This course describes the large-scale circulation systems of the tropical atmosphere and analyses the dynamics of such systems. Topics include: Radiative-convective equilibrium; the Hadley and walker circulation; monsoons; tropical boundary layers; theory of the response of the tropical atmosphere to localized sea-surface temperature anomalies; intraseasonal oscillations; equatorial waves; El Niño/Southern Oscillation; easterly waves; and tropical cyclones.

Forecasting is the ultimate form of model validation. But even if a perfect model is in hand, imperfect forecasts are likely. This course will cover the factors that limit our ability to produce good forecasts, will show how the quality of forecasts can be gauged a priori (predicting our ability to predict!), and will cover the state of the art in operational atmosphere and ocean forecasting systems.

This course is a laboratory accompaniment to 12.803, Quasi-balanced Circulations in Oceans and Atmospheres. The subject includes analysis of observations of oceanic and atmospheric quasi-balanced flows, computational models, and rotating tank experiments. Student projects illustrate the basic principles of potential vorticity conservation and inversion, Rossby wave propagation, baroclinic instability, and the behavior of isolated vortices.

Through a role-playing game, students discover the inequalities between countries with respect to wealth and greenhouse gas emissions.

The students perform an experiment to understand the link between acidity and pH, and also between CO2 concentration in the atmosphere and ocean acidification.

The students carry out an experiment to ascertain how the thermal expansion of seawater contributes to sea level rise.

The numerical methods, formulation and parameterizations used in models of the circulation of the atmosphere and ocean will be described in detail. Widely used numerical methods will be the focus but we will also review emerging concepts and new methods. The numerics underlying a hierarchy of models will be discussed, ranging from simple GFD models to the high-end GCMs. In the context of ocean GCMs, we will describe parameterization of geostrophic eddies, mixing and the surface and bottom boundary layers. In the atmosphere, we will review parameterizations of convection and large scale condensation, the planetary boundary layer and radiative transfer.

Students write about the important aspects of a species of sea life, including physical characteristics, habitat, behaviors and interaction with humans and also provide a video that addresses that sea life along with a short summary. The video and its respective summary are then required to be uploaded to a discussion board so students can share what they learned about the species that they selected.

A Student’s Guide to Tropical Marine Biology is written entirely by students enrolled in the Keene State College Tropical Marine Biology course taught by Dr. Karen Cangialosi. Our goal was to investigate three main aspects of tropical marine biology: understanding the system, identifying problems, and evaluating solutions. Each of the sections contains chapters that utilize openly licensed material and images, and are rich with hyperlinks to other sources. Some of the most pressing tropical marine ecosystem issues are broken up into five sections: Coral Reefs and Diversity, Common Fishes to the Coral Reef, Environmental Threats, Reef Conservation, and Major Marine Phyla. These sections are not mutually exclusive; repetition in some content between chapters is intentional as we expect that users may not read the whole book. This work represents a unique collaborative process with many students across semesters authoring and editing, and therefore reflects the interests and intentions of a broad range of students, not one person’s ideas. This collaboration began with contributions from KSC students in the 2017 semester and includes work from the 2019 class, as well as new content and editorial work from 2017 & 2019 alumni. We look forward to future editions of this book. Enjoy exploring the rainforests of the sea through our collaborative project and please share with those who care!

This lesson guides students to connect the PBS Adaptation video series on climate adaptation to their own community. Students describe their community, identify climate impacts faced by their community, research how their community is adapting to those impacts, and then create a digital story about what they found.

Students work in pairs to survey seafood items sold in local grocery stores or fish markets, recording whether items are farm-raised or wild caught, fresh, frozen or preserved, as well as country of origin. Students use the Seafood Watch website to research the status of each seafood item (e.g., best choice, good choice or avoid). Class data is compiled in an online or Excel spreadsheet. Students use class data to create bar graphs and pie charts of the data for the different categories. Students turn in individual analyses and answer questions based on class results.

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This hands-on lab activity is designed to teach students about how density differences, due to salinity, drive the flow of currents in the ocean. It also helps develop skills in performing and designing simple laboratory measurements; data entry, calculations and graph plotting in a spreadsheet; and comparing experimental data with a theoretical equation.
Key words: ocean circulation; density driven flows; salinity; ocean density; thermohaline circulation.

To prepare for this exercise, students will read about the Earth's energy balance, the electromagnetic spectrum (including visible solar and invisible infrared energy), the effect of the earth's atmosphere, and the earth's resulting general oceanic and atmospheric circulation. For this I like Chapters 3, 4, & 5 in "The Earth System" (2nd Ed.) by Kump, Kasting, & Crane. The students' first step is to estimate zonal averages of Incoming Solar (Shortwave), Absorbed Shortwave, and Outgoing Longwave Radiation from 11x17in color maps of Earth Radiation Budget Experiment (ERBE) data. Then I remix the groups and they create zonal averages of these data at particular longitudes (like Fig. 2-14 in Ruddiman, "Earth's Climate: Past & Future").

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In this Earth Exploration Toolbook chapter, students select, explore, and analyze satellite imagery. They do so in the context of a case study of the origins of atmospheric carbon monoxide and aerosols, tiny solid airborne particles such as smoke from forest fires and dust from desert wind storms. They use the software tool ImageJ to animate a year of monthly images of aerosol data and then compare the animation to one created for monthly images of carbon monoxide data. Students select, explore, and analyze satellite imagery using NASA Earth Observatory (NEO) satellite data and NEO Image Composite Explorer (ICE) tool to investigate seasonal and geographic patterns and variations in concentration of CO and aerosols in the atmosphere.

This course is an introduction to basic ideas of geophysical wave motion in rotating, stratified, and rotating-stratified fluids. Subject begins with general wave concepts of phase and group velocity. It also covers the dynamics and kinematics of gravity waves with a focus on dispersion, energy flux, initial value problems, etc. Also addressed are subject foundation used to study internal and inertial waves, Kelvin, Poincare, and Rossby waves in homogeneous and stratified fluids. Laplace tidal equations are applied to equatorial waves. Other topics include: resonant interactions, potential vorticity, wave-mean flow interactions, and instability.

In this classic hands-on activity, learners estimate the length of a molecule by floating a fatty acid (oleic acid) on water. This lab asks learners to record measurements and make calculations related to volume, diameter, area, and height. Learners also convert meters into nanometers. Includes teacher and student worksheets but lacks in depth procedure information. The author suggests educators search the web for more complete lab instructions.

Children test how cornstarch and glitter in water move when disturbed. They compare their observations with videos of Jupiter's and Earth's storm movements.

This course is an introduction to basic ideas of geophysical wave motion in rotating, stratified, and rotating-stratified fluids. Subject begins with general wave concepts of phase and group velocity. It also covers the dynamics and kinematics of gravity waves with a focus on dispersion, energy flux, initial value problems, etc.

Students extract streams and watersheds from a DEM for the island of Hawai'i. They then look to seeif there is a correlation between precipitation and the way a stream network develops on a mountain. Students also investigate if this is related to vegetation, soil type, and slope.