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Chemistry [clear]
| Title | Offering | Standing | Credits | Credits | When | F | W | S | Su | Description | Preparatory | Faculty | Days | Multiple Standings | Start Quarters | Open Quarters | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
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Paula Schofield and Andrew Brabban
Signature Required:
Spring
|
Program | SO–SRSophomore–Senior | 16 | 16 | Day | S 14Spring | The aim of this program is to apply fundamental knowledge and theories of biology and chemistry to practical, real world situations. The application of biology and chemistry has huge impacts on our society, particularly influencing our economy and quality of life. Cutting edge techniques and processes are continually being developed by biologists and chemists to produce the medicines, chemicals and materials we use daily. Products include pharmaceuticals—from synthetic drugs to gene therapies—used to prevent disease and cure illness; biocompatible materials for use in the medical field; fossil-fuel derived synthetic polymers (plastics, fibers, rubbers, etc.); and modern "green" or "sustainable" materials that include biodegradable polymers. These products are widely used by the general public, as well as in a wide array of industries and professions: agriculture, sports, health-care, law enforcement, the military, automotive, food, etc.We will focus on the practical applications of modern biology and chemistry, studying both small and large molecules, natural and synthetic. Based significantly in the laboratory, students will learn the theoretical principles and relevant lab and instrumentation techniques needed to synthesize, isolate and analyze small molecules and macromolecules. We will examine small biological molecules as well as organic molecules, moving to important biological macromolecules (DNA, RNA, proteins) and synthetic polymers (plastics, fibers, biodegradable polymers, green materials). Theory and techniques of molecular cloning, protein biochemistry, biocatalysis and transgenics will be emphasized, as well as synthesis and characterization of relevant organic molecules, polymers and green materials. Seminars on technical literature and student presentations will be significant components of the program. We will also discuss the professional biologist's and chemist's relationship with industry, government and universities, and examine employment opportunities for biologists and chemists. Students will be evaluated based on their laboratory techniques, laboratory reports, class presentations and homework assignments. | Paula Schofield Andrew Brabban | Sophomore SO Junior JR Senior SR | Spring | Spring | ||||||
|
Rebecca Sunderman
Signature Required:
Winter Spring
|
Program | SO–SRSophomore–Senior | 16 | 16 | Day | F 13 Fall | W 14Winter | S 14Spring | In previous chemistry work, you learned what the atomic orbital shapes were. In this program, you will explore how we know their shape. In previous chemistry work, you learned what a conductor was. In this program, you will examine the solid-state structural characteristics that indicate a material is a potential conductor. You will explore the "But why?" of chemistry by examining topics in thermodynamics, quantum mechanics, kinetics and materials chemistry. Many of the topics require a strong mathematical foundation and comfort with calculus applications.In the lecture component, faculty will present the laws of thermodynamics, enthalpy, entropy, chemical potential, phase diagrams, Gibbs free energy, reaction spontaneity, solid-state structure, solid-state bonding theories, point group symmetry, applications of symmetry, transition metal complexes, materials synthesis, Maxwell relations, the Schrodinger equation, atomic and molecular energy levels, electronic structure of atoms and molecules, unimolecular kinetics, biomolecular kinetics and current kinetic theories.During fall quarter, students will participate in physical chemistry and materials chemistry laboratory experiments. The laboratory component in the winter will train students to use and to explain the theory of several instruments for chemical analysis. In the spring, students will focus on enhancing skills in experimental design and research methods with the incorporation of team research projects surrounding a historical experiment in chemistry. In addition, emphasis will be placed on the development of technical writing skills and on interpretation and integration of issues pertaining to chemistry and society. | Rebecca Sunderman | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||||
|
Allen Mauney
|
Program | FR–SRFreshmen–Senior | 8 | 08 | Day | Su 14 Session II Summer | This program focuses on integral and multi-variable calculus. The definite integral will be motivated by calculating areas and defined in terms of limits. The connection between differential and integral calculus will be made via the FTC. All basic techniques of integration will be studied with emphasis on using definite integrals to answer questions from geometry and physics. Polar and parametric functions and series will be briefly covered. Vectors, gradients, and multiple integrals will be the focus of the second half of the class. There is a significant online component to the class. Calc 1 is required. | Allen Mauney | Mon Tue Wed Thu | Freshmen FR Sophomore SO Junior JR Senior SR | Summer | Summer | |||||
|
Dharshi Bopegedera and Abir Biswas
Signature Required:
