Students experiment with a new material—aerogel. Aerogel is a synthetic (human-made) porous ultra-light (low-density) material, in which the liquid component of a gel is replaced with a gas. In this activity, student pairs use aerogel to simulate the environmental engineering application of cleaning up oil spills. In a simple and fun way, this activity incorporates density calculations, the material effects of surface area, and hydrophobic and hydrophilic properties.

 Oil spill cleaner-upper | micro:bit Increase scientific knowledge, develop research capacity and transfer marine technology, taking into account the Intergovernmental Oceanographic Commission Criteria and Guidelines on the Transfer of Marine Technology, in order to improve ocean health and to enhance the contribution of marine biodiversity to the development of developing countries, in particular small island developing states and least-developed countries.This activity is in two parts, you can do either part – or both. The first part can be completed with no additional hardware or even micro:bits, comprising a challenge to design an efficient algorithm to clean an area of sea. The second part builds on this to create an autonomous vehicle that can mop up oil spills.

As part of a (hypothetical) challenge to help a city find the most affordable and environmentally friendly way to clean up an oil spill, students design and conduct controlled experiments to quantify capillary action in sand. Like engineers and entrepreneurs, student teams use affordable materials to design and construct models to measure the rate of capillary action in four types of sand: coarse, medium, fine and mixed. After observing and learning from a teacher-conducted capillary tube demonstration, teams are given a selection of possible materials and a budget to work within as they design their own experimental setups. After the construction of their designs, they take measurements to quantify the rate of capillary action, create graphs to analyze the data, and make concluding recommendations. Groups compare data and discuss as a class the pros and cons of their designs. Pre- and post-evaluations and two worksheets are provided.

In this lab activity, students determine density differences of water samples with varying temperature and salinity levels. Students synthesize information to predict the effects of oil in given water samples.

In this unit, students explore the various roles of environmental engineers, including: environmental cleanup, water quality, groundwater resources, surface water and groundwater flow, water contamination, waste disposal and air pollution. Specifically, students learn about the factors that affect water quality and the conditions that enable different animals and plants to survive in their environments. Next, students learn about groundwater and how environmental engineers study groundwater to predict the distribution of surface pollution. Students also learn how water flows through the ground, what an aquifer is and what soil properties are used to predict groundwater flow. Additionally, students discover that the water they drink everyday comes from many different sources, including surface water and groundwater. They investigate possible scenarios of drinking water contamination and how contaminants can negatively affect the organisms that come in contact with them. Students learn about the three most common methods of waste disposal and how environmental engineers continue to develop technologies to dispose of trash. Lastly, students learn what causes air pollution and how to investigate the different pollutants that exist, such as toxic gases and particulate matter. Also, they investigate the technologies developed by engineers to reduce air pollution.

This activity is a class lab activity in which students will observe unknown rocks and learn about how they fit into the rock cycle.

This class is designed to expose you to the cycles of disasters, the roots of emergency planning in the U.S., how to understand and map vulnerabilities, and expose you to the disaster planning in different contexts, including in developing countries.

This class is designed to expose you to the cycles of disasters, the roots of emergency planning in the U.S., how to understand and map vulnerabilities, and expose you to the disaster planning in different contexts, including in developing countries.

This activity is a classroom chemistry lab where students will test different cleaning methods that could be used in oil spills. They will see the effects how oil spills damage animals and the environment.

This video adapted from KTOO explores the impact of oil contamination on the herring population of Prince William Sound, Alaska, in 1999, 10 years after the Exxon Valdez oil spill.

This lesson will allow students to explore an important role of environmental engineers: cleaning the environment. Students will learn details about the Exxon Valdez oil spill, which was one of the most publicized and studied environmental tragedies in history. In the accompanying activity, they will try many "engineered" strategies to clean up their own manufactured oil spill and learn the difficulties of dealing with oil released into our waters.

This hands-on experiment will provide students with an understanding of the issues that surround environmental cleanup. Students will create their own oil spill, try different methods for cleaning it up, and then discuss the merits of each method in terms of effectiveness (cleanliness) and cost. They will be asked to put themselves in the place of both an environmental engineer and an oil company owner who are responsible for the clean-up.

This video segment adapted from NOVA follows the clean-up effort after the 1989 Exxon Valdez oil spill off the coast of Alaska. Also featured is a marsh where an oil spill occurred 20 years earlier; analysis suggests that environmental damage may last for decades.

Students learn about oil spills and their environmental and economic effects. They experience the steps of the engineering design process as they brainstorm potential methods for oil spill clean-up, and then design, build, and re-design oil booms to prevent the spread of oil spills. During a reflective session after cleaning up their oil booms, students come up with ideas on how to reduce oil consumption to prevent future oil spills.

Oil spills have been a persistent problem since the start of the oil industry. Millions of wells and trillions of barrels of oil extracted have resulted in significant environmental impact. Accidents in the complex supply chain release toxic crude and refined oil, posing health risks and requiring costly cleanup. Safety measures have improved, but unreported spills remain a concern.

As the number of ice-free days in the seas surrounding Alaska increases over time, so do opportunities. Oil and gas companies are ramping up offshore exploration and drilling in the Arctic and the shipping industry is increasing traffic around and through the region. As a result, Arctic residents may have new opportunities for jobs and development across the region. There’s also a downside to the increased activity. Oil and gas extraction operations occasionally have accidents—events that can result in massive oil spills.

This resource is a video abstract of a research paper created by Research Square on behalf of its authors. It provides a synopsis that's easy to understand, and can be used to introduce the topics it covers to students, researchers, and the general public. The video's transcript is also provided in full, with a portion provided below for preview:

"Oil spills have devastating effects on the environment, and thousands, of varying size, occur each year. Spilled oil can be removed from the environment in numerous ways, such as with the use of dispersants to break up oil slicks on the water surface. But while oil spills themselves pose well-known threats to marine life, the methods used for oil cleanup can also have unintended consequences. To examine these effects, researchers recently investigated how treatment of oil with dispersants produced synthetically (Finasol) and by bacteria (rhamnolipid) impact microbial communities and their ability to break down oil from the subarctic Atlantic Ocean. They found that cold-loving bacteria initially dominated the bacterial communities when both dispersants were used, but some key species of bacteria that specialize in breaking down aromatic hydrocarbons, which are the major and most toxic components of crude oil, became abundant over time in only the presence of rhamnolipid..."

The rest of the transcript, along with a link to the research itself, is available on the resource itself.