Undergraduate Programme and Module Handbook 2011-2012 (archived)
Module CHEM3051: MATERIALS CHEMISTRY
Department: Chemistry
CHEM3051:
MATERIALS CHEMISTRY
| Type |
Open |
Level |
3 |
Credits |
20 |
Availability |
Available in 2011/12 |
Module Cap |
None. |
Location |
Durham
|
Prerequisites
- Core Chemistry 2 (CHEM2012) AND EITHER Core Chemistry 1B (CHEM1022) OR Core Mathematics A (MATH1012) OR Single Mathematics A (MATH1561) OR Maths for Engineers & Scientists (MATH1551).
Corequisites
- Core Chemistry 3 (CHEM3012).
Excluded Combination of Modules
- Core Chemistry 2 (CHEM2012).
Aims
- To apply chemical principles to the design and evaluation of materials with technological potential.
Content
- Inorganic materials and characterisation: structural properties; electronic materials.
- Organic materials.
- Electronic structure of solids: theory and applications.
- Diffraction.
- Two assignments.
Learning Outcomes
- Appreciate and describe structural features of non-stoichiometric compounds, interstitial compounds, intercalates, high temperature superconductors and zeolites; relating these structures to specific chemical, electrical, optical and magnetic properties;
- explain the role that organic synthetic methods play in the synthesis of unconventional and novel molecules;
- describe the functional groups required in a molecule to obtain specific opto-electrical properties and explain the requirements for speciality polymers;
- describe the electronic structure of solids in terms of band theory and use this theory to explain the electrical properties of insulators, semiconductors and metals; explain the origin of electronic, magnetic, optical and thermal properties of solids;
- explain the application of various techniques for probing solids and polymers; identify characterisation techniques for elucidating structure at different length-scales; interpret and combine data from different techniques; describe hierarchical structures in solids and polymers;
- use crystallographic concepts, such as symmetry elements and Miller indices, to describe crystal structures and to apply diffraction theory to structural problems.
- Demonstrate problem solving skills and be able to work confidently with experimental data.
Modes of Teaching, Learning and Assessment and how these contribute to
the learning outcomes of the module
- Lectures are used to convey concepts and are examined by written papers. This is thought to be the best method to assess the knowledge of the students.
- Workshops are larger groups of students where problems are considered and common difficulties shared. This ensures that students have understood the work and can apply it to real life situations. These are formatively assessed.
- At the end of each of the Michaelmas and Epiphany Terms, each student will be given a two hour period to evaluate experimental or theoretical data about a substance or system of interest. This develops problem solving skills in a limited time period.
Teaching Methods and Learning Hours
| Activity |
Number |
Frequency |
Duration |
Total/Hours |
|
| Lectures |
37 |
3 per week |
1 Hour |
37 |
|
| Workshops |
6 |
2 per Term |
1.5 Hour |
9 |
■ |
| Assignment |
2 |
1 per Term |
2 Hour |
4 |
■ |
| Preparation and Reading |
|
|
|
150 |
|
| Total |
|
|
|
200 |
|
Summative Assessment
| Component: Examination |
Component Weighting: 80% |
| Element |
Length / duration |
Element Weighting |
Resit Opportunity |
| Written examination |
3 hour |
100% |
|
| Component: Assignments |
Component Weighting: 20% |
| Element |
Length / duration |
Element Weighting |
Resit Opportunity |
| Problem-solving assignment 1 |
|
50% |
|
| Problem-solving assignment 2 |
|
50% |
|
Set work, usually in preparation for seminars and workshops.
■ Attendance at all activities marked with this symbol will be monitored. Students who fail to attend these activities, or to complete the summative or formative assessment specified above, will be subject to the procedures defined in the University's General Regulation V, and may be required to leave the University
