In this seventh grade science Atmosphere and Weather Unit, students will explore the atmosphere, air and water quality, the water cycle, the greenhouse effect, global warming, climate change, and human-environment interaction through a number of experiments, interactive webquests and projects. They will be exposed to the STEM practices behind growing and agriculture in a hands-on, experiential and experimental life science growing project. They will create terrariums in two-liter soda bottles and will focus on the importance of understanding meteorology and the cycling of water and gasses in and out of the Earth and atmosphere in order to effectively plan, grow and harvest.

This lesson plan engages students in a real-life exploration of climate change as it is affected by greenhouse emissions from vehicles. The aim of this activity is for students to realize the impact of vehicle use in their family and to give students the opportunity to brainstorm viable alternatives to this use.

This is a series of activities demonstrating that air has mass, takes up space, and can exert a force on objects enough to lift them.

By watching and performing several simple experiments, students develop an understanding of the properties of air: it has mass, it takes up space, it can move, it exerts pressure, it can do work.

This is a series of investigations about air and its properties. How air exists all around us, and things it is capable of doing.

This is Activity 12 of a set of Level 1 activities designed by the Science Center for Teaching, Outreach, and Research on Meteorology (STORM) Project. The authors suggest that previous activities in the unit be completed before Activity 12: Air Masses, including those that address pressure systems and dew point temperature. In Activity 12, the students learn about the four main types of air masses that affect weather in the United States, their characteristic temperatures, and humidity levels as it relates to dew point temperatures. The lesson plan follows the 5E format. Initially, students discuss local weather and then examine surface temperature and dew point data on maps to determine patterns and possible locations of air masses. They learn about the source regions of air masses and compare their maps to a forecast weather map with fronts and pressure systems drawn in. During the Extension phase, students access current maps with surface and dew point temperatures at http://www.uni.edu/storm/activities/level1 and try to identify locations of air masses. They sketch in fronts and compare their results to the fronts map. Evaluation consists of collection of student papers.

Phase 1: Definition of Projects and Research Teams (Homework +1 Class)

Each student is assigned the task of proposing a site to investigate within the city and the surrounding region. Students are encouraged to discuss the assignment with community members for suggestions and inspiration. Each student will produce an easel-size poster of their proposal highlighting the following:


Site location;

Reasons for selecting this site;

Potential interest to the community;

Potential logistical problems associated with the proposed site/project.

Posters will be hung in a gallery-walk format, and each student will mark the location of their proposed study site on the classroom map of New York City. The class is given time to read and comment on each of their peers' proposals, after which the instructor will lead a class discussion of the interests, merits, and obstacles associated with each proposal, with the goal of having the class settle on the set of projects on which to move forward.
Students will define groups of 2 to 4 students per project. If more than 4 students are interested in the same site, then multiple groups may develop parallel projects.

Phase 2: Data Collection and Analysis (5 weeks)

In consultation with the instructor, teams develop and implement a sampling protocol, including the documentation of terrain, human activity, and weather conditions (wind speed and direction) at the time of collection. Sample stations and prevailing wind direction are plotted on Google Earth to determine likely sources of particulates. Using binocular microscopes students document size distribution, form, color, and abundance of particulates. This data is analyzed using statistical functions in Excel. Teams use SEM-EDS analysis to determine the composition of particles, and more fully describe their form. Teams submit weekly progress reports, including personal work reports for each team member.

Phase 3: Communication of Results (1 Week)

Teams submit to their instructor a formal laboratory report: Purpose, Equipment, Method, Data Tabulation, Data Analysis, and Conclusions.
Teams prepare an oral presentation, or visual information campaign, targeted at an audience of their choice (e.g., neighbors, church group, community activist group, college administration) using discourse appropriate to that audience. Teams present in an in-class dress-rehearsal prior to their formal presentation. Teams invite members of their desired audience to the presentation (official invitations sent). On the last day of class, the instructor leads a debriefing and critique of the presentations, highlighting results and effective communication techniques.

