University: Al-Nahrain ... Stage: 2 Lecturer name: Alaa H. jawd
University: Al-Nahrain Stage: 2nd College: Science Lecturer name: Alaa H. jawd Department: chemistry Academic Status: Course Instructor E_mail Title Course Code [email protected] Biochemistry CHEM 251 Type here course description Course Description This course about general bio chemistry Learning Outcome Type here course Textbook Type here textbook (title,author,edition,publisher,year) References Type here the reference (title,author,edition,publisher,year) Linger 2010 Course Assessment General Notes Term Tests 30 Laboratory Quizzes - 8 Assignments Final Exam 2 Type here general notes regarding the course Course weekly Outline week 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Topics Covered The structure of cells The chemistry of water acidsbases and buffers carbohydrate Monosaccharide and the optical activity Function of monosaccharide Amino sugars and sugars derivatives Oligosaccharides Polysaccharides Glycoprotein and glycolipids Amino acids and peptides Ionization reaction of amino acids Proteins Classification of proteins Denaturation and renaturation Identification of protein Instructor Signature: Lab. Experiment Assignments 40 University: Al-Nahrain Stage: : Second College: Science Lecturer name: Dr. Ahmed Abdulrazaq Ahmed Course Instructor E_mail Title Course Code Course Description Department: Chemistry Academic Status: Organic Chemistry [email protected] Organic Chemistry CHEM 231 Organic chemistry is a chemistry sub discipline involving the scientific study of the structure, properties, and reactions of organic compounds [(Aromatic compounds and benzene) (Arenes and derivatives) (polynuclear Aromatic compounds "Naphthalene" )] and other physical and chemical methods to preparation them and the mechanism for preparation and reaction for all of types. Learning Outcome Structures, Physical properties, Chemical properties, Reactions, Preparation, Mechanism (for all of types) Textbook "Principles of biochemistry", Lehninger, Third edition, worth publishers New york, 2004 1- Morrison & Boyd- Organic Chemistry References 2- Organic Chemistry 4th ed - Francis A. Carey Course Assessment General Notes 3- Organic Chemistry 4th ed - Paula Bruice Term Laboratory Quizzes Assignments Final Exam Tests 20% 15% 3% 2% 60% Course weekly Outline week Topics Covered 1 Aromaticity, Structure and stability of benzene 2 Aromatic character and the Hückel rule 3 Electrophilic aromatic substitution 4 Mechanism of nitration, mechanism of sulfonation, mechanism of halogenation, mechanism of Friedel-Crafts alkylation 5 mechanism of Friedel-Crafts acylation, Theory of reactivety 6 Theory of orientation 7 First Exam 8 Arenes Structure and Physical properties 9 Synthesis 10 Reactions 11 Second Exam 12 Polynuclear aromatic hydrocarbons (Naphthalene) Structure and Physical properties 13 Reactions 14 15 Synthesis Third Exam Instructor Signature: Lab. Experiment Assignments General instructions and Safety for organic chemistry laboratory Preparation of Cyclohexene Preparation of Acetylene Preparation of Cyclopentanone Preparation of n-Butyl bromide Complete the Experiment above Review for the four experiments above Preparation of Succinic anhydride Complete the Experiment above Preparation of Acetyl salicylic acid Preparation of Acetanilide Complete the Experiment above Preparation of Benzene diazonium chloride Complete the Experiment above Review for the four experiments above University: Al-Nahrain College: Science Department: Chemistry Stage: 2nd Lecturer name: Dr. Hilal Shahab Wahab Course Instructor E_mail Title Course Code Course Description Academic Status: Assistant Professor Assistant Professor Dr. Hilal Shahab Wahab [email protected] Physical Chemistry Chem 241 Chem 241 The course encompasses the principles of thermodynamics for ideal and real gases including first, second and third laws of thermodynamics in addition to the fundamental thermodynamics equations of states. Learning Outcome The properties of ideal gases and the essential laws which govern their behavior. Further, how the equation of states is related in terms of thermodynamic functions like enthalpy, entropy, Gibbs energy and internal energy. Moreover, how the properties of real gases differ from those of the perfect gases and construct an equation of state that describes their properties. Textbook Physical Chemistry/ P.W.Atkins and J. D. Paula / 9th edition / Oxford university press/ 2010 References Course Assessment General Notes 1-Laidler, K.J.; Meiser,J.H. and Sauctuary, B.C./ Physical chemistry/ 4th edition/ Houghton Mifflin Co. / N.Y. / 2003 2-Physical Chemistry/ P.W.Atkins/ 6th edition / Oxford university press/ 2001 Term Tests 15% Laboratory Quizzes 15% 5% Assignments Final Exam 5% The course introduces some basic ideas about fundamental thermodynamic processes like spontaneous, reversible, isothermal and adiabatic which it will be useful to know about before their applications. Course weekly Outline week 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Topics Covered Gas laws Gas laws Dalton’s law First law of thermodynamics Work Internal