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 Academic Year: | 2016/7 |
| Owning Department/School: | Department of Chemistry |
| Credits: | 12 [equivalent to 24 CATS credits] |
| Notional Study Hours: | 240 |
| Level: | Certificate (FHEQ level 4) |
| Period: |
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| Assessment Summary: | EX 100%, OT 0% |
| Assessment Detail: |
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| Supplementary Assessment: |
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| Requisites: |
In taking this module you cannot take CH10138 . You must have A level Chemistry or equivalent to take this unit. |
| Description:
| Aims: To introduce the basic concepts of physical chemistry upon which understanding of modern chemistry depends. These include the principles governing chemical processes in terms of thermodynamic properties, the measurement and analysis of reaction rates, chemical equilibria, phase behaviour, molecular spectroscopy and basic quantum mechanics. Learning Outcomes: After studying this unit, students should be able to: * Describe simply the role of thermodynamics, kinetics and spectroscopy in chemistry * Discuss the fundamental ideas lying behind thermodynamics, kinetics and spectroscopy and how they can be used to interpret chemical behaviour * Perform qualitative and quantitative analyses of and solve problems involving thermodynamic and kinetic concepts and data. * Solve numerical problems in of thermodynamics, kinetics and spectroscopy * Apply some basic mathematical methods to the solution of chemical problems. Skills: Numeracy (F, A), Problem solving (T, F, A), Oral communication (F). Content: * The world of gases: ideal and non-ideal gases. Intermolecular forces: vapours, liquids and solutions. First law of thermodynamics and thermochemistry: energy changes in chemical reactions. Entropy and free energy. * Reaction kinetics, stoichiometry, molecularity; reaction rate and order: half-life; integrated rate equations. * Experimental methods in reaction kinetics. Arrhenius equation. Consecutive reactions; intermediates; rate limiting steps; chain reactions; catalysis. * Calculation of changes in U, H, S, G under a range of temp., pressure and composition conditions. Le Chatelier principle. Relation between Gibbs free energy and equilibrium constants with examples drawn from chemical reactions, redox and electrochemical processes. * Energy levels and molecular speeds in gases, Boltzmann equation,. Relationship between rate and equilibrium constants. * Phase behaviour of solids, liquids and gases. Qualitative and quantitative characterisation of phase transitions. Emphasis will be placed on the solution of a range of types of problems. * UV/visible spectrophotometry. Vibrational spectroscopy. Linear diatomic and polyatomic molecules. IR spectra of functional group containing compounds. Rotational spectroscopy; rigid rotor model. Vibration-rotation spectroscopy. |
| Programme availability: |
CH10137 is Compulsory on the following programmes:Department of Chemistry
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Notes:
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