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courses/CHEM-4030.html
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CHEM-4030: Experimental Chemistry III Abridged: Physical Methods
</title>
<meta property="og:title" content="CHEM-4030: Experimental Chemistry III Abridged: Physical Methods">
<meta property="og:description" content="Laboratory exploration of physical methods used to characterize the structure and properties of compounds. Involves the experiments in CHEM 4020 that do not depend on the theoretical material of CHEM 4010 . Students can not get credit for both this course and CHEM 4020 .">
<meta property="og:description" content="Laboratory exploration of physical methods used to characterize the structure and properties of compounds. Involves the experiments in that do not depend on the theoretical material of . Students can not get credit for both this course and .">
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CHEM-4030
</h2>
<p>
Laboratory exploration of physical methods used to characterize the structure and properties of compounds. Involves the experiments in CHEM 4020 that do not depend on the theoretical material of CHEM 4010 . Students can not get credit for both this course and CHEM 4020 .
Laboratory exploration of physical methods used to characterize the structure and properties of compounds. Involves the experiments in that do not depend on the theoretical material of . Students can not get credit for both this course and .
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courses/CHEM-4110.html
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CHEM-4110: Instrumental Methods of Analysis
</title>
<meta property="og:title" content="CHEM-4110: Instrumental Methods of Analysis">
<meta property="og:description" content="This course will introduce advanced instrumental physicochemical methods of chemical analysis as well as instrument design and data capture/processing. Topics covered include atomic and molecular spectroscopy, chromatography, electroanalytical chemistry and measurement basics. This course is a prerequisite or corequisite for CHEM 4120 / CHEM 4130 .">
<meta property="og:description" content="This course will introduce advanced instrumental physicochemical methods of chemical analysis as well as instrument design and data capture/processing. Topics covered include atomic and molecular spectroscopy, chromatography, electroanalytical chemistry and measurement basics. This course is a prerequisite or corequisite for / .">
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CHEM-4110
</h2>
<p>
This course will introduce advanced instrumental physicochemical methods of chemical analysis as well as instrument design and data capture/processing. Topics covered include atomic and molecular spectroscopy, chromatography, electroanalytical chemistry and measurement basics. This course is a prerequisite or corequisite for CHEM 4120 / CHEM 4130 .
This course will introduce advanced instrumental physicochemical methods of chemical analysis as well as instrument design and data capture/processing. Topics covered include atomic and molecular spectroscopy, chromatography, electroanalytical chemistry and measurement basics. This course is a prerequisite or corequisite for / .
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courses/CHEM-4130.html
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CHEM-4130: Mass Spectrometry
</title>
<meta property="og:title" content="CHEM-4130: Mass Spectrometry">
<meta property="og:description" content="Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both CHEM 4130 and CHEM 6130 .">
<meta property="og:description" content="Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both CHEM 4130 and .">
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CHEM-4130
</h2>
<p>
Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both CHEM 4130 and CHEM 6130 .
Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both CHEM 4130 and .
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courses/CHEM-4140.html
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CHEM-4140: NMR Spectroscopy for Scientists and Engineers
</title>
<meta property="og:title" content="CHEM-4140: NMR Spectroscopy for Scientists and Engineers">
<meta property="og:description" content="This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and CHEM 6140 .">
<meta property="og:description" content="This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and .">
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CHEM-4140
</h2>
<p>
This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and CHEM 6140 .
This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and .
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courses/CHEM-4310.html
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CHEM-4310: Bioorganic Mechanisms
</title>
<meta property="og:title" content="CHEM-4310: Bioorganic Mechanisms">
<meta property="og:description" content="The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with CHEM 6310 ; both courses cannot be taken for credit.">
<meta property="og:description" content="The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with ; both courses cannot be taken for credit.">
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CHEM-4310
</h2>
<p>
The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with CHEM 6310 ; both courses cannot be taken for credit.
The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with ; both courses cannot be taken for credit.
</p>
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courses/CHEM-4330.html
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CHEM-4330: Drug Discovery
</title>
<meta property="og:title" content="CHEM-4330: Drug Discovery">
<meta property="og:description" content="This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and CHEM 6330 .">
<meta property="og:description" content="This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and .">
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<link rel="stylesheet" href="../css/coursedisplay.css">
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CHEM-4330
</h2>
<p>
This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and CHEM 6330 .
This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and .
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courses/CHEM-4530.html
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CHEM-4530: Modern Techniques in Chemistry
</title>
<meta property="og:title" content="CHEM-4530: Modern Techniques in Chemistry">
<meta property="og:description" content="A lecture/laboratory course for Chemical Engineering students. Topics include the principles of chemical equilibria and their relation to modern analytical methods and the basis of instrumental techniques for characterizing the chemical structures and properties of compounds. The course provides laboratory experience in the use of modern instruments along with other chemical techniques. Aspects of analytical, organic, and physical chemistry will be illustrated throughout the course. Students cannot get credit for both this course and CHEM 2110 .">
<meta property="og:description" content="A lecture/laboratory course for Chemical Engineering students. Topics include the principles of chemical equilibria and their relation to modern analytical methods and the basis of instrumental techniques for characterizing the chemical structures and properties of compounds. The course provides laboratory experience in the use of modern instruments along with other chemical techniques. Aspects of analytical, organic, and physical chemistry will be illustrated throughout the course. Students cannot get credit for both this course and .">
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CHEM-4530
</h2>
<p>
A lecture/laboratory course for Chemical Engineering students. Topics include the principles of chemical equilibria and their relation to modern analytical methods and the basis of instrumental techniques for characterizing the chemical structures and properties of compounds. The course provides laboratory experience in the use of modern instruments along with other chemical techniques. Aspects of analytical, organic, and physical chemistry will be illustrated throughout the course. Students cannot get credit for both this course and CHEM 2110 .
