In this activity students investigate tidal phenomena by exploring water level observational (or predicted tidal) data from several locations around the world that provide examples of semi-diurnal, diurnal, and mixed tides. Students are asked to identify patterns of variability and differences among the sites on time scales of just a few days and over a period of a couple months. The activity is designed more to get students thinking about tides, asking questions about the causes of tidal variations, and thinking about ways to answer these questions, as opposed to providing an explanation of tidal processes. The activity leads to a body of observations that generate numerous questions about tides. The goal is to capture student's interest before spending subsequent class time developing a conceptual/theoretical model of how tides work.

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In this unit, students explore the role of ocean circulation in climate modification and bioproductivity. The activities require students to interpret the effect of horizontal and vertical seawater movement on heat distribution, carbon dioxide dissolution, and nutrient availability. Students will use their new knowledge to predict how those parameters may change as a result of major shifts in ocean circulation associated with global climate change.

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Students will be provided with seawater pH and carbon dioxide concentration (pCO2) data spanning as far back as 1850. They will describe trends in pH, pCO2 and atmospheric CO2 concentration, outline why these parameters are related, and predict how changes in these parameters will affect marine biology. Each group of students will be given a different set of data from different regions and asked to compare with other groups to determine if seawater pH change is a global or regional phenomena. This unit will provide students with an understanding of the pH buffering system and an opportunity to interpret real climate data.

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Students will be able to identify the functional roles that organisms play in ocean ecosystems. How do human-induced changes in ocean conditions affect biodiversity, and thereby the health and resilience of a coral reef? Students explore and discuss the direct and indirect impacts that ocean acidification can have on species, food web dynamics, ecosystem function, and commercial resources. At the end of this unit the students should be able to articulate how changes in ocean chemistry can create negative outcomes for humans who depend on living ocean resources.

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Students will read and summarize an article that details scientific studies on behavioral changes of gray whales. Discussed are their feeding behavior, migratory behavior, and breeding patterns in the Pacific. Students will examine the whales' responses and discuss in small groups how the responses relate to climate change. By interpreting potential links between gray whale behavior and changed ocean conditions, students will be able to infer the ecological role that gray whales play within a community and an ecosystem. Students will summarize the main concepts, scientific evidence, data and observations cited, and justify why gray whales can be considered "ecosystem sentinels."

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Students will review current ocean pressures related to overfishing and human impacts on ocean ecosystems. By examining data collected in relation to the presence of marine reserves, students will explore long-term strategies for protecting ocean resources. Students will review scientific data to assess biomass, biodiversity, and reproductive success of fishery stocks in a marine protected area (MPA) and propose a location for the establishment of a marine reserve in the Channel Islands, California.

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Students are introduced to the concept of geoengineering, "the deliberate large-scale intervention in the Earth's climate system, in order to moderate global warming" (The Royal Society). The goal is for them to leverage their acquired knowledge from previous units in physical oceanography, ocean chemistry, biodiversity, and ecosystem ecology to evaluate the validity and/or the risk of geoengineering (systems thinking). Current and future generations will be required to make informed decisions on whether they support strategies that result in irreversible changes in Earth's carbon cycle.

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In this activity, students examine a pair of satellite images of the ocean and determine whether there is a relationship between the height of ocean waves and the sea level. Data from the two images are plotted side by side and students discuss the reasons for their findings. The resource includes the images and a student worksheet. Summary background information, data and images supporting the activity are available on the Earth Update data site. To complete the activity, students will need to access the Space Update multimedia collection, which is available for download and purchase for use in the classroom.

This 8-page assignment on the topic of ocean tides is intended to be completed by students alone or in small groups during class (with the possible exception of the last page which requires access to the internet) with the instructor available for help or assistance. It begins by introducing relevant vocabulary and leads students through examples of different tidal patterns. Instructors should make sure that the students have answered these first four pages correctly before moving on to the more challenging scenarios in which students are asked to analyze and make interpretations.

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This lab uses Google Earth to measure the rate of seacliff retreat. It touches upon coastal processes, natural hazards, and coastal management issues. The central focus of the lab is in the Monterey Bay area.

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Physical demonstrations of physical processes are a key component of most geoscience courses and serve to help deepen student understanding of complex processes. How does one do this for online courses? I filmed all of my oceanography demos at my school's Educational TV studio. I created them in two parts (what I call "predictive demos"), where students get to observe the setup in Part 1, then they have to predict what happens next before they see Part 2 of the ocean demo video. I perform the actual demonstrations live in my face-to-face classes, but the predictive part works best in an online, asynchronous setting.