Winter
|
Program | FR–SRFreshmen–Senior | 16 | 16 | Day | F 13 Fall | W 14Winter | This interdisciplinary, introductory-level program will explore topics in physical geology and general chemistry. It is designed for students with a desire to have a broader and deeper understanding of the Earth, the structure of matter that makes up the Earth, and their interconnectedness. The study of lab and field sciences through rigorous, quantitative, and interdisciplinary investigations will be emphasized throughout the program. We expect students to finish the program with a strong understanding of the scientific and mathematical concepts that help us investigate the world around us.In the fall quarter we will study fundamental concepts in Earth science such as geologic time, plate tectonics, and earth materials supported by explorations into the atomic structure and bonding. We will focus on skill building in the laboratory with the goal of doing meaningful field and lab work later in the year. Winter quarter will focus on Earth processes such as nutrient cycling and climate change supported by the study of stoichiometry, chemical equilibria, acid-base chemistry, and kinetics. Quantitative reasoning and statistical analysis of data will be emphasized throughout the program and students will participate in weekly geology and chemistry content-based workshops focusing on improving mathematical skills. Opportunities will be available for field work and to explore topics of interest through individual and group projects. | Dharshi Bopegedera Abir Biswas | Freshmen FR Sophomore SO Junior JR Senior SR | Fall | Fall Winter | |||||
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Dharshi Bopegedera and Susan Aurand
|
Program | FR–SOFreshmen–Sophomore | 16 | 16 | Day | S 14Spring | In this program, we will explore how artistic and scientific inquiries can lead to a better understanding of ceramics, a material that has been in human use since antiquity. We will study the principles of chemistry that will enable us to understand the properties of ceramics, which is an exceptional medium for creative expression. In the studio, students will learn basic hand-building techniques and gain an introduction to slips, stains, glazes and the firing process. We will also explore the basics of the chemistry of clay bodies, glaze formation and reduction versus oxidation firing. Program activities will include lectures, workshops, seminars, studios and labs. We expect everyone to create original artworks in ceramics and participate in lab experiences that will enrich their understanding of this material that has evolved with human history. No prior ceramics or chemistry experience is necessary. | arts and sciences. | Dharshi Bopegedera Susan Aurand | Freshmen FR Sophomore SO | Spring | Spring | |||||
|
Rebecca Sunderman
|
Program | FR–SRFreshmen–Senior | 8 | 08 | Day | Su 14 Session I Summer | We will begin the study of general chemistry by exploring the structure of the atom and the nature of the chemical bond and then proceed towards an understanding of molecular geometry. This will lead us to discussions of the periodic table, chemical reactions, stoichiometry, and properties of gases. Issues of chemistry and society will also be discussed and incorporated. In the laboratory we will work to develop the skills needed to be successful in a chemistry lab. In particular we will focus on measurements, solutions, and possibly some spectroscopy. This is part one of a two course sequence, that together cover one year of general chemistry with lab. | Rebecca Sunderman | Mon Tue Wed Thu Fri | Freshmen FR Sophomore SO Junior JR Senior SR | Summer | Summer | |||||
|
Hilary Palevsky
|
Program | FR–SRFreshmen–Senior | 8 | 08 | Day | Su 14 Session II Summer | This course is designed to offer the equivalent of the second half of a year-long course in general chemistry. The topics to be presented will include thermochemistry, properties and physical changes of matter, solution chemistry, kinetics, thermodynamics, chemical equilibrium, acid-base chemistry, and aqueous equilibria. Additional topics in electrochemistry, nuclear chemistry, and coordination chemistry may be presented if time permits. Course activities will include lectures, small-group problem-solving workshops, and laboratories. Laboratory work will build upon the skills learned in General Chemistry I, and provide hands-on experience with additional methods relevant to the topics presented in lecture. This is part two of a two course sequence, that together cover one year of general chemistry with lab. | Hilary Palevsky | Mon Tue Wed Thu Fri | Freshmen FR Sophomore SO Junior JR Senior SR | Summer | Summer | |||||
|
Tapas Das
|
Course | FR–SRFreshmen–Senior | 6 | 06 | Evening | F 13 Fall | W 14Winter | S 14Spring | Chemistry is the foundation for everything around us and relates to everything we do. These courses provide the fundamental principles of general chemistry. They also provide the prerequisites for advanced chemistry offerings as well as various studies: science, liberal arts, health, agriculture, engineering, and medicine. These courses include a mandatory laboratory component as an integral part of the course. This is the first course in a year-long general chemistry sequence. Topics covered in fall quarter include unit conversions, electron structures, and chemical bonding. Laboratory experiments will be carried out to complement the course materials. General Chemistry II builds upon material covered in General Chemistry I. Topics covered in winter quarter include thermochemistry, chemical kinetics, chemical equilibria, and acid-base equilibria. Course has a mandatory laboratory component. | Tapas Das | Mon Wed | Freshmen FR Sophomore SO Junior JR Senior SR | Fall | Fall Winter | |||