A lecture/laboratory course for Chemical Engineering students. Topics include the principles of chemical equilibria and their relation to modern analytical methods and the basis of instrumental techniques for characterizing the chemical structures and properties of compounds. The course provides laboratory experience in the use of modern instruments along with other chemical techniques. Aspects of analytical, organic, and physical chemistry will be illustrated throughout the course. Students cannot get credit for both this course and .
</p>
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courses/CHEM-4620.html
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CHEM-4620: Introduction to Polymer Chemistry
</title>
<meta property="og:title" content="CHEM-4620: Introduction to Polymer Chemistry">
<meta property="og:description" content="This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and CHEM 6620 .">
<meta property="og:description" content="This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and .">
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CHEM-4620
</h2>
<p>
This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and CHEM 6620 .
This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and .
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courses/CHEM-4710.html
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CHEM-4710: Chemical Biology
</title>
<meta property="og:title" content="CHEM-4710: Chemical Biology">
<meta property="og:description" content="This course introduces the fundamentals of protein structure and function with an emphasis on chemical concepts as applied to biological problems. It provides an introduction to enzymatic reaction mechanisms and includes interactive hands-on computer-aided visualization exercises. The goal is to equip students with an understanding and appreciation for the diversity and versatility of protein function. This course is intended for upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and CHEM 6710 .">
<meta property="og:description" content="This course introduces the fundamentals of protein structure and function with an emphasis on chemical concepts as applied to biological problems. It provides an introduction to enzymatic reaction mechanisms and includes interactive hands-on computer-aided visualization exercises. The goal is to equip students with an understanding and appreciation for the diversity and versatility of protein function. This course is intended for upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and .">
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CHEM-4710
</h2>
<p>
This course introduces the fundamentals of protein structure and function with an emphasis on chemical concepts as applied to biological problems. It provides an introduction to enzymatic reaction mechanisms and includes interactive hands-on computer-aided visualization exercises. The goal is to equip students with an understanding and appreciation for the diversity and versatility of protein function. This course is intended for upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and CHEM 6710 .
This course introduces the fundamentals of protein structure and function with an emphasis on chemical concepts as applied to biological problems. It provides an introduction to enzymatic reaction mechanisms and includes interactive hands-on computer-aided visualization exercises. The goal is to equip students with an understanding and appreciation for the diversity and versatility of protein function. This course is intended for upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and .
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courses/CHEM-4760.html
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CHEM-4760: Molecular Biochemistry I
</title>
<meta property="og:title" content="CHEM-4760: Molecular Biochemistry I">
<meta property="og:description" content="Part I of a two-semester sequence focusing on the chemistry, structure, and function of biological molecules, macromolecules, and systems. Topics covered include protein and nucleic acid structure, enzymology, mechanisms of catalysis, regulation, lipids and membranes, carbohydrates, bioenergetics, and carbohydrate metabolism. (Students cannot obtain credit for both this course and either BIOL 4760 or BCBP 4760 .)">
<meta property="og:description" content="Part I of a two-semester sequence focusing on the chemistry, structure, and function of biological molecules, macromolecules, and systems. Topics covered include protein and nucleic acid structure, enzymology, mechanisms of catalysis, regulation, lipids and membranes, carbohydrates, bioenergetics, and carbohydrate metabolism. (Students cannot obtain credit for both this course and either or .)">
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CHEM-4760
</h2>
<p>
Part I of a two-semester sequence focusing on the chemistry, structure, and function of biological molecules, macromolecules, and systems. Topics covered include protein and nucleic acid structure, enzymology, mechanisms of catalysis, regulation, lipids and membranes, carbohydrates, bioenergetics, and carbohydrate metabolism. (Students cannot obtain credit for both this course and either BIOL 4760 or BCBP 4760 .)
Part I of a two-semester sequence focusing on the chemistry, structure, and function of biological molecules, macromolecules, and systems. Topics covered include protein and nucleic acid structure, enzymology, mechanisms of catalysis, regulation, lipids and membranes, carbohydrates, bioenergetics, and carbohydrate metabolism. (Students cannot obtain credit for both this course and either or .)
</p>
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courses/CHEM-4770.html
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CHEM-4770: Molecular Biochemistry II
</title>
<meta property="og:title" content="CHEM-4770: Molecular Biochemistry II">
<meta property="og:description" content="The second semester of the Molecular Biochemistry sequence. Topics include lipids and lipid metabolism, amino acid metabolism and the coenzymes involved in this metabolism, nucleic acid synthesis and chemistry, protein synthesis and degradation, integration of metabolism, photobiology, and photosynthesis. This course is taught in studio mode. (Students cannot obtain credit for both this course and either BIOL 4770 or BCBP 4770 .)">
<meta property="og:description" content="The second semester of the Molecular Biochemistry sequence. Topics include lipids and lipid metabolism, amino acid metabolism and the coenzymes involved in this metabolism, nucleic acid synthesis and chemistry, protein synthesis and degradation, integration of metabolism, photobiology, and photosynthesis. This course is taught in studio mode. (Students cannot obtain credit for both this course and either or .)">
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CHEM-4770
</h2>
<p>
The second semester of the Molecular Biochemistry sequence. Topics include lipids and lipid metabolism, amino acid metabolism and the coenzymes involved in this metabolism, nucleic acid synthesis and chemistry, protein synthesis and degradation, integration of metabolism, photobiology, and photosynthesis. This course is taught in studio mode. (Students cannot obtain credit for both this course and either BIOL 4770 or BCBP 4770 .)
The second semester of the Molecular Biochemistry sequence. Topics include lipids and lipid metabolism, amino acid metabolism and the coenzymes involved in this metabolism, nucleic acid synthesis and chemistry, protein synthesis and degradation, integration of metabolism, photobiology, and photosynthesis. This course is taught in studio mode. (Students cannot obtain credit for both this course and either or .)