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The Phoenix metropolitan area, like many large cities, has problems with air pollution at certain times of the year. You can do a simple experiment to determine some of the factors that affect air pollution.

What effect does geography have on air quality? Use this model to explore the effect of point-source pollution, geography, and wind on regional air quality.

What causes an area to have poor air quality? Use this model to explore the connections between pollution sources, weather, geography, and air quality. Discover which weather condition causes the development of additional air pollutants. Compare the effects of two different pollution sources, pollution-control devices, and changing weather conditions on the air quality over a city.

Students are introduced to measuring and identifying sources of air pollution, as well as how environmental engineers try to control and limit the amount of air pollution. In Part 1, students are introduced to nitrogen dioxide as an air pollutant and how it is quantified. Major sources are identified, using EPA bar graphs. Students identify major cities and determine their latitudes and longitudes. They estimate NO2 values from color maps showing monthly NO2 averages from two sources: a NASA satellite and the WSU forecast model AIRPACT. In Part 2, students continue to estimate NO2 values from color maps and use Excel to calculate differences and ratios to determine the model's performance. They gain experience working with very large numbers written in scientific notation, as well as spreadsheet application capabilities.

Air pressure is pushing on us all the time although we do not usually notice it. In this activity, students learn about the units of pressure and get a sense of just how much air pressure is pushing on them.

Students engage in hands-on, true-to-life research experiences on air quality topics chosen for personal interest through a unit composed of one lesson and five associated activities. Using a project-based learning approach suitable for secondary science classrooms and low-cost air quality monitors, students gain the background and skills needed to conduct their own air quality research projects. The curriculum provides: 1) an introduction to air quality science, 2) data collection practice, 3) data analysis practice, 4) help planning and conducting a research project and 5) guidance in interpreting data and presenting research in professional poster format. The comprehensive curriculum requires no pre-requisite knowledge of air quality science or engineering. This curriculum takes advantage of low-cost, next-generation, open-source air quality monitors called Pods. These monitors were developed in a mechanical engineering lab at the University of Colorado Boulder and are used for academic research as well as education and outreach. The monitors are made available for use with this curriculum through AQ-IQ Kits that may be rented from the university by teachers. Alternatively, nearly the entire unit, including the student-directed projects, could also be completed without an air quality monitor. For example, students can design research projects that utilize existing air quality data instead of collecting their own, which is highly feasible since much data is publically available. In addition, other low-cost monitors could be used instead of the Pods. Also, the curriculum is intentionally flexible, so that the lesson and its activities can be used individually. See the Other section for details about the Pods and ideas for alternative equipment, usage without air quality monitors, and adjustments to individually teach the lesson and activities.

In this module, students engage in a visual demonstration on the causes & effects of air pollutants on air quality and kinesthetic activities on particulate matter & visibility.

This video discusses ways that communities can prepare for air quality changes that will occur due to rising global temperatures.

This is an inquiry activity that relies of pervious understanding of balancing and weighing to introduce a properties of air.

Students are introduced to air masses, with an emphasis on the differences between and characteristics of high- versus low-pressure air systems. Students also hear about weather forecasting instrumentation and how engineers work to improve these instruments for atmospheric measurements on Earth and in space.

Students learn what causes air pollution and how to investigate the different pollutants that exist, such as toxic gases and particulate matter. They investigate the technologies developed by engineers to reduce air pollution.

During World War Two, a fierce battle between American and Japanese forces on Kwajalein atoll left a trail of debris on the deep lagoon floor. This lagoon now has one of the largest collections of well-preserved aircraft in the world. In this video, as part of the first ever film crew allowed onto this secret military base, Jonathan explores a B-25, F4-U Corsair and Dauntless dive bomber still sitting on the bottom of the ocean, as if ready to take off. Please see the accompanying study guide for educational objectives and discussion points.

Classroom experiment illustrating the law of diminishing marginal productivity through the production of paper airplanes.