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James Neitzel, Mario Gadea and Kristopher Waynant
|
Program | FR–SRFreshmen–Senior | 12, 16 | 12 16 | Day | F 13 Fall | W 14Winter | S 14Spring | This introductory-level program is designed for students who are prepared to take their first year of college-level science using an interdisciplinary framework. This program offers an integrated study of biology, chemistry, and physics that serves as an introduction to the concepts, theories and structures which underlie all the natural sciences. Our goal is to equip students with the conceptual, methodological and quantitative tools that they will need to ask and answer questions that arise in a variety of disciplines using the models and tools of chemistry, biology, and physics. . Students will also gain a strong appreciation of the interconnectedness of biological and physical systems, and an ability to apply this knowledge to complex problemProgram activities will include lectures and small-group problem-solving workshops, where conceptual and technical skills will be developed. There will be a significant laboratory component--students can expect to spend at least a full day in lab each week, maintain laboratory notebooks, write formal laboratory reports and give formal presentations of their work. Biology laboratories in this program will include participation in the SEA-PHAGE program coordinated by the Howard Hughes Medical Institute and the use of bioinformatics tools on a bacteriophage genome. We will make extensive use of mathematical modeling in all program activities.Seminar will enable us to apply our growing understanding of scientific principles and methodology to societal issues such as genetic testing and engineering or the causes and effects of climate change. In addition to studying current scientific theories, we will consider the historical, societal and personal factors that influence our thinking about the natural world. Students will be exposed to the primary literature of these sciences and develop skill in writing for diverse audiences. During spring quarter, students will have the opportunity to design and carry out their own laboratory investigations, the results of which they will present in talks and papers at the end of the quarter.All laboratory work and approximately one half of the non-lecture time will be spent working in collaborative problem-solving groups. It will be a rigorous program, requiring a serious commitment of time and effort. Overall, we expect students to end the program in the spring with a solid working knowledge of scientific and mathematical concepts, and with the ability to reason critically and solve problems.Students completing this program will have covered material equivalent to one year of general biology and general chemistry, with a significant amount of physics. | James Neitzel Mario Gadea Kristopher Waynant | Freshmen FR Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||||
|
Clyde Barlow and Neil Switz
Signature Required:
Winter Spring
|
Program | FR–SRFreshmen–Senior | 16 | 16 | Day | F 13 Fall | W 14Winter | S 14Spring | Modern science has been remarkably successful in providing understanding of how natural systems behave. Such disparate phenomena as the workings of cell-phones, the ways in which we detect supermassive black holes in the galactic core, the use of magnetic resonance imaging in the diagnosis of disease, the effects of global carbon dioxide levels on shellfish growth, and the design of batteries for electric cars are all linked at a deeply fundamental level. This program will introduce you to the theory and practice of the science behind these and other phenomena, while providing the solid academic background in mathematics, chemistry, and physics necessary for advanced study in those fields as well as for engineering, medicine, and biology.We will integrate material from first-year university physics, chemistry, and calculus with relevant areas of history and scientific literature. The program will have a strong laboratory focus using computer-based experimental control and analysis to explore the nature of chemical and physical systems; this work will take place in a highly collaborative environment. Seminars will provide the opportunity to explore the connections between theory and practice and will provide opportunities to enhance technical writing and communication skills. The program is intended for students with solid high-school level backgrounds in science and mathematics, but the key to succeeding will be a commitment to work, learn, and collaborate. | Clyde Barlow Neil Switz | Freshmen FR Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||||
|
Lydia McKinstry and Clarissa Dirks
Signature Required:
Fall Winter Spring
|