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courses/CHEM-4780.html
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CHEM-4780: Bioenergetics: The Art of Energy Conversion in Nature
</title>
<meta property="og:title" content="CHEM-4780: Bioenergetics: The Art of Energy Conversion in Nature">
<meta property="og:description" content="This course introduces the chemical and physical principles of energy transformation in nature. It emphasizes the structure and function of proteins with a special focus on highly-efficient energy conversion in mitochondrial and photosynthetic systems. The course provides the basic physical and chemical concepts that are required for understanding energy conversion and offers design principles that can be applied to the improvement of man-made catalytic and other devices for energy conversion and storage. It is intended for graduate or upper-level undergraduate students in the School of Science and Engineering. There are no prerequisites for this course. Students cannot get credit for both this course and CHEM 6780 .">
<meta property="og:description" content="This course introduces the chemical and physical principles of energy transformation in nature. It emphasizes the structure and function of proteins with a special focus on highly-efficient energy conversion in mitochondrial and photosynthetic systems. The course provides the basic physical and chemical concepts that are required for understanding energy conversion and offers design principles that can be applied to the improvement of man-made catalytic and other devices for energy conversion and storage. It is intended for graduate or upper-level undergraduate students in the School of Science and Engineering. There are no prerequisites for this course. Students cannot get credit for both this course and .">
<link rel="stylesheet" href="../css/common.css">
<link rel="stylesheet" href="../css/coursedisplay.css">
<link rel="stylesheet" href="../css/themes.css">
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CHEM-4780
</h2>
<p>
This course introduces the chemical and physical principles of energy transformation in nature. It emphasizes the structure and function of proteins with a special focus on highly-efficient energy conversion in mitochondrial and photosynthetic systems. The course provides the basic physical and chemical concepts that are required for understanding energy conversion and offers design principles that can be applied to the improvement of man-made catalytic and other devices for energy conversion and storage. It is intended for graduate or upper-level undergraduate students in the School of Science and Engineering. There are no prerequisites for this course. Students cannot get credit for both this course and CHEM 6780 .
This course introduces the chemical and physical principles of energy transformation in nature. It emphasizes the structure and function of proteins with a special focus on highly-efficient energy conversion in mitochondrial and photosynthetic systems. The course provides the basic physical and chemical concepts that are required for understanding energy conversion and offers design principles that can be applied to the improvement of man-made catalytic and other devices for energy conversion and storage. It is intended for graduate or upper-level undergraduate students in the School of Science and Engineering. There are no prerequisites for this course. Students cannot get credit for both this course and .
</p>
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courses/CHEM-6130.html
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CHEM-6130: Mass Spectrometry
</title>
<meta property="og:title" content="CHEM-6130: Mass Spectrometry">
<meta property="og:description" content="Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both CHEM 4130 and CHEM 6130.">
<meta property="og:description" content="Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both and CHEM 6130.">
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<link rel="stylesheet" href="../css/coursedisplay.css">
<link rel="stylesheet" href="../css/themes.css">
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CHEM-6130
</h2>
<p>
Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both CHEM 4130 and CHEM 6130.
Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both and CHEM 6130.
</p>
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courses/CHEM-6140.html
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CHEM-6140: NMR Spectroscopy for Scientists and Engineers
</title>
<meta property="og:title" content="CHEM-6140: NMR Spectroscopy for Scientists and Engineers">
<meta property="og:description" content="This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and CHEM 4140 .">
<meta property="og:description" content="This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and .">
<link rel="stylesheet" href="../css/common.css">
<link rel="stylesheet" href="../css/coursedisplay.css">
<link rel="stylesheet" href="../css/themes.css">
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CHEM-6140
</h2>
<p>
This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and CHEM 4140 .
This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and .
</p>
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courses/CHEM-6170.html
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CHEM-6170: Advanced Topics in Nuclear Magnetic Resonance
</title>
<meta property="og:title" content="CHEM-6170: Advanced Topics in Nuclear Magnetic Resonance">
<meta property="og:description" content="Advanced graduate course covering fundamental aspects of NMR common for application in a broad range of fields. Classical and quantum-mechanical descriptions are utilized to explore information content of NMR pulse sequences. The latter approach includes density matrix theory and proceeds with the product-operator formalism. Practical aspects and data analysis are also described. Subsequent focus is on liquid-state NMR of biological macromolecules, including resonance assignment and determination of molecular structure and dynamics. Students cannot obtain credit for both this course and BCBP 6170 .">
<meta property="og:description" content="Advanced graduate course covering fundamental aspects of NMR common for application in a broad range of fields. Classical and quantum-mechanical descriptions are utilized to explore information content of NMR pulse sequences. The latter approach includes density matrix theory and proceeds with the product-operator formalism. Practical aspects and data analysis are also described. Subsequent focus is on liquid-state NMR of biological macromolecules, including resonance assignment and determination of molecular structure and dynamics. Students cannot obtain credit for both this course and .">
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CHEM-6170
</h2>
<p>
Advanced graduate course covering fundamental aspects of NMR common for application in a broad range of fields. Classical and quantum-mechanical descriptions are utilized to explore information content of NMR pulse sequences. The latter approach includes density matrix theory and proceeds with the product-operator formalism. Practical aspects and data analysis are also described. Subsequent focus is on liquid-state NMR of biological macromolecules, including resonance assignment and determination of molecular structure and dynamics. Students cannot obtain credit for both this course and BCBP 6170 .
