This course will introduce students to the principles of remote sensing, characteristics of remote sensors, and remote sensing applications. Image acquisition, data collection in the electromagnetic spectrum, and data set manipulations for earth and environmental science applications will be emphasized. We will cover fundamental knowledge of the physics of remote sensing; aerial photographic techniques; multispectral, hyperperspectral, thermal, and other image analysis. Students will pursue an independent research project using remote sensing tools, and at the end of the semester should have a good understanding and the basic skills of remote sensing.
Evaluation of environmental contamination and liability is an important tool during acquisition of real estate property, and a standard work product in the environmental consulting field. This course will cover the purpose and history of the Superfund law, the various classifications of Superfund liable parties, and protections against Superfund liability, specifically with regard to bona fide prospective purchasers (BFPP). In the context of the BFPP liability defense the course will focus on the performance of “All Appropriate Inquiry” for the presence of environmental contamination (e.g. Phase I environmental site assessment). Our study of “All Appropriate Inquiry” will include evaluation of historical maps and other resources, aerial photography, chain-of-title documentation, and governmental database information pertaining to known contaminated sites in the area of select properties on or near campus. Site visits will be performed to gain experience and knowledge for the identification of recognized environmental conditions. Students will prepare environmental reports for select properties and will have an opportunity to hone technical writing skills.
This course covers the fundamentals of atmosphere and ocean dynamics, and aims to put these in the context of climate change in the 21st century. Large-scale atmospheric and oceanic circulation, the global energy balance, and the global energy balance, and the global hydrological cycle. We will introduce concepts of fluid dynamics and we will apply these to the vertical and horizontal motions in the atmosphere and ocean. Concepts covered include: hydrostatic law, buoyancy and convection, basic equations of fluid motions, Hadley and Ferrel cells in the atmosphere, thermohaline circulation, Sverdrup ocean flow, modes of climate variability (El-Nino, North Atlantic Oscillation, Southern Annular Mode). The course will incorporate student led discussions based on readings of the 2007 Intergovernmental Panel on Climate Change (IPCC) report and recent literature on climate change. Aimed at undergraduate or graduate students who have no prior knowledge of meteorology or oceanography or training in fluid mechanics. Previous background in calculus and/or introductory physics is helpful. This is a general course which spans many subdisciplines (fluid mechanics, atmospheric science, oceanography, hydrology).
The oceans cover over 2/3 of the Earth’s surface, but what do we know about them and how do they impact our climate and everyday life? We will examine climate change’s impacts on the oceans and how this in turn affects our daily lives from eating seafood to our weather patterns, to movement of goods across vast distances. Through frequent individual assignments using real-time data, readings, video lectures, and asynchronous discussions, students are exposed to the major areas of oceanography including plate tectonics, marine sediments, physical and chemical properties of seawater, ocean circulation, air-sea interactions, waves, tides, nutrient cycles in the ocean, and biology of the oceans through the lens of climate change and the consequent impacts on your daily life. The required text for this course is Essentials of Oceanography, 13th edition, by Alan P. Trujillo and Harold B. Thurman, which is available from a variety of online book retailers.
The oceans cover over 2/3 of the Earth’s surface, but what do we know about them and how do they impact our climate and everyday life? We will examine climate change’s impacts on the oceans and how this in turn affects our daily lives from eating seafood to our weather patterns, to movement of goods across vast distances. Through frequent individual assignments using real-time data, readings, video lectures, and asynchronous discussions, students are exposed to the major areas of oceanography including plate tectonics, marine sediments, physical and chemical properties of seawater, ocean circulation, air-sea interactions, waves, tides, nutrient cycles in the ocean, and biology of the oceans through the lens of climate change and the consequent impacts on your daily life. The required text for this course is Essentials of Oceanography, 13th edition, by Alan P. Trujillo and Harold B. Thurman, which is available from a variety of online book retailers.
The aim of this 10-day summer program is to introduce inquisitive students to the nature, culture, history and languages of the European Alps in Switzerland and Italy. We will be exploring the geology of the Alps and how it influences the development of wildlife, flora, history, religion, culture and of entire regions, how humans have altered the environment, and how humans respond to climate change in Alpine ecosystems. We will learn how to observe nature in a spectacular landscape, visit cultural sites off the beaten track and explore some of the well-known localities, such as Zurich, Valtellina, Bellinzona, and the Engadine.
Natural disasters play a fundamental role in shaping landscapes and structuring ecosystems. The purpose of this course is to introduce you to both the natural and social science of disasters. This course will explore the geologic processes that cause natural disasters, the ecological and social consequences of disasters, and the role of human behavior in disaster management and mitigation. Through exploring these concepts, this class will provide you with a broad background in the geosciences and the basic tools needed to understand: how earthquakes, volcanoes, landslides, and hurricanes occur; the myriad of ways that we can mitigate against their impacts; and the way in which we can “calculate the cost” of these disasters.
Processes of soil development in a variety of temperate environments. Effects of lithology and climate on soil properties. This is a field course with 5 required field days.
Microorganisms inhabit almost every conceivable environment on the planet’s surface, and extent the biosphere to depths of several kilometers into the crust. Significantly, the chemical reactivity and metabolic diversity displayed by microbial communities make them integral components of global elemental cycles, from mineral dissolution and precipitation reactions, to aqueous reduction-oxidation processes. In that regard, microorganisms have helped shape our planet overthe past 4 billion years and made it habitable for higher forms of life. In this course we will evaluate the geological consequences of microbial activities, by taking am interdisciplinary and “global” view of microbe-environment interactions.
All forms of frozen water at Earth’s surface define the cryosphere. These icy environmnets are an integral part of the global climate system, with important linkages and feedbacks resulting from their influences on surface energy and moisture fluxes, clouds, precipitation, hydrology, and circulation in the atmosphere and oceans. This course will survey the various components of the cryosphere and their interactions with climate, with a strong emphasis on the dynamics of glaciers and ice sheets. Broad topics to be covered are 1)the rudimentary mechanics of glacier and ice sheet flow, 2)fast-flowing ice streams and factors limiting their motion, 3)ice-quakes and their origins, 4)the nature of climate data recorded in natural ice bodies, 5)the influence of climate on the stability of ice sheets and glaciers, and 6)glacier-like flow on other planetary bodies. This will be a lecture-based course with written assignmnets and problems sets.