Program | SO–SRSophomore–Senior | 16 | 16 | Day | F 13 Fall | W 14Winter | S 14Spring | This program develops and interrelates concepts in experimental (laboratory and field) biology, organic chemistry and biochemistry, thus providing a foundation for students who plan to continue studies in chemistry, laboratory and field biology and medicine. Students will carry out upper-division work in biochemistry, microbiology, cellular and molecular biology, field biology and organic chemistry in a yearlong sequence. This program will also give students many of the prerequisites needed for the following health careers: medicine, dentistry, veterinary medicine, naturopathy, optometry and pharmacy.The program examines the subject matter through the central idea that structure defines function, integrating a scaled theme from the "cell" to the "molecule" and "ecosystem" levels. We will start with the cell and proceed to the whole organism and ecosystem with the examination of structure-function relationships at all levels. We will examine organic chemistry, the nature of organic compounds and reactions and carry this work into biochemistry and the fundamental chemical reactions of living systems. As the year progresses, the scaled theme will continue through studies of cellular and molecular processes in biological systems.Each aspect of the program will contain a significant laboratory component, some of which may be based on field experiments, involving extensive hands-on learning. On a weekly basis, students will be writing papers and maintaining laboratory notebooks. All laboratory work, and approximately one half of the non-lecture time will be spent working in collaborative problem solving groups. Group work will also include reading and discussion of topics of current or historical significance in science. This is an intensive program; the subjects are complex, and the sophisticated understanding we expect to develop will require students to work for many hours each week, both in and out of class. | laboratory and field biology, chemistry, education, medicine and health science. | Lydia McKinstry Clarissa Dirks | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | |||
|
Carolyn Prouty, Trisha Vickrey and Wenhong Wang
Signature Required:
Winter Spring
|
Program | SO–SRSophomore–Senior | 16 | 16 | Day | F 13 Fall | W 14Winter | S 14Spring | This introductory, three-quarter interdisciplinary program explores the basics of health and illness through the lenses of biology, chemistry and medical sociology. We will focus on the social, cultural and scientific aspects of human health and health care primarily in the U.S., with some comparative examination of global health topics. Our case-based approach will incorporate human biology, anatomy, physiology, nutrition, general chemistry and statistics, while also examining the social aspects of health, illness, and health care.Enhancing our study of human systems biology and chemistry, we will examine topics such as epilepsy, cancer, diabetes, tobacco, and HIV/AIDS, how cultures interact with medical systems, and end-of-life decision-making. These specific topics will provide a platform to explore health care systems and health care reform, social and cultural constructions of health and illness, the social determinants of health, role development of health care professionals and their relationships with patients, and ethical issues involved in medical fields. We’ll also cover basic descriptive and inferential statistics, which will give us quantitative tools to untangle some of the complex issues within these topics.Program activities will include lectures, seminar, lab work, workshops, small-group problem solving, guest lectures, film viewing, and individual and group projects. Students will undertake writing, and statistical assignments focused on interpreting and integrating the topics covered. Students will learn the foundational skills of scientific research; how to find, interpret, and evaluate primary medical literature; and how to critically examine issues related to human health through a variety of lenses.Students who complete three quarters will have a solid foundation in human biology, chemistry, human anatomy, physiology, nutrition, statistics, and medical sociology with a working knowledge of the scientific, social and ethical principles relating to human health and public health. | Carolyn Prouty Trisha Vickrey Wenhong Wang | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||||
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Paula Schofield and Andrew Brabban
|
Program | FR ONLYFreshmen Only | 16 | 16 | Day | F 13 Fall | W 14Winter | Are you curious about the world around you? Would you like to really understand "buzz terms" the media uses such as sustainability, green materials, climate change, the water crisis, the energy debate, genetic engineering, DNA fingerprinting and cloning? How can we believe what we are being told? What is the evidence? How is scientific data actually collected, and what analytical methods are being used? Are the correct conclusions being drawn? As responsible citizens we should know the answers to these questions.In this two-quarter program we will demystify the hype surrounding popular myths, critically examine the data, and use scientific reasoning and experimental design to come to our own conclusions. In fall, we will study "water" and "energy" as themes to examine our environment, considering local and global water issues. We will also examine current energy use and demand, critically assessing various sources of energy: fossil fuels, nuclear, hydropower, etc.We will begin the program on September 23 (Orientation Week), one week BEFORE the regularly scheduled fall quarter start, so that we are prepared for our field trip by beginning our study of energy, and establishing our learning community. The Eastern Washington field trip will be a unique