Advanced graduate course covering fundamental aspects of NMR common for application in a broad range of fields. Classical and quantum-mechanical descriptions are utilized to explore information content of NMR pulse sequences. The latter approach includes density matrix theory and proceeds with the product-operator formalism. Practical aspects and data analysis are also described. Subsequent focus is on liquid-state NMR of biological macromolecules, including resonance assignment and determination of molecular structure and dynamics. Students cannot obtain credit for both this course and .
</p>
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4
courses/CHEM-6310.html
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@ -5,7 +5,7 @@
CHEM-6310: Bioorganic Mechanisms
</title>
<meta property="og:title" content="CHEM-6310: Bioorganic Mechanisms">
<meta property="og:description" content="The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with CHEM 4310 ; both courses cannot be taken for credit.">
<meta property="og:description" content="The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with ; both courses cannot be taken for credit.">
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@ -34,7 +34,7 @@
CHEM-6310
</h2>
<p>
The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with CHEM 4310 ; both courses cannot be taken for credit.
The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with ; both courses cannot be taken for credit.
</p>
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4
courses/CHEM-6330.html
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@ -5,7 +5,7 @@
CHEM-6330: Drug Discovery
</title>
<meta property="og:title" content="CHEM-6330: Drug Discovery">
<meta property="og:description" content="This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and CHEM 4330 .">
<meta property="og:description" content="This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and .">
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@ -34,7 +34,7 @@
CHEM-6330
</h2>
<p>
This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and CHEM 4330 .
This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and .
</p>
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courses/CHEM-6620.html
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@ -5,7 +5,7 @@
CHEM-6620: Polymer Chemistry
</title>
<meta property="og:title" content="CHEM-6620: Polymer Chemistry">
<meta property="og:description" content="This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and CHEM 4620 .">
<meta property="og:description" content="This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and .">
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@ -34,7 +34,7 @@
CHEM-6620
</h2>
<p>
This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and CHEM 4620 .
This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and .
</p>
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courses/CHME-2020.html
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@ -5,7 +5,7 @@
CHME-2020: Energy, Entropy, and Equilibrium
</title>
<meta property="og:title" content="CHME-2020: Energy, Entropy, and Equilibrium">
<meta property="og:description" content="A continuation of CHME 2010 . Topics include process flowsheeting, solution thermodynamics, phase equilibria, chemical-reaction equilibria, and applications of thermodynamics to problems in chemical-process design. One credit hour of this course is devoted to Professional Development.">
<meta property="og:description" content="A continuation of . Topics include process flowsheeting, solution thermodynamics, phase equilibria, chemical-reaction equilibria, and applications of thermodynamics to problems in chemical-process design. One credit hour of this course is devoted to Professional Development.">
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CHME-2020
</h2>
<p>
A continuation of CHME 2010 . Topics include process flowsheeting, solution thermodynamics, phase equilibria, chemical-reaction equilibria, and applications of thermodynamics to problems in chemical-process design. One credit hour of this course is devoted to Professional Development.
A continuation of . Topics include process flowsheeting, solution thermodynamics, phase equilibria, chemical-reaction equilibria, and applications of thermodynamics to problems in chemical-process design. One credit hour of this course is devoted to Professional Development.
</p>
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courses/CHME-4010.html
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@ -5,7 +5,7 @@
CHME-4010: Transport Phenomena I
</title>
<meta property="og:title" content="CHME-4010: Transport Phenomena I">
<meta property="og:description" content="An introductory course in transport phenomena covering fluid statics, and one-dimensional diffusive processes including laminar flow, heat conduction, and mass diffusion. Course focuses on developing the equations of change, introducing sum-of-resistance concepts and couple fluid flow, heat transfer, and mass transfer problems. The concept of extended surfaces as a means of enhancing transport process is included. The course introduces numerical simulation concepts for solving simple, one-dimensional transport problems. Credit not allowed for both this course and ENGR 2250 .">
<meta property="og:description" content="An introductory course in transport phenomena covering fluid statics, and one-dimensional diffusive processes including laminar flow, heat conduction, and mass diffusion. Course focuses on developing the equations of change, introducing sum-of-resistance concepts and couple fluid flow, heat transfer, and mass transfer problems. The concept of extended surfaces as a means of enhancing transport process is included. The course introduces numerical simulation concepts for solving simple, one-dimensional transport problems. Credit not allowed for both this course and .">
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@ -34,7 +34,7 @@
CHME-4010
</h2>
<p>
An introductory course in transport phenomena covering fluid statics, and one-dimensional diffusive processes including laminar flow, heat conduction, and mass diffusion. Course focuses on developing the equations of change, introducing sum-of-resistance concepts and couple fluid flow, heat transfer, and mass transfer problems. The concept of extended surfaces as a means of enhancing transport process is included. The course introduces numerical simulation concepts for solving simple, one-dimensional transport problems. Credit not allowed for both this course and ENGR 2250 .
An introductory course in transport phenomena covering fluid statics, and one-dimensional diffusive processes including laminar flow, heat conduction, and mass diffusion. Course focuses on developing the equations of change, introducing sum-of-resistance concepts and couple fluid flow, heat transfer, and mass transfer problems. The concept of extended surfaces as a means of enhancing transport process is included. The course introduces numerical simulation concepts for solving simple, one-dimensional transport problems. Credit not allowed for both this course and .
