In this presentation, we will discuss how we can know whether one individual is more susceptible to harmful effect of air pollution than others are. Everyone is exposed, but some groups may be more susceptible to the harmful effect of air pollution than others may.

In this lecture, we will describe the mechanisms by which air pollution causes pulmonary health effects in the human population. The pulmonary health effects include exacerbation of asthma and chronic obstructive pulmonary diseases (COPD), increased risk of lower
respiratory tracts infections and lung cancer.

In this presentation, we will describe the mechanisms by which air pollution causes health effects in other parts of the body than the lungs. In continuation of this, we will discuss the important mechanisms of extra pulmonary health effect.

There is a long way before the whole world complies with the WHO guidelines for air quality, but the enormous burden of disease from outdoor air pollution forces us to increase action to come as far as possible. In continuation of this, we will discuss what we can do about air pollution at global, international, national, city and individual levels. Most of the actions to reduce air pollution also mitigates climate change and/or promote health in other ways – so there are many win-win and
win-win-win situations

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.

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.

SYNOPSIS: In this lesson, students learn about particle pollution.

SCIENTIST NOTES: This lesson introduces students to gain elementary knowledge about air pollution, its sources, and implications on air quality. It provides critical insights on the impacts it has on low-income communities of Los Angeles. The lesson materials are well-written and cited. Thus, this lesson has passed our science review.

POSITIVES:
-This lesson dives deeper into the concept of air pollution and how to monitor air quality.
-This lesson involves movement and allows kids to have fun while learning about something serious.

ADDITIONAL PREREQUISITES:
-You will need to prepare the appropriate materials for The Cilia Game before class begins.
-The Cilia Game is quite silly. Be prepared for some laughs as the "cilia" try to defend the "lungs"!
-Cilia are tiny hair-like structures in our respiratory system that protect our lungs from foreign matter like particle pollution.
-In this lesson we use the term "particle pollution." This is usually referred to as "particulate pollution" or "particulate matter." For the purposes of this lesson, we have decided to use the simpler "particle pollution."
-"Air pollution" is kind of a catchall term, referring to things like ozone, particulate matter, and even greenhouse gases. This can be tricky for elementary students to sort out. The purpose of this lesson is for students to better understand particulate matter.

DIFFERENTIATION:
-Curious students may want more time to explore the interactive map of air quality.
-Students who complete their journal entry early can make their own air quality monitor.
-Be sensitive to your students' health situation. Some students with asthma or who know someone with asthma may find it difficult to learn more about this topic.

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.

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.

In this discussion you can learn how you can combat light pollution and how it impacts the world around us.

This animated video consist of information about air pollution , its sources, its impact and control measures

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:

"This video is based on a preprint. Preprints are preliminary reports that have not undergone peer review. They should not be considered conclusive, used to inform clinical practice, or referenced by the media as validated information. As the COVID-19 pandemic wages on, scientific research is uncovering multiple forces that alter the spread of the disease. One enhancing factor could be air pollution. Researchers at the University of Cambridge recently linked COVID-19 to air pollution levels in England, where more than 45,000 patients have died of COVID-19. Initial findings revealed that regional variations in nitrogen oxide and ozone in particular could predict COVID-19 cases and deaths. The risk of infection was found to be increased by exposure to particulate matter (PM). Such pollution can lead to increased inflammation in the lungs or even help carry the virus that causes COVID-19 across large distances..."

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

In this Interactive Lecture Demonstration, students will predict the main issues that might be included in short French language videos treating topics such as endangered species, organic farming, the effect of aerosols on the environment, pollution and sustainable development. They will then view short videos on the topics and reflect on how their prior assumptions meshed with reality.

Animals are an important part of the ecosystem. They help to maintain the balance of nature by providing food for other animals, by pollinating plants, and by dispersing seeds. Animals are also important to humans, as they provide us with food, clothing, and companionship.However, animals are facing a number of threats, including habitat loss, climate change, and pollution. These threats are causing the decline of many animal species, and some species are even facing extinction.It is important to conserve animals and to protect their habitats so that future generations can enjoy them.

Animals are an important part of the ecosystem. They help to maintain the balance of nature by providing food for other animals, by pollinating plants, and by dispersing seeds. Animals are also important to humans, as they provide us with food, clothing, and companionship.However, animals are facing a number of threats, including habitat loss, climate change, and pollution. These threats are causing the decline of many animal species, and some species are even facing extinction.It is important to conserve animals and to protect their habitats so that future generations can enjoy them.

This course details the quantitative treatment of chemical processes in aquatic systems such as lakes, oceans, rivers, estuaries, groundwaters, and wastewaters. It includes a brief review of chemical thermodynamics that is followed by discussion of acid-base, precipitation-dissolution, coordination, and reduction-oxidation reactions. Emphasis is on equilibrium calculations as a tool for understanding the variables that govern the chemical composition of aquatic systems and the fate of inorganic pollutants.
This course is offered through The MIT/WHOI Joint Program. The MIT/WHOI Joint Program is one of the premier marine science graduate programs in the world. It draws on the complementary strengths and approaches of two great institutions: the Massachusetts Institute of Technology (MIT) and the Woods Hole Oceanographic Institution (WHOI).

In this lesson children will investigate 6 major pollutants in our world and how they can be eliminated or limited. This lesson is a continuation of the other Are We Our Own Worst Enemy ? lesson plans. It can stand on its own but if you haven't taught the others you may want to show the World Population Over Time video before starting this lesson. This lesson results from a collaboration between the Alabama State Department of Education and ASTA.

This course explores the physical processes that control Earth's atmosphere, ocean, and climate. Quantitative methods for constructing mass and energy budgets. Topics include clouds, rain, severe storms, regional climate, the ozone layer, air pollution, ocean currents and productivity, the seasons, El Ni–o, the history of Earth's climate, global warming, energy, and water resources.

This course provides a detailed overview of the chemical transformations that control the abundances of key trace species in the Earth’s atmosphere. Emphasizes the effects of human activity on air quality and climate. Topics include photochemistry, kinetics, and thermodynamics important to the chemistry of the atmosphere; stratospheric ozone depletion; oxidation chemistry of the troposphere; photochemical smog; aerosol chemistry; and sources and sinks of greenhouse gases and other climate forcers.

This course provides a detailed overview of the chemical transformations that control the abundances of key trace species in the Earth's atmosphere. Emphasizes the effects of human activity on air quality and climate. Topics include photochemistry, kinetics, and thermodynamics important to the chemistry of the atmosphere; stratospheric ozone depletion; oxidation chemistry of the troposphere; photochemical smog; aerosol chemistry; and sources and sinks of greenhouse gases and other climate forcers.