energy Enthalpy Heat capacity Thermochemistry Hess law Standard enthalpies Real gases Van der Waals approximation Second law of thermodynamics Touton’s rule Instructor Signature: 60% Lab. Experiment Assignments Safety measures Significant figures Density molar volumes Calorimetric Constant neutralization heat heat of solutionExams University: Al-Nahrain College: Science Lecturer name: Dr. Nasreen Raheem Jber Course Instructor E_mail Title Course Code Course Description Department: Chemistyr Stage: Fourth Academic Status: Assistance Professor Dr. Nasreen Raheem Jber [email protected] Spectroscopic identification of organic compounds. CHEM 431 Spectroscopy is the study of the interaction of matter and electromagnetic radiation. A continuum of different types of electromagnetic radiation constitutes the electromagnetic spectrum. High-energy radiation is associated with high frequencies, large wavenumbers, and short wavelengths. Infrared spectroscopy identifies the kinds of functional groups in a compound. NMR spectroscopy is used to identify the carbon–hydrogen framework of an organic compound. When a sample is placed in a magnetic field, protons aligning with the field are in the lower-energy -spin state; those aligning against the field are in the higher-energy -spin state The energy difference between the spin states depends on the strength of the applied magnetic field. Each set of chemically equivalent protons gives rise to a signal, so the number of signals in an1H NMR spectrum indicates the number of different kinds of protons in a compound. The chemical shift is a measure of how far the signal is from the reference TMS signal. The chemical shift ()is independent of the operating frequency of the spectrometer. The number of signals in a NMR spectrum tells how many different kinds of carbons a compound has. Carbons in electron-dense environments produce low-frequency signals; carbons close to electron-withdrawing groups produce high-frequency signals. Chemical shifts for NMR range over about 220 ppm, compared with about 12 ppm for NMR. NMR signals are not normally split by neighboring carbons, unless the spectrometer is run in a proton-coupled mode. Learning Outcome Textbook References Course Assessment General Notes identification of the structure of organic compounds using: 1- UV-Vis spectroscopy 2- Infra-red spectroscopy 3- Proton NMR spectroscopy 4- Carbon NMR spectroscopy Spectrometric identification of organic compounds; Robert M. Silverstein, Francis X. Webster, David J. Kiemle, seventh edition, John Wiley & Sons, Inc., 2005 Modern Spectroscopy, J. Michael Hollas, Fourth Edition, John Wiley & Sons, Ltd, 2004. Organic Chemistry, Paula Y. Bruice, Sixth edition, Pearson Education, Inc., 2011. Term Tests 13 Laboratory Quizzes 25 2 Assignments Final Exam 40 60 Course weekly Outline week Topics Covered Introduction to spectroscopy, types of 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 electronic transition, Chromophore and Auxochromen concept, solvent effect Woodward-fieser Rules for calculating absorption maximum in dienes Calculating absorption maximum in polydienes, and ,-unsaturated carbonyl compounds Calculating absorption maximum in benzene and derivatives Principle of infra-red spectroscopy, types of fundamental vibrations, factors influencing vibrational frequencies, instrumental. Finger print region, spectral features of some classes of organic compounds, hydrocarbons spectral features of carbonyl compounds spectral features of carboxylic compounds and its derivatives Mid Exam spectral features of amines, anilides, spectral features of nitro, nitriles, thiol Introduction to nuclear magnetic resonance, number of signals, chemical shift, factors influencing chemical shift, solvent used Peak area and proton coupling, splitting of the signals Chemical shift in 13CNMR Instructor Signature: Lab. Experiment Assignments Determination the physical properties of organic compounds. Determination of elements (sodium fussion) Solubility Identification of oxygen containing compounds Identification of nitrogen containing compounds unknown unknown unknown unknown unknown unknown unknown unknown University:AlNahrain College:Science Lecturer name:Dr.Ahmed Askar Course Instructor Email Title Course Code Course Description Learning Outcome Textbook References Department:Chemistry Stage:4th Academic Status:Assistant Professor Dr. Ahmed Asker Najaf [email protected] Geology 362/Geol 491 This course introduce the basics and fundamentals of Earth science focusing on all minerals ,crystal system and rock types .Also geology is an important topic for enable students for better understanding of the source of chemical elements and raw materials which are extracted from the earth . Open a new horizon for the students, and for more acquiring the new and update studies that related with applied sciences of various approaches of pure sciences. Physical Geology Physical Geology Norris W.Jones Charles E. Jones Sixth Edition-Mc Graw Hill Higher Education-2008 Course Assessment General Notes Term Tests 25 Laboratory Quizzes - 7 8 40 Geology and other sciences are major parts of our