</p>
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courses/CHME-4011.html
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@ -5,7 +5,7 @@
CHME-4011: Semiconductor Electrochemistry
</title>
<meta property="og:title" content="CHME-4011: Semiconductor Electrochemistry">
<meta property="og:description" content="An interdisciplinary course focusing on the fundamentals and applications of semiconductor electrochemistry, and will serve as a bridge between classical electrochemistry and solid state physics. Topics include fundamentals of semiconductor physics, principles of electrochemistry, nature of semiconductor/electrolyte interfaces, current flow, and the applications of above principles to environment remediation and renewable energy devices such as solar cells, photocatalysis, and battery technologies. This course is cross listed with CHME 6011 .">
<meta property="og:description" content="An interdisciplinary course focusing on the fundamentals and applications of semiconductor electrochemistry, and will serve as a bridge between classical electrochemistry and solid state physics. Topics include fundamentals of semiconductor physics, principles of electrochemistry, nature of semiconductor/electrolyte interfaces, current flow, and the applications of above principles to environment remediation and renewable energy devices such as solar cells, photocatalysis, and battery technologies. This course is cross listed with .">
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<link rel="stylesheet" href="../css/themes.css">
@ -34,7 +34,7 @@
CHME-4011
</h2>
<p>
An interdisciplinary course focusing on the fundamentals and applications of semiconductor electrochemistry, and will serve as a bridge between classical electrochemistry and solid state physics. Topics include fundamentals of semiconductor physics, principles of electrochemistry, nature of semiconductor/electrolyte interfaces, current flow, and the applications of above principles to environment remediation and renewable energy devices such as solar cells, photocatalysis, and battery technologies. This course is cross listed with CHME 6011 .
An interdisciplinary course focusing on the fundamentals and applications of semiconductor electrochemistry, and will serve as a bridge between classical electrochemistry and solid state physics. Topics include fundamentals of semiconductor physics, principles of electrochemistry, nature of semiconductor/electrolyte interfaces, current flow, and the applications of above principles to environment remediation and renewable energy devices such as solar cells, photocatalysis, and battery technologies. This course is cross listed with .
</p>
<div id="cattrs-container">
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courses/CHME-4020.html
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@ -5,7 +5,7 @@
CHME-4020: Transport Phenomena II
</title>
<meta property="og:title" content="CHME-4020: Transport Phenomena II">
<meta property="og:description" content="A continuation of CHME 4010 . Course includes topics on multi-dimensional transport processes, potential, boundary layer and turbulent fluid flows, convective heat and mass transfer processes, friction factors and drag in and around solid objects, heat and mass exchangers, and radiation heat transfer. The course extends the use of numerical methods to apply to multidimensional problems, convective heat and mass transfer problems, and the simulation of more complicated fluid flows including turbulence approximations. Credit not allowed for both this course and ENGR 2250 .">
<meta property="og:description" content="A continuation of . Course includes topics on multi-dimensional transport processes, potential, boundary layer and turbulent fluid flows, convective heat and mass transfer processes, friction factors and drag in and around solid objects, heat and mass exchangers, and radiation heat transfer. The course extends the use of numerical methods to apply to multidimensional problems, convective heat and mass transfer problems, and the simulation of more complicated fluid flows including turbulence approximations. Credit not allowed for both this course and .">
<link rel="stylesheet" href="../css/common.css">
<link rel="stylesheet" href="../css/coursedisplay.css">
<link rel="stylesheet" href="../css/themes.css">
@ -34,7 +34,7 @@
CHME-4020
</h2>
<p>
A continuation of CHME 4010 . Course includes topics on multi-dimensional transport processes, potential, boundary layer and turbulent fluid flows, convective heat and mass transfer processes, friction factors and drag in and around solid objects, heat and mass exchangers, and radiation heat transfer. The course extends the use of numerical methods to apply to multidimensional problems, convective heat and mass transfer problems, and the simulation of more complicated fluid flows including turbulence approximations. Credit not allowed for both this course and ENGR 2250 .
A continuation of . Course includes topics on multi-dimensional transport processes, potential, boundary layer and turbulent fluid flows, convective heat and mass transfer processes, friction factors and drag in and around solid objects, heat and mass exchangers, and radiation heat transfer. The course extends the use of numerical methods to apply to multidimensional problems, convective heat and mass transfer problems, and the simulation of more complicated fluid flows including turbulence approximations. Credit not allowed for both this course and .
</p>
<div id="cattrs-container">
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4
courses/CHME-4060.html
View file

@ -5,7 +5,7 @@
CHME-4060: Chemical Process Design: Applications
</title>
<meta property="og:title" content="CHME-4060: Chemical Process Design: Applications">
<meta property="og:description" content="A continuation of CHME 4050 . Topics include chemical plant design including full economic analysis, implementation of safety protocols, plant layout design, and complete feasibility study. Projects can be chosen from a wide variety of chemical and bioprocesses to study different aspects of chemical industry.">
<meta property="og:description" content="A continuation of . Topics include chemical plant design including full economic analysis, implementation of safety protocols, plant layout design, and complete feasibility study. Projects can be chosen from a wide variety of chemical and bioprocesses to study different aspects of chemical industry.">
<link rel="stylesheet" href="../css/common.css">
<link rel="stylesheet" href="../css/coursedisplay.css">
<link rel="stylesheet" href="../css/themes.css">
@ -34,7 +34,7 @@
CHME-4060
</h2>
<p>
A continuation of CHME 4050 . Topics include chemical plant design including full economic analysis, implementation of safety protocols, plant layout design, and complete feasibility study. Projects can be chosen from a wide variety of chemical and bioprocesses to study different aspects of chemical industry.
A continuation of . Topics include chemical plant design including full economic analysis, implementation of safety protocols, plant layout design, and complete feasibility study. Projects can be chosen from a wide variety of chemical and bioprocesses to study different aspects of chemical industry.