opportunity for personalized tours of Hanford Reactor B (the world's first full-scale nuclear reactor which produced the plutonium for the "Fat Man" bomb dropped over Nagasaki in 1945), Grand Coulee Dam (the largest hydropower producer in the U.S.), and the Wild Horse Wind and Solar Energy facility (150 turbines across 10,000 acres serving more than 80,000 homes). On this trip, we will also learn key field science techniques: how to take measurements in the field, collect samples for laboratory analysis and precisely determine concentrations of nutrients and pollutants.In winter quarter, we will use "natural and synthetic materials" as a theme to study petrochemical plastics, biodegradable plastics and other sustainable materials, as well as key biological materials such as proteins and DNA. We will carefully examine the properties of these materials in the laboratory and study their role in the real world. "Forensics" will be our final theme, learning techniques such as DNA fingerprinting, blood spatter analysis, ballistics and other modern forensic procedures.In this field- and lab-based program, scientific analysis—rather than conjecture or gut-feeling—will be the foundation of our work. Other class activities will include small group problem-solving workshops, seminars, student researched presentations and lectures. | Paula Schofield Andrew Brabban | Freshmen FR | Fall | Fall Winter | |||||
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Hansina Hill
|
SOS | FR–SRFreshmen–Senior | 6 | 06 | Evening | S 14Spring | and will include selected topics in thermodynamics, kinetics, nuclear chemistry, and some introductory organic. | Hansina Hill | Mon Wed | Freshmen FR Sophomore SO Junior JR Senior SR | Spring | Spring | |||||
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Dylan Fischer and Paul Przybylowicz
|
Program | JR–SRJunior–Senior | 16 | 16 | Day | F 13 Fall | W 14Winter | The Pacific Northwest is home to temperate rainforests, among the most biologically complex ecosystems in the world. How did these forests develop? How do they function? How do human activities affect them? Is sustainable harvest a reality or an oxymoron? We will use a biogeochemical lens to examine these forests, their effects on us and our impacts on them. Topics covered will include forest ecology, ecosystem ecology, soils, mycology, biogeochemistry, sustainable forestry and forest conservation.In fall quarter, we will explore how forests “work” through studying forest ecosystem science that includes both global and regional perspectives, with a focus on carbon and nutrient cycling. We will also examine the tremendous fungal biodiversity found within temperate rainforests, particularly the local forests of the Pacific Northwest. We’ll cover methods in forest biogeochemical measurement, fungal biology, taxonomy and advanced forest ecology.Human impacts on temperate rainforests will be the focus of winter quarter. We’ll focus on sustainable forestry, both theory and practice, along with an examination of soils and the life within them, which will deepen our understanding of forest function and the short- and long-term impacts of various forestry practices. These topics will merge as we explore carbon sequestration in forest ecosystems, which is an emerging component of “sustainable” forestry. We will explore current and past controversies in forest ecology related to old-growth forests, spotted owls and other endangered species and biofuels.Our program time will consist of field work, laboratory work, lectures, workshops and weekly seminars. Expect to research topics in the primary scientific literature and to summarize and share your findings with the entire class. We’ll cover various sampling techniques that are used to measure nitrogen, water and carbon in forested ecosystems. There will be ample opportunities for independent directed work, both individually and in small groups.In addition to one-day trips regularly scheduled throughout both quarters, there will be a 4-day field trip each quarter. In the fall, we’ll spend four days doing field research in temperate rainforests. In the winter, we’ll tour through the Pacific Northwest and visit a variety of managed and unmanaged forests. Plan to spend a lot of time in the field (and remember that every field day generates 3-4 days of work once we return). Students who may need accommodations for field trips should contact the faculty as soon as possible. | Dylan Fischer Paul Przybylowicz | Junior JR Senior SR | Fall | Fall Winter | |||||
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Paula Schofield, Neil Switz, David McAvity, Andrew Brabban, Brian Walter, Richard Weiss, Abir Biswas, Michael Paros, Clyde Barlow, Judith Cushing, Dharshi Bopegedera, Rebecca Sunderman, EJ Zita, Donald Morisato, Clarissa Dirks, James Neitzel, Sheryl Shulman, Neal Nelson and Lydia McKinstry
Signature Required:
Fall Winter Spring
|
