbon and ice melt, the wet lab activity has students create ice samples both with and without black carbon and then compare how they respond to radiant energy while considering implications for the Arctic.

How does the blackbody spectrum of the sun compare to visible light? Learn about the blackbody spectrum of the sun, a light bulb, an oven, and the earth. Adjust the temperature to see the wavelength and intensity of the spectrum change. View the color of the peak of the spectral curve.

Rockets need a lot of thrust to get into space. In this lesson, students learn how rocket thrust is generated with propellant. The two types of propellants are discussed and relation to their use on rockets is investigated. Students learn why engineers need to know the different properties of propellants.

Students are introduced to our Sun as they explore its composition, what is happening inside it, its relationship to our planet (our energy source), and the ways engineers help us learn about it.

Read this blog post for background information about the relationship between the biological environment and life processes and systems in Fast Plants. Growing healthy Fast Plants is easy if you understand how the environment can affect growth and development. Three broad categories of environmental factors influence how an individual plant matures through its life cycle:  1) the physical environment, 2) the chemical environment, 3) the biological environment.  Based on this information about standard conditions for optimal Fast Plants growth, one could easily design a wide variety of controlled experiments. Questions naturally arise while reading about optimal conditions that could be investigated by designing an experiment to how varying one condition affects growth, development and/or reproduction. This blog post is part of a series explaining how key environmental factors–physical, chemical, and biological–can impact the growth of Wisconsin Fast Plants.

Read this blog post for background information about the relationship between the physical environment and life processes and systems in Fast Plants. Growing healthy Fast Plants is easy if you understand how the environment can affect growth and development. Three broad categories of environmental factors influence how an individual plant matures through its life cycle:  1) the physical environment, 2) the chemical environment, 3) the biological environment. Based on this information about standard conditions for optimal Fast Plants growth, one could easily design a wide variety of controlled experiments. Questions naturally arise while reading about optimal conditions that could be investigated by designing an experiment to how varying one condition affects growth, development and/or reproduction. This blog post is part of a series explaining how key environmental factors "physical, chemical, and biological" can impact the growth of Wisconsin Fast Plants.

Students are introduced to the circulatory system with an emphasis on the blood clotting process, including coagulation and the formation and degradation of polymers through their underlying atomic properties. They learn about the medical emergency of strokes the loss of brain function commonly due to blood clots including various causes and the different effects depending on the brain location, as well as blood clot removal devices designed by biomedical engineers.

Students make a skydiver and parachute contraption to demonstrate how drag caused by air resistance slows the descent of skydivers as they travel back to Earth. Gravity pulls the skydiver toward the Earth, while the air trapped by the parachute provides an upward resisting force (drag) on the skydiver.

Students are introduced to the circulatory system, the heart, and blood flow in the human body. Through guided pre-reading, during-reading and post-reading activities, students learn about the circulatory system's parts, functions and disorders, as well as engineering medical solutions. By cultivating literacy practices as presented in this lesson, students can improve their scientific and technological literacy.