</p>
<div id="cattrs-container">
<span id="credits-pill" class="attr-pill">

2
courses/MATH-1900.html
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@ -135,7 +135,7 @@
<ul class="prof-list">
</ul>
<span class="course-capacity">
Seats Taken: 19/32
Seats Taken: 20/32
</span>
</div>
</td>

2
courses/MGMT-1100.html
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@ -162,7 +162,7 @@
<li>Margaret A McDermott</li>
</ul>
<span class="course-capacity">
Seats Taken: 126/180
Seats Taken: 125/180
</span>
</div>
</td>

2
courses/PHYS-1960.html
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@ -142,7 +142,7 @@
<li>Charles Harold Martin</li>
</ul>
<span class="course-capacity">
Seats Taken: 271/720
Seats Taken: 272/720
</span>
</div>
</td>

46
json/searchable_catalog.json
View file

@ -7446,7 +7446,7 @@
"attributes" : null,
"code" : "CHEM-4620",
"credits" : "3 credits",
"description" : "This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and CHEM 6620 .",
"description" : "This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and .",
"name" : "Introduction to Polymer Chemistry"
},
{
@ -9787,7 +9787,7 @@
"attributes" : null,
"code" : "CHME-4060",
"credits" : "? credits",
"description" : "A continuation of CHME 4050 . Topics include chemical plant design including full economic analysis, implementation of safety protocols, plant layout design, and complete feasibility study. Projects can be chosen from a wide variety of chemical and bioprocesses to study different aspects of chemical industry.",
"description" : "A continuation of . Topics include chemical plant design including full economic analysis, implementation of safety protocols, plant layout design, and complete feasibility study. Projects can be chosen from a wide variety of chemical and bioprocesses to study different aspects of chemical industry.",
"name" : "Chemical Process Design: Applications"
},
{
@ -9815,7 +9815,7 @@
"attributes" : null,
"code" : "CHEM-6310",
"credits" : "3 credits",
"description" : "The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with CHEM 4310 ; both courses cannot be taken for credit.",
"description" : "The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with ; both courses cannot be taken for credit.",
"name" : "Bioorganic Mechanisms"
},
{
@ -11766,7 +11766,7 @@
"attributes" : null,
"code" : "CHME-4020",
"credits" : "4 credits",
"description" : "A continuation of CHME 4010 . Course includes topics on multi-dimensional transport processes, potential, boundary layer and turbulent fluid flows, convective heat and mass transfer processes, friction factors and drag in and around solid objects, heat and mass exchangers, and radiation heat transfer. The course extends the use of numerical methods to apply to multidimensional problems, convective heat and mass transfer problems, and the simulation of more complicated fluid flows including turbulence approximations. Credit not allowed for both this course and ENGR 2250 .",
"description" : "A continuation of . Course includes topics on multi-dimensional transport processes, potential, boundary layer and turbulent fluid flows, convective heat and mass transfer processes, friction factors and drag in and around solid objects, heat and mass exchangers, and radiation heat transfer. The course extends the use of numerical methods to apply to multidimensional problems, convective heat and mass transfer problems, and the simulation of more complicated fluid flows including turbulence approximations. Credit not allowed for both this course and .",
"name" : "Transport Phenomena II"
},
{
@ -14550,7 +14550,7 @@
"attributes" : null,
"code" : "CHEM-4770",
"credits" : "4 credits",
"description" : "The second semester of the Molecular Biochemistry sequence. Topics include lipids and lipid metabolism, amino acid metabolism and the coenzymes involved in this metabolism, nucleic acid synthesis and chemistry, protein synthesis and degradation, integration of metabolism, photobiology, and photosynthesis. This course is taught in studio mode. (Students cannot obtain credit for both this course and either BIOL 4770 or BCBP 4770 .)",
"description" : "The second semester of the Molecular Biochemistry sequence. Topics include lipids and lipid metabolism, amino acid metabolism and the coenzymes involved in this metabolism, nucleic acid synthesis and chemistry, protein synthesis and degradation, integration of metabolism, photobiology, and photosynthesis. This course is taught in studio mode. (Students cannot obtain credit for both this course and either or .)",
"name" : "Molecular Biochemistry II"
},
{
@ -15188,7 +15188,7 @@
"attributes" : null,
"code" : "CHEM-6330",
"credits" : "3 credits",
"description" : "This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and CHEM 4330 .",
"description" : "This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and .",
"name" : "Drug Discovery"
},
{
@ -16134,7 +16134,7 @@
"attributes" : null,
"code" : "CHEM-6130",
"credits" : "3 credits",
"description" : "Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both CHEM 4130 and CHEM 6130.",
"description" : "Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both and CHEM 6130.",
"name" : "Mass Spectrometry"
},
{
@ -16588,7 +16588,7 @@
"attributes" : null,
"code" : "CHEM-4780",
"credits" : "4 credits",
"description" : "This course introduces the chemical and physical principles of energy transformation in nature. It emphasizes the structure and function of proteins with a special focus on highly-efficient energy conversion in mitochondrial and photosynthetic systems. The course provides the basic physical and chemical concepts that are required for understanding energy conversion and offers design principles that can be applied to the improvement of man-made catalytic and other devices for energy conversion and storage. It is intended for graduate or upper-level undergraduate students in the School of Science and Engineering. There are no prerequisites for this course. Students cannot get credit for both this course and CHEM 6780 .",
"description" : "This course introduces the chemical and physical principles of energy transformation in nature. It emphasizes the structure and function of proteins with a special focus on highly-efficient energy conversion in mitochondrial and photosynthetic systems. The course provides the basic physical and chemical concepts that are required for understanding energy conversion and offers design principles that can be applied to the improvement of man-made catalytic and other devices for energy conversion and storage. It is intended for graduate or upper-level undergraduate students in the School of Science and Engineering. There are no prerequisites for this course. Students cannot get credit for both this course and .",
"name" : "Bioenergetics: The Art of Energy Conversion in Nature"
},
{
@ -17194,7 +17194,7 @@