lives, and many of the daily decisions we make are affected in some way by science. This course is the linkage with the other sciences applying the physical, chemical, biological, and even computer sciences all together as a material science. Course weekly Outline week 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Instructor Signature: Assignments Final Exam Topics Covered Introduction Properties of Minerals Mineral Identification Crystals Igneous Rocks Mineral composition Classification and Identification Texture Sedimentary Rocks Erosion and Transportation Deposition and Lithification Metamorphic Rocks Types of Metamorphism Metamorphic Texture Zones of Metamorphism University:Al-nahrain Stage: Fourth year 1st semester College:Science Lecturer name:Dr.Khaleda H. Al-saidi Department:Chemistry Academic Status: Assistant professor Course Instructor E_mail Assistant professor Dr- Khaleda Hamid Al-Saidi [email protected] Title Course Coordinator Analytical Chemistry (Electro-analytical methods) CHM421 1- Electrochemical definitions and terminology, 2- Potentiometric methods , 3- Electro-gravimetric and Coulometric methods, 4- Voltammetry and polarography, 5- Conductometric methods First semester (analytical Chemistry) Course Description Learning Outcome Textbook References Course Assessment General Notes 1-Fundamentals of Analytical Chemistry Eighth Edition, 2009 By: Douglas A. Skoog, Donald M. West, F. James Holler, Stanley R. Crouch , pub. Brooks/Cole- Thomson Learning 10 Davis Drive Belmont, CA 94002 USA. 2-Principles of Instrumental Analysis Third edition By – Douglas A. Skoog, Saunders Golden Sunburst Series (Saunders college publishing New York 1984 1-Principle and Practice of Analytical Chemistry , F.W. Fifield and D. Kealey , 2nd edition , International Textbook company London , 1986 2- Modern Analytical Chemistry By David Harvey, International Edition coprint 2000, McGraw-Hill, USA. Some of journals. Term Tests Laboratory Quizzes Assignments Final Exam 25% 15 60% Electrochemical definitions and terminology, includes:Potentiometric methods, Electro-gravimetric and Coulometric methods, Voltammetry and polarography, Conductometric methods 1 week 1 2 3 4 5 6 7 8 9 10 11 12 Course weekly Outline Topics Covered 1- Electrochemical definitions and terminology Oxidation/Reductionin Electrochemical cells. , Types of Electrochemical cells., Reversible and irreversible cells., conducting in Electrochemical cells, galvanic and electrolyte cells The components of the cell Anode ., Cathode., Liquid junctions, salt bridge., The schematic Representation of cell., Electrode potentials. Examples and questions. Calculation of dissociation constant. Calculation of complex formation constant. Examples and questions. Calculation of solubility product constant. 2- Potentiometric methods a- Indicator electrodes, metallic electrodes first, second and third order e lectrodes b- Membrane electrodes, Alkaline and acid errors, pH electrode calibration methods. c- glass selective electrodes, selectivity of electrode and selectivity ratio d- Ion selective electrodes, glass, liquid membrane, solid - state, precipitate, gas sensing and Enzyme electrodes . Examples and questions. Types of reference electrodes. Calomel electrode. Double junction reference electrodes. Silver/silver Chloride electrodes. e- Instruments for potential measurement f- Potentiometers g- Direct reading instruments h- Analytical application Examples and questions. Calculation of dissociation constant. Calculation of complex formation constant. Calculation of solubility product constant. Examples and questions. i- External and standard addition methods j- Potentiometric titrations, conventional, first and second derivative plots for end point detections. 3- Electro-gravimetric and Coulometric methods a- Electrolysis and current- voltage relationships b- Constant current and constant potential electrolysis . Examples and questions c- Types of coulometric methods, constant potential coulometry d- Coulometric titration, neutralization, precipitation, complex formation, oxidation - reduction titration. . Examples and questions Examination 4- Voltammetry and polarography a- Description of polarographic measurements, polarographic cell, Dropping Mercury electrode, polarograms b- polarographic wave, residual current, limiting current, diffusion current, and half - wave potential. Examples and questions. c- Supporting electrolyte and current maxima suppressors d- Ilkovic equation and its analytical application 2 13 14 15 e- Voltammetry and related techniques. f- Amperometric titrations, titration curves, analytical applications, Examples and questions 5- Conductometric methods a- Electrolytic conductance, equivalent conductance b- conductance measurements, power sources, types of cells, cell constant c- Conductometric titrations, acid - base mixture titrations . Examples and questions . Review , Examples and questions., Examination Term Paper :Involve a preparation of a recent research article in own words Instructor Signature: Assistant professor Dr- Khaleda Hamid Al-Saidi 3
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