Program | SO–SRSophomore–Senior | V | V | Day | F 13 Fall | W 14Winter | S 14Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. These are valuable skills for students pursuing a graduate degree or entering the job market.Faculty offering undergraduate research opportunities are listed below. Contact them directly if you are interested. (chemistry) works with biophysical applications of spectroscopy to study physiological processes at the organ level, with direct applications to health problems. Students with backgrounds in biology, chemistry, physics, mathematics or computer science can obtain practical experience in applying their backgrounds to biomedical research problems in an interdisciplinary laboratory environment.. (geology, earth science) studies nutrient and toxic trace metal cycles in terrestrial and coastal ecosystems. Potential projects could include studies of mineral weathering, wildfires and mercury cycling in ecosystems. Students could pursue these interests at the laboratory-scale or through field-scale biogeochemistry studies taking advantage of the Evergreen Ecological Observation Network (EEON), a long-term ecological study area. Students with backgrounds in a combination of geology, biology or chemistry could gain skills in soil, vegetation and water collection and learn methods of sample preparation and analysis for major and trace elements. (biotechnology) studies the physiology and biochemistry of prokaryotes of industrial and agricultural importance. Students who commit at least a full year to a research project, enrolling for 4 to 16 credits each quarter, will learn a broad range of microbiology (both aerobic and anaerobic techniques), molecular (DNA analysis and cloning), and biochemical techniques (chemical and pathway analysis, protein isolation). Students will also have opportunities for internships at the USDA and elsewhere, and to present data at national and international conferences. (chemistry) would like to engage students in two projects. (1) Quantitative determination of metals in the stalactites formed in aging concrete using ICP-MS. Students who are interested in learning about the ICP-MS technique and using it for quantitative analysis will find this project interesting. (2) Science and education. We will work with local teachers to develop lab activities that enhance the science curriculum in local schools. Students who have an interest in teaching science and who have completed general chemistry with laboratory would be ideal for this project. (computer science, ecology informatics) studies how scientists might better use information technology and visualization in their research, particularly in ecology and environmental studies. She would like to work with students who have a background in computer science or one of the sciences (e.g., ecology, biology, chemistry or physics), and who are motivated to explore how new computing paradigms can be harnessed to improve the individual and collaborative work of scientists. Such technologies include visualizations, plugins, object-oriented systems, new database technologies and "newer" languages that scientists themselves use such as python or R. (biology) aims to better understand the evolutionary principles that underlie the emergence, spread and containment of infectious disease by studying the coevolution of retroviruses and their primate hosts. Studying how host characteristics and ecological changes influence virus transmission in lemurs will enable us to address the complex spatial and temporal factors that impact emerging diseases. Students with a background in biology and chemistry will gain experience in molecular biology techniques, including tissue culture and the use of viral vectors. (organic chemistry) is interested in organic synthesis research, including asymmetric synthesis methodology, chemical reaction dynamics and small molecule synthesis. One specific study involves the design and synthesis of enzyme inhibitor molecules to be used as effective laboratory tools with which to study the mechanistic steps of programmed cell death (e.g., in cancer cells). Students with a background in organic chemistry and biology will gain experience with the laboratory techniques of organic synthesis as well as the techniques of spectroscopy. (biology) is interested in the developmental biology of the embryo, a model system for analyzing how patterning occurs. Maternally encoded signaling pathways establish the anterior-posterior and dorsal-ventral axes. Individual student projects will use a combination of genetic, molecular biological and biochemical approaches to investigate the spatial regulation of this complex process. (biochemistry) uses methods from organic and analytical chemistry to study biologically interesting molecules. A major focus of his current work is on fatty acids; in particular, finding spectroscopic and chromatographic methods to identify fatty acids in complex mixtures and to detect changes that occur in fats during processing or storage. This has relevance both for foods and in biodiesel production. The other major area of interest is in plant natural products, such as salicylates. Work is in process screening local plants for the presence of these molecules, which are important plant defense signals. Work is also supported in determining the nutritional value of indigenous plants. Students with a background and interest in organic, analytical or biochemistry could contribute to this work. (computer science) and (computer science) are interested in working with advanced computer topics and current problems in the application of computing to the sciences. Their areas of interest include simulations of advanced architectures for distributed computing, advanced programming languages and compilers, programming languages for concurrent and parallel computing and hardware modeling languages. (biology, veterinary medicine) is interested in animal health and diseases that affect the animal agriculture industry. Currently funded research includes the development of bacteriophage therapy for dairy