A CHM 143 Pre-Organic Chemistry (1)The course provides a background and review of those topics necessary for success in organic chemistry. Topics may include bonding, Lewis acid/bases, hybridization, electronegativity, polarizability, 3-D structures, energy profile diagrams, oxidation states, and reaction mechanisms. Carbon containing compounds will be emphasized. Prerequisite(s): A CHM 120. Prerequisite(s) or corequisite(s): A CHM 121.
A CHM 220 Organic Chemistry I (3)Structure, synthesis, and reactions of the principal classes of organic compounds, stressing the underlying principles of reaction mechanisms and stereochemistry techniques. Prerequisite(s): A CHM 121 or 131 and 125.
Organic Chemistry: Principles and Mechanisms download
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A CHM 420 Inorganic Chemistry I (3)Bonding and reactivity in inorganic systems, including metal complexes and covalent molecules. Applications of crystal field theory and introductory molecular orbital theory to coordination compounds, including group theory and symmetry, the spectrochemical series, and substitution mechanisms. Metal carbonyl complexes and an introduction to organometallic compounds and their reactions. Prerequisite(s): A CHM 350 or 444.
A CHM 436 Advanced Organic Chemistry (3)Organic chemistry at an advanced level, including introduction of theoretical background and application in synthesis. Prerequisite(s) or corequisite(s): A CHM 351 or 445.A CHM 437 Organic Synthesis (3)The course will focus on the total synthesis of complex organic molecules, such as natural products. Synthetic strategies as well as reaction mechanisms of every step will be discussed. Prerequisite(s): A CHM 221.A CHM 438 Forensic Trace Metal Analysis (3)This course aims at providing students with fundamental skills and knowledge in trace metal analysis, in particular for forensic applications. The course will enable students to understand, develop and execute analytical protocols involving recent trace metal analysis methodologies and instrumentation, namely atomic spectroscopies and voltammetry. The lecture will consider all common techniques such as inorganic sample preparation, ICP-MS, ICP-OES, AAS, X-ray fluorescence, neutron activation, polarography, and stripping voltammetry. Students will learn by lectures, class activities, and homework assignments how to plan analytical tasks considering the available ICP, AAS, and voltammetry techniques in a modern routine laboratory, as well as how to optimize the conditions in order to obtain sufficient analytical performance parameters in terms of selectivity, detection limit, cost, and analysis time. Three lecture meetings per week. Prerequisite(s): A CHM 226 and 227 or 250 and 251. Corequisite(s): A CHM 350 or 444.A CHM 439 Introduction to Toxicology (3)Objective for this course is to provide the students with an appreciation and understanding of the fundamental principles of toxicology such as the basic chemistry of the toxicants, sources and fate of contaminants in the human organism, and effects of toxicants. While primarily designed for students of analytical chemistry, it is a beneficial course also for students from other backgrounds (biology, forensics, environmental sciences, etc.). Topics to be discussed will include major classifications of drugs as they relate to organ systems or major pathophysiological disease entities. The clinical toxicology section of the course will review the more common toxins, their effects, and appropriate treatments. Three contact hours of lecture meetings per week. Prerequisite(s): A CHM 342 or 442 or A BIO 365.
Description: College Chemistry II is the second course of a two-course sequence. This course covers fundamental principles of modern chemistry including problem-solving techniques. Topics include thermochemistry, thermodynamics, kinetics, equilibrium, acid-base theory, solubility products, oxidation-reduction, nuclear chemistry, and organic chemistry. Note: This course is not the designated SUNY Seamless Transfer Path course. Before the Fall 2017 this course was entitled "General Chemistry II" (3 lecture, 3 laboratory hours) Laboratory fee applies.SUNY GEN ED-GLAB; NCC GEN ED-LSCI Offered: Fall, Spring, Summer
Description: A one semester laboratory course encompassing basic principles of inorganic, organic and biochemistry with emphasis on their application. Topics include metric/SI systems, energy, basic atomic theory, stoichiometry, gas laws, solutions, pH, buffers, nomenclature and structure of organic compounds, amino acids, proteins, carbohydrates, lipids and metabolism. (3 lecture, 3 laboratory hours) Laboratory fee applies.SUNY GEN ED-GLAB; NCC GEN ED-LSCI Offered: Fall, Spring
Description: This is the first course of the CHE 201 - CHE 202 sequence. This 1st semester course in organic chemistry covers the nomenclature, physical properties, stereochemistry, structure-reactivity relationships, and reaction mechanisms of alkanes, alkenes and alkynes, Laboratory activities include organic synthesis, qualitative analysis and instrumental techniques. (3 lecture, 6 laboratory hours) Laboratory fee applies. Molecular model set required.SUNY GEN ED-GLAB; NCC GEN ED-LSCI Offered: Fall, Spring, Summer
This course is a one-semester, rigorous college level introductory Chemistry course covering the fundamental principles of general, organic, and biochemistry. One year of high school chemistry is strongly recommended, and students should have math placement beyond the level of Math 021. 3 Credits, fulfills the General Education requirements. Course topics include dimensional analysis, atomic structure and periodicity, chemical bonding, molecular structure, states of matter and intermolecular forces, basic gas laws, solutions and solubility, acids, bases and equilibria, reaction stoichiometry and thermodynamics. In addition, fundamentals of organic nomenclature, properties of main organic functional groups, structure and function of biological macromolecules, as well as metabolism will be discussed. The course will emphasize chemistry in environmental and health-related contexts. This course is primarily designed for students in a program that does not require the more theoretical and mathematically oriented general chemistry courses (CHEM 110/112), such as some majors in the colleges of Nursing, Agriculture Sciences, and Health & Human Development. It is a suitable prerequisite for the organic chemistry course sequence CHEM 202/203. This course is not appropriate for medical school preparation and will not serve as a prerequisite for the organic chemistry CHEM 210/212 course sequence. Students majoring in chemistry, other natural sciences, or engineering will normally register in the CHEM 110/112 sequence. Consult your advisor and the instructor if you have questions about CHEM 130 vs. CHEM 110/112.
