This activity involves student research on the Internet to create a PowerPoint presentation showing the various parts that make up a biome (abiotic & biotic factors).

Students discover that they already know a lot about energy through their own life experiences. As active consumers of various forms of energy, they are aware of energy purchases for electricity, home heating/cooling and transportation. Through the pedagogical technique of a "carousel," all students become involved in brainstorming and contributing ideas. The goal is to introduce students to key terms and issues associated with energy, as a prerequisite for the rest of the unit.

Campus Climate Conversations are designed to be both educational and "deliberative," meaning students, staff, and faculty interact with one another in small groups to share views and ideas about climate action strategies. This activity is structured to enhance education and engagement, and to generate collaborative climate action strategies.

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Faculty and students of politics inevitably engage with contentious debates about global inequality and development, conflict, and environmental sustainability. Teaching and learning outcomes in politics tend to emphasize critical and analytical thinking, but have paid less attention to emotion and feeling in considering how to navigate current issues. How can contemplative practices help instructors and students not only intellectually consider, but also emotionally hold difficult and often divisive and unsettling issues? In what ways can such practices both create space for honest, compassionate discussion and encourage engaged citizenship? By using a guided exercise of self-reflection and dialogue, students will develop self-awareness of their emotional responses and of their peers to contentious political issues, and recognize the importance of open listening and dialogue for gaining a deeper appreciation of contrasting views.

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I use an "engaging question" on the first day of class in all of my courses. This activity is designed to be both engaging and central to all of the course content. That is, the activity is designed around questions that we can keep coming back to, over and over, after each learning unit. This approach not only provides a unifying focus for the course, but it also provides an opportunity to model critical thinking as we revisit the question each time with a different perspective. For the Dynamic Earth and Global Change (the Physical Geology course at Macalester) I chose a question about climate change. The activity starts with two graphs (plots of surface temperature and atmosphere CO2 composition for the past 1,000 years). Students are asked to describe the graphs, interpret the graphs, make some predictions, and explain the graphs using basic earth science processes.

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This introductory activity engages learners in the study of earthquake hazards and the risk these hazards pose to humans in the communities in which we live. Learners will compare three maps of Anchorage, AK, depicting spatial information related to seismic hazards to generate questions about the factors that influence shaking intensity and damage to the built environment during earthquakes.

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Students extend their knowledge of the skeletal system to biomedical engineering design, specifically the concept of artificial limbs. Students relate the skeleton as a structural system, focusing on the leg as structural necessity. They learn about the design considerations involved in the creation of artificial limbs, including materials and sensors.

Students are introduced to genetic techniques such as DNA electrophoresis and imaging technologies used for molecular and DNA structure visualization. In the field of molecular biology and genetics, biomedical engineering plays an increasing role in the development of new medical treatments and discoveries. Engineering applications of nanotechnology such as lab-on-a-chip and deoxyribonucleic acid (DNA) microarrays are used to study the human genome and decode the complex interactions involved in genetic processes.

Under the "The Science Behind Harry Potter" theme, a succession of diverse complex scientific topics are presented to students through direct immersive interaction. Student interest is piqued by the incorporation of popular culture into the classroom via a series of interactive, hands-on Harry Potter/movie-themed lessons and activities. They learn about the basics of acid/base chemistry (invisible ink), genetics and trait prediction (parseltongue trait in families), and force and projectile motion (motion of the thrown remembrall). In each lesson and activity, students are also made aware of the engineering connections to these fields of scientific study.

This biomimetic engineering challenge introduces students to the fields of nanotechnology and biomimicry. Students explore how to modify surfaces such as wood or cotton fabric at the nanoscale. They create specialized materials with features such as waterproofing and stain resistance. The challenge starts with student teams identifying an intended user and developing scenarios for using their developed material. Students then design and create their specialized material using everyday materials. Each students test each design under specific testing constraints to determine the hydrophobicity of the material. After testing, teams iterate ways to improve their self-cleaning superhydrophobic modification technique for their design. After iterating and testing their designs, students present their final product and results to the class.

Students design a temporary habitat for a future classroom pet—a hingeback tortoise. Based on their background research, students identify what type of environment this tortoise needs and how to recreate that environment in the classroom. The students divide into groups and investigate the features of a habitat for a hingeback tortoise. These features include how many holes a temporary habitat may need, the animal’s ideal type of bedding, and how much water is needed to create the necessary humidity level within the tortoise’s environment. Each group communicates and presents this information to the rest of the class after they research, brainstorm, collect and analyze data, and design their final plan.