cattle uterine infections, calf salmonellosis and mastitis. A number of hands-on laboratory projects are available to students interested in pursuing careers in science. (organic, polymer, materials chemistry) is interested in the interdisciplinary fields of biodegradable plastics and biomedical polymers. Research in the field of biodegradable plastics is becoming increasingly important to replace current petroleum-derived materials and to reduce the environmental impact of plastic wastes. Modification of starch through copolymerization and use of bacterial polyesters show promise in this endeavor. Specific projects within biomedical polymers involve the synthesis of poly (lactic acid) copolymers that have potential for use in tissue engineering. Students with a background in chemistry and biology will gain experience in the synthesis and characterization of these novel polymer materials. Students will present their work at American Chemical Society (ACS) conferences. (computer science) is interested in working with advanced computer topics and current problems in the application of computing to the sciences. Her areas of interest include simulations of advanced architectures for distributed computing, advanced programming languages and compilers, programming languages for concurrent and parallel computing, and hardware modeling languages. (inorganic/materials chemistry, physical chemistry) is interested in the synthesis and property characterization of new bismuth-containing materials. These compounds have been characterized as electronic conductors, attractive activators for luminescent materials, second harmonic generators and oxidation catalysts for several organic compounds. Traditional solid-state synthesis methods will be utilized to prepare new complex bismuth oxides. Once synthesized, powder x-ray diffraction patterns will be obtained and material properties such as conductivity, melting point, biocidal tendency, coherent light production and magnetic behavior will be examined when appropriate. (mathematics) is interested in problems relating to graphs, combinatorial games and especially combinatorial games played on graphs. He would like to work with students who have a strong background in mathematics and/or computer science and who are interested in applying their skills to open-ended problems relating to graphs and/or games. (computer science, mathematics) has several ongoing projects in computer vision, robotics and security. There are some opportunities for students to develop cybersecurity games for teaching network security concepts and skills. In robotics, he is looking for students to develop laboratory exercises for several different mobile robotic platforms, including Scribbler, LEGO NXT and iRobot Create. This would also involve writing tools for image processing and computer vision using sequences of still images, video streams and 2.5-D images from the Kinect. In addition, he is open to working with students who have their own ideas for projects in these and related areas, such as machine learning, artificial intelligence and analysis of processor performance. (physics) studies the Sun and the Earth. What are the mechanisms of global warming? What can we expect in the future? What can we do about it right now? How do solar changes affect Earth over decades (e.g., Solar Max) to millennia? Why does the Sun shine a bit more brightly when it is more magnetically active, even though sunspots are dark? Why does the Sun's magnetic field flip every 11 years? Why is the temperature of the Sun’s outer atmosphere millions of degrees higher than that of its surface? Students can do research related to global warming in Zita's academic programs and in contracts, and have investigated the Sun by analyzing data from solar observatories and using theory and computer modeling. Serious students are encouraged to form research contracts and may thereafter be invited to join our research team. Please go to the catalog view for specific information about each option. | Paula Schofield Neil Switz David McAvity Andrew Brabban Brian Walter Richard Weiss Abir Biswas Michael Paros Clyde Barlow Judith Cushing Dharshi Bopegedera Rebecca Sunderman EJ Zita Donald Morisato Clarissa Dirks James Neitzel Sheryl Shulman Neal Nelson Lydia McKinstry | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||||
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Clyde Barlow
Signature Required:
Fall Winter Spring
|
Research | SO–SRSophomore–Senior | V | V | Day | F 13 Fall | W 14Winter | S 14Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. These are valuable skills for students pursuing a graduate degree or entering the job market. (chemistry) works with biophysical applications of spectroscopy to study physiological processes at the organ level, with direct applications to health problems. Students with backgrounds in biology, chemistry, physics, mathematics or computer science can obtain practical experience in applying their backgrounds to biomedical research problems in an interdisciplinary laboratory environment. | Clyde Barlow | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||||
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Dharshi Bopegedera
Signature Required:
Fall Winter Spring
|