"attributes" : null,
"code" : "CHME-4010",
"credits" : "4 credits",
"description" : "An introductory course in transport phenomena covering fluid statics, and one-dimensional diffusive processes including laminar flow, heat conduction, and mass diffusion. Course focuses on developing the equations of change, introducing sum-of-resistance concepts and couple fluid flow, heat transfer, and mass transfer problems. The concept of extended surfaces as a means of enhancing transport process is included. The course introduces numerical simulation concepts for solving simple, one-dimensional transport problems. Credit not allowed for both this course and ENGR 2250 .",
"description" : "An introductory course in transport phenomena covering fluid statics, and one-dimensional diffusive processes including laminar flow, heat conduction, and mass diffusion. Course focuses on developing the equations of change, introducing sum-of-resistance concepts and couple fluid flow, heat transfer, and mass transfer problems. The concept of extended surfaces as a means of enhancing transport process is included. The course introduces numerical simulation concepts for solving simple, one-dimensional transport problems. Credit not allowed for both this course and .",
"name" : "Transport Phenomena I"
},
{
@ -17498,7 +17498,7 @@
"attributes" : null,
"code" : "CHEM-4130",
"credits" : "3 credits",
"description" : "Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both CHEM 4130 and CHEM 6130 .",
"description" : "Survey of modern techniques in and associated with mass spectrometry, including historical perspectives, strengths/weaknesses, detection/quantification of analytes, ionization source/mass analyzer design, and construction of associated technologies including vacuum systems, ion detection, and ion optics. Ion formation processes will also be discussed. Students cannot get credit for both CHEM 4130 and .",
"name" : "Mass Spectrometry"
},
{
@ -17652,14 +17652,14 @@
"attributes" : null,
"code" : "CHEM-4530",
"credits" : "4 credits",
"description" : "A lecture/laboratory course for Chemical Engineering students. Topics include the principles of chemical equilibria and their relation to modern analytical methods and the basis of instrumental techniques for characterizing the chemical structures and properties of compounds. The course provides laboratory experience in the use of modern instruments along with other chemical techniques. Aspects of analytical, organic, and physical chemistry will be illustrated throughout the course. Students cannot get credit for both this course and CHEM 2110 .",
"description" : "A lecture/laboratory course for Chemical Engineering students. Topics include the principles of chemical equilibria and their relation to modern analytical methods and the basis of instrumental techniques for characterizing the chemical structures and properties of compounds. The course provides laboratory experience in the use of modern instruments along with other chemical techniques. Aspects of analytical, organic, and physical chemistry will be illustrated throughout the course. Students cannot get credit for both this course and .",
"name" : "Modern Techniques in Chemistry"
},
{
"attributes" : null,
"code" : "CHEM-4110",
"credits" : "3 credits",
"description" : "This course will introduce advanced instrumental physicochemical methods of chemical analysis as well as instrument design and data capture/processing. Topics covered include atomic and molecular spectroscopy, chromatography, electroanalytical chemistry and measurement basics. This course is a prerequisite or corequisite for CHEM 4120 / CHEM 4130 .",
"description" : "This course will introduce advanced instrumental physicochemical methods of chemical analysis as well as instrument design and data capture/processing. Topics covered include atomic and molecular spectroscopy, chromatography, electroanalytical chemistry and measurement basics. This course is a prerequisite or corequisite for / .",
"name" : "Instrumental Methods of Analysis"
},
{
@ -17823,7 +17823,7 @@
"attributes" : null,
"code" : "CHEM-4030",
"credits" : "2 credits",
"description" : "Laboratory exploration of physical methods used to characterize the structure and properties of compounds. Involves the experiments in CHEM 4020 that do not depend on the theoretical material of CHEM 4010 . Students can not get credit for both this course and CHEM 4020 .",
"description" : "Laboratory exploration of physical methods used to characterize the structure and properties of compounds. Involves the experiments in that do not depend on the theoretical material of . Students can not get credit for both this course and .",
"name" : "Experimental Chemistry III Abridged: Physical Methods"
},
{
@ -17930,7 +17930,7 @@
"attributes" : null,
"code" : "CHEM-6140",
"credits" : "3 credits",
"description" : "This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and CHEM 4140 .",
"description" : "This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and .",
"name" : "NMR Spectroscopy for Scientists and Engineers"
},
{
@ -18038,7 +18038,7 @@
"attributes" : null,
"code" : "CHEM-4330",
"credits" : "3 credits",
"description" : "This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and CHEM 6330 .",
"description" : "This course will examine how bioinformatics, functional genomics, and other modern biotechnologies are used to speed the discovery of new drugs, especially those small organic molecules to treat human diseases with large unmet therapeutic need. Special emphasis will be placed on molecular target identification and validation as well as high-throughput screening to identify a lead. Topics to be discussed will include transgenic mice, RNA interference, DNA and protein microarrays, homogenous time-resolved fluorescence bioassays, phage-display, combinatorial chemistry, and parallel synthesis. Students cannot receive credit for both this course and .",
"name" : "Drug Discovery"
},
{
@ -18100,7 +18100,7 @@
"attributes" : null,
"code" : "CHEM-4710",
"credits" : "3 credits",
"description" : "This course introduces the fundamentals of protein structure and function with an emphasis on chemical concepts as applied to biological problems. It provides an introduction to enzymatic reaction mechanisms and includes interactive hands-on computer-aided visualization exercises. The goal is to equip students with an understanding and appreciation for the diversity and versatility of protein function. This course is intended for upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and CHEM 6710 .",
"description" : "This course introduces the fundamentals of protein structure and function with an emphasis on chemical concepts as applied to biological problems. It provides an introduction to enzymatic reaction mechanisms and includes interactive hands-on computer-aided visualization exercises. The goal is to equip students with an understanding and appreciation for the diversity and versatility of protein function. This course is intended for upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and .",