This unit covers the broad spectrum of topics that make-up our very amazing human body. Students are introduced to the space environment and learn the major differences between the environment on Earth and that of outer space. The engineering challenges that arise because of these discrepancies are also discussed. Then, students dive into the different components that make up the human body: muscles, bones and joints, the digestive and circulatory systems, the nervous and endocrine systems, the urinary system, the respiratory system, and finally the immune system. Students learn about the different types of muscles in the human body and the effects of microgravity on muscles. Also, they learn about the skeleton, the number of and types of bones in the body, and how outer space affects astronauts' bones. In the lessons on the digestive, circulatory, nervous and endocrine systems, students learn how these vital system work and the challenges faced by astronauts whose systems are impacted by spaceflight. And lastly, advances in engineering technology are discussed through the lessons on the urinary, respiratory and immune systems while students learn how these systems work with all the other body components to help keep the human body healthy.

Students learn how healthy human heart valves function and the different diseases that can affect heart valves. They also learn about devices and procedures that biomedical engineers have designed to help people with damaged or diseased heart valves. Students learn about the pros and cons of different materials and how doctors choose which engineered artificial heart valves are appropriate for certain people.

The Common Core State Standards for English Language Arts & Literacy in History/Social Studies, Science, and Technical Subjects (“the standards”) represent the next generation of K–12 standards designed to prepare all students for success in college, career, and life by the time they graduate from high school.

ELL students create and share a botanic field guide incorporating depiction, measurement, description, and classification of common Minnesota trees, shrubs, wildflowers, and plants.

This is a problem set that gets students to think quantitatively about magmas. To be most effective, it should be done in conjunction with a showing of some or all (I recommend some...) of the movie "Volcano". How much water would be needed to stop a lava flow on Wilshire Blvd. in Los Angeles?!

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This assignment requires that students research the historical context of an environmental issue within their own communities and apply different types of organizing/advocacy tactics for instigating social change.

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The classic campus-based project is an environmental or sustainability assessment, often referred to as an environmental audit. This course, taught at Carleton in 2001, describes how this type of project can be undertaken. In this scenario, a student, campus environmental group or class researches aspects the envinormental impact of the school.

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The goal of this exercise is for students to complete a basic environmental assessment of Newark Road Prairie, a 35-acre wet-mesic prairie and state natural area owned by Beloit College.

The exercise is completed over a 5-week period as the class covers chapters on Streams and Flooding, Soil Resources, and Groundwater Resources. Students visit the prairie once a week during a 2-hour class period. Two additional 2-hour class periods per week are devoted to lecture, discussion, and analysis of field data. During the site visits, students conduct an initial field reconnaissance, measure the discharge of a stream that flows through the prairie (inflow and outflow), describe prairie soils, and measure water levels at seven previously installed water table wells and four staff gages. The field data can be collected in any order after the field reconnaissance is completed.

All field data, including GPS coordinates of the positions of discharge measurements, soils samples, and wells, are recorded in a standardized data dictionary (using GPS Pathfinder Office/TerraSync software) on a handheld PC. A satellite image of the prairie is loaded on the handheld PC, so that students can see where they are relative to other physical features as they collect their data. Data are downloaded in the lab and utilized for the construction of a water table map (by hand) and an assessment of site conditions and potential impacts.

In addition to the data collected in the field, students are given a topographic map of the region, which they utilize to delineate the basin for the stream that flows through the prairie, and a soils map of the prairie, with which they compare their own soil descriptions. They are also given a land use map of the region. Using all of this information, students write a 4 to 5 page report that describes current conditions and potential challenges or threats to the preservation and management of the prairie.

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This four week curriculum is for elementary learners to explore environmental engineering in urban environments. The unit starts with a broad question of “how can we make our community more sustainable?”, the unit will cover what the field of environmental engineering is, what predictability, mitigation and sustainability are, and how they relate to each other. These principles will be taught as vocabulary and will be supported with the use of anchor charts; students will be expected to use them during discussions. The unit will teach about urban infrastructure and the phenomenon of the Urban Heat Island effect. Students will then learn about and explore the possibilities of alternative energy sources and cities that already implementing green engineering. Students will explore how they can answer the question that was presented to them at the beginning of the unit. Following the engineering design process students will plan changes that they would make to their own city (in our case New Haven, Connecticut). Students will act as environmental engineers to come up with potential solutions to answer the broad question posed at the beginning of the unit.