Research | SO–SRSophomore–Senior | V | V | Day | F 13 Fall | W 14Winter | S 14Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. These are valuable skills for students pursuing a graduate degree or entering the job market. (chemistry) would like to engage students in two projects. (1) Quantitative determination of metals in the stalactites formed in aging concrete using ICP-MS. Students who are interested in learning about the ICP-MS technique and using it for quantitative analysis will find this project interesting. (2) Science and education. We will work with local teachers to develop lab activities that enhance the science curriculum in local schools. Students who have an interest in teaching science and who have completed general chemistry with laboratory would be ideal for this project. | Dharshi Bopegedera | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||||
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Lydia McKinstry
Signature Required:
Fall Winter Spring
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Research | SO–SRSophomore–Senior | V | V | Day | F 13 Fall | W 14Winter | S 14Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. These are valuable skills for students pursuing a graduate degree or entering the job market. (organic chemistry) is interested in organic synthesis research, including asymmetric synthesis methodology, chemical reaction dynamics and small molecule synthesis. One specific study involves the design and synthesis of enzyme inhibitor molecules to be used as effective laboratory tools with which to study the mechanistic steps of programmed cell death (e.g., in cancer cells). Students with a background in organic chemistry and biology will gain experience with the laboratory techniques of organic synthesis as well as the techniques of spectroscopy. | chemistry, health sciences. | Lydia McKinstry | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | |||
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Neil Switz
Signature Required:
Fall Winter Spring
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Research | SO–SRSophomore–Senior | 6 | 06 | Day | F 13 Fall | W 14Winter | S 14Spring | Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. Laboratory experience is especially important – and useful – for students planning to pursue graduate studies or enter the technical job market. (physics) develops optical instruments for use in biophysical and biomedical applications, including low-cost diagnostics. Projects in the lab are suitable for motivated students with quantitative backgrounds in physics, biology, chemistry, mathematics or computer science. | Neil Switz | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||||
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Paula Schofield
Signature Required:
Fall Winter Spring
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Research | SO–SRSophomore–Senior | V | V | Day | F 13 Fall | W 14Winter | S 14Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. These are valuable skills for students pursuing a graduate degree or entering the job market. (organic, polymer, materials chemistry) is interested in the interdisciplinary fields of biodegradable plastics and biomedical polymers. Research in the field of biodegradable plastics is becoming increasingly important to replace current petroleum-derived materials and to reduce the environmental impact of plastic wastes. Modification of starch through copolymerization and use of bacterial polyesters show promise in this endeavor. Specific projects within biomedical polymers involve the synthesis of poly (lactic acid) copolymers that have potential for use in tissue engineering. Students with a background in chemistry and biology will gain experience in the synthesis and characterization of these novel polymer materials. Students will present their work at American Chemical Society (ACS) conferences. | Paula Schofield | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring | ||||
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Rebecca Sunderman
Signature Required:
Fall Winter Spring
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Research | SO–SRSophomore–Senior | V | V | Day | F 13 Fall | W 14Winter | S 14Spring | Rigorous quantitative and qualitative research is an important component of academic learning in Scientific Inquiry. Research opportunities allow science students to work on specific projects associated with faculty members’ expertise. Students typically begin by working in an apprenticeship model with faculty or laboratory staff and gradually take on more independent projects within the context of the specific research program as they gain experience. Students can develop vital skills in research design, data acquisition and interpretation, modeling and theoretical analysis, written and oral communication, collaboration and critical thinking. These are valuable skills for students pursuing a graduate degree or entering the job market. (inorganic/materials chemistry, physical chemistry) is interested in the synthesis and property characterization of new bismuth-containing materials. These compounds have been characterized as electronic conductors, attractive activators for luminescent materials, second harmonic generators and oxidation catalysts for several organic compounds. Traditional solid-state synthesis methods will be utilized to prepare new complex bismuth oxides. Once synthesized, powder x-ray diffraction patterns will be obtained and material properties such as conductivity, melting point, biocidal tendency, coherent light production and magnetic behavior will be examined when appropriate. | Rebecca Sunderman | Sophomore SO Junior JR Senior SR | Fall | Fall Winter Spring |
