Diminishing fossil resources, increasing oil prices and numerous other drivers are rapidly forcing society to seek new, sustainable sources of carbon for future chemicals, energy and materials production. This module looks at the variables in this complex equation, from the design of a synthetic route, energy consumption, alternative feedstocks and engineering methods for efficient chemical production.
Pre-requisites: Chemistry / Chemical Sciences / other appropriate discipline undergraduate degree
Occurrence | Teaching period |
---|---|
A | Semester 1 2024-25 |
Diminishing fossil resources, increasing oil prices and numerous other drivers are rapidly forcing society to seek new, sustainable sources of carbon for future chemicals, energy and materials production. This module looks at the variables in this complex equation, from the design of a synthetic route, energy consumption, alternative feedstocks and engineering methods for efficient chemical production.
Analyse and use real examples to illustrate how the principles of green chemistry can be applied to chemical and pharmaceutical manufacturing.
Critically analyse the changing trends in raw material utilisation and to understand the potential of alternative feedstocks.
Evaluate engineering methods for improving process efficiencies
Calculate and critically evaluate the mass and energy balance in a chemical production process
Critically analyse, discuss and the importance of energy efficiency and the range of energy sources, both economically and in terms of impact on climate change
Demonstrate a high level of practical ability in the design and execution of green chemical processes
Have an excellent knowledge of how biomass can be used as a feedstock for future production industries
The specific module learning outcomes map onto the following Programme Learning Outcomes
PLO 1: Apply whole systems thinking and inter/trans-disciplinary approaches to the creative problem solving of complex global grand challenges using holistic green chemistry and sustainable industrial technology related interventions in concert with the United Nations Sustainable Development Goals (UN SDGs)
PLO3: Effectively communicate detailed, complex, green and sustainable chemistry research concepts to both experts and non-experts through the application of a variety of key transferable skills such as IT, scientific writing, oral presentations, posters, team-working,etc
PLO5: Critically evaluate the environmental impact and sustainability of chemical processes and products, through the use of relevant metrics and whole systems thinking.
Topics in this module:
Clean Synthesis
Sustainable Industrial Technologies and Processes
Renewable Resources
Task | % of module mark |
---|---|
Essay/coursework | 30 |
Essay/coursework | 30 |
Essay/coursework | 40 |
None
Task | % of module mark |
---|---|
Essay/coursework | 30 |
Essay/coursework | 30 |
Essay/coursework | 40 |
Students receive written feedback from each assessment
General Background
Green Chemistry: An Introductory Text
M. Lancaster, Royal Society of Chemistry, Edition 3 2016, Print ISBN 978-1-78262-294-9, ePub eISBN 978-1-83916-294-7
Handbook of Green Chemistry, Green Processes, Designing Safer Chemicals
P. Anastas and P. Trevorrow, 2013, ISBN 3527326391
Green Chemistry Metrics: Measuring and Monitoring Sustainable Processes
A. Lapkin and D. Constable, 2008, ISBN 9781405159685
Sustainable Solvents: Perspectives from Research, Business and International Policy (Green Chemistry Series)
J. H. Clark, A. Hunt, C. Topi, G. Paggiola and J. Sherwood, 2017, ISBN 1782623353
Sustainable Catalysis (Green Chemistry Series)
M. North, J.H. Clark, 2015, ISBN 1782620583
Alternative Energy Sources for Green Chemistry (Green Chemistry Series)
G. Stefanifis, A. Stankiewicz, J.H. Clark, A. de la Hoz, J. Fan, R. Mato Chain, J. Santamaria, 2016 ISBN 1782621407
Green Chemistry for Surface Coatings, Inks and Adhesives: Sustainable applications (Green Chemistry Series)
R. Höfer, A.S. Matharu, Z. Zhang. 2019, ISBN 9781782629948