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DEGREE REGULATIONS & PROGRAMMES OF STUDY 2014/2015
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DRPS : Course Catalogue : School of Chemistry : Chemistry

Undergraduate Course: Chemistry 3A (CHEM09005)

Course Outline
School	School of Chemistry	College	College of Science and Engineering
Credit level (Normal year taken)	SCQF Level 9 (Year 3 Undergraduate)	Availability	Available to all students
SCQF Credits	40	ECTS Credits	20
Summary	Chemistry 3A consists of the following lecture courses under the theme of characterisation of molecules, matter, and reactions: molecular symmetry and electronic structure; molecular spectroscopy; nuclear magnetic resonance spectroscopy; phases and interfaces; reaction kinetics; statistical thermodynamics; structure and bonding; X-ray crystallography. When taken in combination with Chemistry 3B and Chemistry 3P, this course forms part of the prescribed third year curriculum for students on degrees in Chemistry, Chemistry with Environmental & Sustainable Chemistry, Chemistry with Materials Chemistry, and Medicinal and Biological Chemistry (including the With Industrial Experience, With Year Abroad, and With Management variants of these programmes).
Course description	Not entered

Entry Requirements (not applicable to Visiting Students)
Pre-requisites	Students MUST have passed: Chemistry 2 (CHEM08019) AND Mathematics for Science and Engineering 1a (MATH08060) AND Mathematics for Science and Engineering 1b (MATH08061)	Co-requisites
Prohibited Combinations	Students MUST NOT also be taking Chemical Physics 3S1 (CHPH09007) OR Chemical Physics 3S2 (CHPH09006)	Other requirements	Direct entrants with mathematics qualifications recognised as being equivalent to a pass in the Year 1 Mathematics for Scientists and Engineers 1a & 1b courses are exempted from the formal passes in Year 1 mathematics courses.

Information for Visiting Students
Pre-requisites	None

Course Delivery Information

Academic year 2014/15, Available to all students (SV1)		Quota: None
Course Start	Full Year
Timetable	Timetable
Learning and Teaching activities (Further Info)	Total Hours: 400 ( Lecture Hours 60, Seminar/Tutorial Hours 33, Online Activities 4, Feedback/Feedforward Hours 2, Summative Assessment Hours 9, Programme Level Learning and Teaching Hours 8, Directed Learning and Independent Learning Hours 284 )
Assessment (Further Info)	Written Exam 100 %, Coursework 0 %, Practical Exam 0 %
Additional Information (Assessment)	2 x 3 hour exams.
Feedback	Not entered
Exam Information
Exam Diet	Paper Name		Hours & Minutes
Main Exam Diet S2 (April/May)	Paper 1		2:30
Main Exam Diet S2 (April/May)	Paper 2		2:30
Resit Exam Diet (August)	Paper 1		2:30
Resit Exam Diet (August)	Paper 2		2:30

Learning Outcomes
By the end of this course, students will be able to: * Assign molecules to point groups and use symmetry properties to predict vibrational spectra and describe atomic and molecular orbitals. * Understand the basis of spectroscopic selection rules and of experimental spectroscopic methods. * Interpret the electronic behaviour of transition metal coordination compounds, and have a basic understanding of ESR spectroscopy. * Understand a range of analytical electrochemical techniques. * Demonstrate a detailed knowledge of the factors which determine the energies, intensities, and linewidths of the transitions observed in molecular rotation, vibrational and electronic spectra. * Understand the principles of NMR spectroscopy, and undertake structural and stereochemical interpretation from 1D and 2D NMR spectra. * Draw and interpret phase diagrams, and understand the thermodynamics of phase transitions in terms of the behaviour at the interfaces between phases. * Understand the basic concepts of biological catalysis by enzymes. * Show proficiency in the quantitative analysis of kinetic data and the ability to relate a theoretical reaction mechanism to an experimentally determined rate law. * Know how to calculate thermodynamic properties using the Boltzmann distribution and partition function. * Explain the bulk properties of substances in relation to the structure of their constituent molecules. * Predict the structure of the ground state, electronically excited states, and the ionic states of small molecules using molecular orbital theory. * Use the Huckel Approximation to describe the electronic structure of large molecules, extend it to the band structure of solids and rationalise their electronic conductivity and spectroscopic properties. * Understand how crystal structures are obtained, and the relationship between the diffraction pattern measured from a crystal and the crystal structure.

Reading List
None

Additional Information
Graduate Attributes and Skills	Not entered
Additional Class Delivery Information	Plus tutorials at times to be arranged
Keywords	C3A

Contacts
Course organiser	Dr Philip Camp Tel: (0131 6)50 4763 Email: Philip.Camp@ed.ac.uk	Course secretary	Mrs Moira Wilson Tel: (0131 6)50 4754 Email: Moira.Wilson@ed.ac.uk

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