Introduction to organic chemistry, with emphasis on the properties of organic compounds of biochemical importance. Because of duplication of subject matter, students may not receive credit for both CHEM 202 and CHEM 210. CHEM 202 CHEM 202 Fundamentals of Organic Chemistry I (3) CHEM 202 is a one-semester, comprehensive course that introduces the students to the fundamental principles of organic chemistry including relationships between the molecular structure of organic compounds and their macroscopic properties. Some of the principles are illustrated with a variety of examples from nature and everyday life. The course covers the following topics: alkanes; alkenes, including polymers; alkynes; benzene and aromaticity; alcohols and phenols; ethers; aldehydes; ketones; carboxylic acids and their acyl derivatives; amines; alkyl halides; nomenclature; stereochemistry, including conformational analysis and chirality. Chemical reactions of the functional groups will be discussed along with the mechanistic details, including stereospecificity, of some of these processes. Biological molecules such as carbohydrates, lipids, steroids, peptides/proteins and nucleic acids, along with their importance in living systems, will be surveyed.
Bonding theories for organic molecules; stereochemistry and conformational analysis; reactions (and mechanisms) of alkyl halides, alkenes, alkynes, aromatics, and alcohols. CHEM 210 Organic Chemistry I (3) Organic chemistry is an essential subject for many scientific disciplines, particularly those in the life, materials, and chemical sciences, as well as chemical engineering. The fundamentals of organic chemistry, as developed in CHEM 210, the first part of a two-semester organic chemistry sequence, are required for scientists to understand the electronic structure and reactivity of simple and complex molecules. Concepts taught in CHEM 210 include hierarchical bonding models (Lewis dot, valence bond, molecular orbital), Lewis acids and bases, conformational analysis and stereochemistry, functional groups and their reactivity (alkenes, alkynes, alkyl halides, dienes, aromatics, alcohols, and ethers), organic reaction mechanisms focusing on electrophiles and nucleophiles, and aromaticity. Successful students will understand and be able to apply various structural and reactivity models to solving problems in organic chemistry.
Principles and theories; nomenclature; chemistry of the functional groups; applications of spectroscopy. Because of duplication of material, students may not receive credit for both CHEM 210 and 202. CHEM 210H Organic Chemistry I - Honors (4) Chemistry 210H is the first semester of an in-depth two semester survey of organic chemistry. It should be followed by Chemistry 212H. The concentrated and fast-moving pace of this course is facilitated by four class periods/week, seven (biweekly) hour exams and an evening recitation dedicated to the informal discussion of the subject material covered in previous or pending hour exams. This course will emphasize the mechanistic underpinning of organic chemistry. That is, students will not only learn what happens in organic chemistry but also, and more importantly, why and how. It is hoped that students will develop an intuition for the structure, function and reactivity properties of organic compounds which is of fundamental importance for subsequent studies in the life, material and chemical sciences. The course begins with an introduction to the structural aspects of organic compounds and an appreciation of the three-dimensionality of the subject based upon the important concepts of molecular orbital theory, valence bond theory, hybridization and conformational analysis. Reaction mechanisms and organic synthesis, two important topics that are emphasized throughout the course, are introduced early in the context of addition reactions of alkenes and alkynes. Perhaps the most abstract/vexing topic in organic chemistry is next encountered, namely, stereochemistry. These fundamentals are then used to explore the reactivity properties of various classes of compounds including substitutions and eliminations of alkyl halides, free radical reactions of alkenes, isomerization and cycloadditions of conjugated pi systems, and electrophilic substitution reactions of aromatic compounds. 2ff7e9595c
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