"name" : "Chemical Biology"
},
{
@ -18149,7 +18149,7 @@
"attributes" : null,
"code" : "CHEM-4760",
"credits" : "4 credits",
"description" : "Part I of a two-semester sequence focusing on the chemistry, structure, and function of biological molecules, macromolecules, and systems. Topics covered include protein and nucleic acid structure, enzymology, mechanisms of catalysis, regulation, lipids and membranes, carbohydrates, bioenergetics, and carbohydrate metabolism. (Students cannot obtain credit for both this course and either BIOL 4760 or BCBP 4760 .)",
"description" : "Part I of a two-semester sequence focusing on the chemistry, structure, and function of biological molecules, macromolecules, and systems. Topics covered include protein and nucleic acid structure, enzymology, mechanisms of catalysis, regulation, lipids and membranes, carbohydrates, bioenergetics, and carbohydrate metabolism. (Students cannot obtain credit for both this course and either or .)",
"name" : "Molecular Biochemistry I"
},
{
@ -18254,7 +18254,7 @@
"attributes" : null,
"code" : "CHEM-6170",
"credits" : "4 credits",
"description" : "Advanced graduate course covering fundamental aspects of NMR common for application in a broad range of fields. Classical and quantum-mechanical descriptions are utilized to explore information content of NMR pulse sequences. The latter approach includes density matrix theory and proceeds with the product-operator formalism. Practical aspects and data analysis are also described. Subsequent focus is on liquid-state NMR of biological macromolecules, including resonance assignment and determination of molecular structure and dynamics. Students cannot obtain credit for both this course and BCBP 6170 .",
"description" : "Advanced graduate course covering fundamental aspects of NMR common for application in a broad range of fields. Classical and quantum-mechanical descriptions are utilized to explore information content of NMR pulse sequences. The latter approach includes density matrix theory and proceeds with the product-operator formalism. Practical aspects and data analysis are also described. Subsequent focus is on liquid-state NMR of biological macromolecules, including resonance assignment and determination of molecular structure and dynamics. Students cannot obtain credit for both this course and .",
"name" : "Advanced Topics in Nuclear Magnetic Resonance"
},
{
@ -18407,7 +18407,7 @@
"attributes" : null,
"code" : "CHME-2020",
"credits" : "3 credits",
"description" : "A continuation of CHME 2010 . Topics include process flowsheeting, solution thermodynamics, phase equilibria, chemical-reaction equilibria, and applications of thermodynamics to problems in chemical-process design. One credit hour of this course is devoted to Professional Development.",
"description" : "A continuation of . Topics include process flowsheeting, solution thermodynamics, phase equilibria, chemical-reaction equilibria, and applications of thermodynamics to problems in chemical-process design. One credit hour of this course is devoted to Professional Development.",
"name" : "Energy, Entropy, and Equilibrium"
},
{
@ -18449,7 +18449,7 @@
"attributes" : null,
"code" : "CHME-4011",
"credits" : "3 credits",
"description" : "An interdisciplinary course focusing on the fundamentals and applications of semiconductor electrochemistry, and will serve as a bridge between classical electrochemistry and solid state physics. Topics include fundamentals of semiconductor physics, principles of electrochemistry, nature of semiconductor/electrolyte interfaces, current flow, and the applications of above principles to environment remediation and renewable energy devices such as solar cells, photocatalysis, and battery technologies. This course is cross listed with CHME 6011 .",
"description" : "An interdisciplinary course focusing on the fundamentals and applications of semiconductor electrochemistry, and will serve as a bridge between classical electrochemistry and solid state physics. Topics include fundamentals of semiconductor physics, principles of electrochemistry, nature of semiconductor/electrolyte interfaces, current flow, and the applications of above principles to environment remediation and renewable energy devices such as solar cells, photocatalysis, and battery technologies. This course is cross listed with .",
"name" : "Semiconductor Electrochemistry"
},
{
@ -18965,7 +18965,7 @@
"attributes" : null,
"code" : "CHEM-6620",
"credits" : "3 credits",
"description" : "This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and CHEM 4620 .",
"description" : "This course will introduce synthetic and kinetic aspects of various polymerization reactions that have been employed to produce commodity and specialty plastic materials. Control and prediction of the molecular weight distribution for different polymerization mechanisms will be discussed along with various characterization techniques of molecular weight distribution and its relation to properties. Thermal/solution properties, chemical/physical properties, and uses of polymers also will be discussed. Students cannot get credit for both this course and .",
"name" : "Polymer Chemistry"
},
{
@ -22437,7 +22437,7 @@
"attributes" : null,
"code" : "CHEM-4310",
"credits" : "4 credits",
"description" : "The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with CHEM 6310 ; both courses cannot be taken for credit.",
"description" : "The study of mechanisms of organic reactions in biochemical processes on a molecular level. Enzyme active sites, mechanisms of enzymatic transformations, catalysis, cofactors, enzyme kinetics, environmental toxicology. Strong emphasis on the design and mechanism of action of pharmaceutical agents. Meets with ; both courses cannot be taken for credit.",
"name" : "Bioorganic Mechanisms"
},
{
@ -24452,7 +24452,7 @@
"attributes" : null,
"code" : "CHEM-4140",
"credits" : "3 credits",
"description" : "This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and CHEM 6140 .",
"description" : "This course will review modern techniques of multi-dimensional NMR spectroscopy, including the history of magnetic resonance, principles of NMR, 13C and 1H NMR, multinuclear NMR, 2D homonuclear and heteronuclear methods, nuclear Overhauser effect, relaxation, structure elucidation, solid-state NMR and the nuts and bolts of NMR spectrometers and probes. This course is intended for graduate and upper-level undergraduate students in the School of Science and Engineering. Students cannot get credit for both this course and .",
"name" : "NMR Spectroscopy for Scientists and Engineers"
},
{