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.

About every two weeks I ask each student in my introductory course to
write brief responses to questions I pose to them. They write these in
an e-Journal, a part of the blog function of BlackBoard. My laboratory
instructor and I use their responses to learn about the background and
interests of students in the class, to assess how well they are
learning, to determine if group work is going well, and to give us
ideas for improving the course.

The following two eJournal question sets are part of a course, Marine Environmental
Geology, a non-majors science course that has a significant service
learning component. The semester long service learning projects that
accompany this course require constant monitoring.

Assessing Service Learning Project Work The set of questions just below
is designed to have students think outside the group context about what
concrete steps need to be done to finish the work of their service
learning project. We read these and respond very quickly, supporting
good ideas. During the following week we encourage each group to come
together and share what they have written in Part 1. Writing their
thoughts down and having them supported by faculty helps some students
who normally don't express their ideas in a group to try out their
ideas with their peers.

The second question asks the student to reflect upon their own work and
work effort and helps us learn if there are any potential problems
within groups.

This week's e-journal is a follow-up to the presentations & lab we
did this week. The first part, goals & help needed, should be
written as a bulleted list with concrete objectives. The second part
should be answered in brief paragraph format.

The data collection phase of the projects is complete, or for some
groups, almost complete. While project work will carry on independently
through the end of the semester, we only have one more week in lab
devoted to it.

Part 1

After reviewing where you stood at the time of your presentation and
what you accomplished in lab this week, what do you intend to do with
the remaining lab period? What analyses do you hope to complete before
you present your results to the class in November? What help do you
need to meet these objectives?

Part 2

How do you feel about your project at this point? What do you feel you
did well? Are there any places you think you could have done better,
either personally or as a team?

Assessing Mastery of Content and Concepts

Last year I used this question to learn what specific problems students
were having with course material before an exam. By asking them to use
"use textbook vocabulary and to use it precisely" I am forcing them to
dig into material and be very specific about what they don't
understand. Sometimes students will write a very careful paragraph and
at the end say, "I understand it now." That doesn't always happen, so
for the most part I see what gets voted for most frequently and weave
that into the next lecture.

Critical Concepts Question

Thus far I have covered topics in my lectures which depend on the
following Critical Concepts sections in your textbook

CC1 Density

CC4 Particle size/sinking

CC6 Salinity, temp, etc

Read through these sections and write about the one that you had the
greatest difficulty understanding. Be specific about what you don't
understand. Be very careful to use textbook vocabulary and to use it
precisely. Write no more than three paragraphs

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In this lab activity students use the pH scale and the reaction of carbon dioxide with water to understand ocean acidification and make predictions regarding the effect of ocean acidification on marine organisms by experimentally determining the effect of pH of calcite dissolution.

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While most fish are completely harmless to people, there are some species that are mildly to extremely venomous and can actually kill humans. In this video, Jonathan travels the world to meet some of the most venomous fish in the sea. Please see the accompanying study guide for educational objectives and discussion points.

This YouTube playlist contains the video recordings of the lectures presented by scientists at the Ocean Acidification workshop on July 11th, 2012. Playlist also contains a variety of other related videos that can be used as teaching tools and/or resources.

A primary objective of marine science classes is to learn the location and formation of ocean sediment types. Nearly 50 years of scientific ocean drilling has produced a tremendous scientific collection of cores from the global ocean floor. In addition, there are large online databases and related publications that have a wealth of associated information to supplement physical cores. Here we created a virtual marine core collection that provides exemplars of the primary ocean sediment lithologies, along with links to expedition reports and datasets, and tips for making requests for real core samples to use in education.

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Interactive online tutorial about growing urchin larvae in a lab setting. Students manipulate data and are led through a lab-based situation. There is a module on ocean acidification. Lesson plans can be downloaded from website.

This visualization is a series of three short animations/videos that illustrate how the changing ice sheets result in sea level rise. It uses satellite data to show how Greenland and Antarctica are losing mass at a rate of 283 gigatons per year and 145 gigatons per year, respectively. Simulation shows visualization of one gigaton and how much this translates to sea level rise.

This game is suitable for play both within and outside of the classroom, and although designed for children ages 9-13, it offers a fun, learning opportunity for the entire family. In addition to being a game, it is an eye-catching poster showing continents, oceans and all of the major ocean currents. On the reverse, there are black and white educational activities designed to be reproduced directly from the poster for use in the classroom.