PHY3222 2023-2024 - Module Description

PHY3222	Energy, Materials and Sustainability	2023-24
	Dr S.M. Strawbridge and Dr K. Papadopoulou

Delivery Weeks:	T2:01-11
Level:	6 (NQF)
Credits:	15 NICATS / 7.5 ECTS
Enrolment:	30 students (approx)

Description

This module will allow you to develop a critical, scientific, and pragmatic understanding of the role energy and materials can play in building a sustainable future. The module will emphasise the relationship human activity has with our only finite resource, the Earth. The environmental and societal impacts of acquiring energy and primary resources required to survive as a species will be explored. We will discuss the costs and limitations of manufacturing using more sustainable materials on a planet with finite resources. You will gain a strong background in renewable energy generation and new materials to help build a sustainable future.

Module Aims

This module will provide you with: A global perspective of our total energy and resource needs now and in the future. An overview of established energy sources. An overview of renewable energy sources including photovoltaics, wind, and wave power An overview of how these more sustainable technologies can help reduce our dependence on fossil fuels, and the environmental implications of the move to renewable energy sources.

In addition, the module will enable you to: Investigate the current and potential future energy storage technologies including batteries and demands on raw materials needed for the manufacture. Discuss ways to reduce energy demand. Discuss energy inequality in a global context. Critically assess the costs and benefits of various energy supply scenarios

Intended Learning Outcomes (ILOs)

A student who has passed this module should be able to:

Module Specific Skills and Knowledge:
1. Describe the impact of energy generation currently and in the future
2. Outline the principles of established and new energy-generating techniques and critically assess their advantages and disadvantages
3. Understand the need to not just generate energy but to store energy on scale and reduce energy demand.
4. Understand how more sustainable materials can help tackle the climate change challengeinvestigate areas of physics in a systematic way using appropriate experimental and/or theoretical techniques;
Discipline Specific Skills and Knowledge:
1. Understand local and global demand for resources
2. Analyse data regarding energy generation and consumption
3. Understand key components of energy systems
4. Critically assess new energy-generating and energy storage techniques and sustainable materialsresearch and write background material;
Personal and Key Transferable / Employment Skills and Knowledge:
1. Communicate ideas effectively through written and oral means
2. Undertake independent study and build time management skills
3. Identify, and evaluate data from a variety of sources
4. Prepare and present information via a range of media
5. Work effectively and constructively in a team environment
6. Have a professional and yet personal position on ideas and actions regarding the role of energy and materials in building a sustainable future.organise a programme of work

Syllabus Plan

Whilst the module's precise content may vary from year to year, it is envisaged that the syllabus will cover some or all of the following topics:

Current and future energy demand

Finite energy sources (fossil fuels)

Sustainable energy sources (solar, wind and wave power, geothermal, hydroelectric, nuclear power, organic matter/biofuels, hydrogen as clean fuel) Environmental Impacts of Energy Production (acid rain, stratospheric ozone depletion etc).

Emissions Reduction and Waste Management

Physics of new energy storage materials/battery technologies (graphene, MAX phases, MXenes, thermoelectrics) including simulation methods in materials physics The energy and materials transition

Urban sustainability, and challenges and opportunities for sustainable energy generation

Learning and Teaching

Learning Activities and Teaching Methods

Description	Study time	KIS type
20×1-hour Lectures, guest lectures, discussions	20 hours	SLT
Approx. 2×1-hour workshops troubleshooting individual and group projects	2 hours	SLT
Individual Report and Group Project	80 hours	GIS
Reading and private study	48 hours	GIS

Assessment

Weight	Form	Size	ILOS assessed	Feedback
0%	Class discussions	Weekly	1-14	Verbal discussion in class
80%	Individual report	4000-words	5,7,8-12,14	Written feedback
20%	Group project and presentation (3 to 4 students per group)	15 minutes	1-14	Written feedback and oral feedback

Notes: Refer to the detailed description of the BSc Final Year Group Projects assessment criteria in the Physics Handbook.

Resources

The following list is offered as an indication of the type & level of information that students are expected to consult. Further guidance will be provided by the Module Instructor(s).

Core text:

Not applicable

Supplementary texts:

Not applicable

ELE:

http://newton.ex.ac.uk/redirects/ELE/PHY3222

Further Information

Prior Knowledge Requirements

Pre-requisite Modules	none
Co-requisite Modules	none

Re-assessment

Re-assessment is not available except when required by referral or deferral.

Original form of assessment	Form of re-assessment	ILOs re-assessed	Time scale for re-assessment
Individual report	Individual report (4000 words)	5,7,8-12,14	Submission in Ref/Def period
Group project and presentation (3 to 4 students per group)	15 minute narrated PowerPoint on reassessment topic	1-14	Submission in Ref/Def period

KIS Data Summary

Learning activities and teaching methods
SLT - scheduled learning & teaching activities	22 hrs
GIS - guided independent study	128 hrs
PLS - placement/study abroad	0 hrs
Total	150 hrs

Summative assessment
Coursework	100%
Written exams	0%
Practical exams	0%
Total	100%

Miscellaneous

Availability	unrestricted
Distance learning	NO
Keywords	Energy, Materials, Sustainability, Resources.
Created	14-Mar-23
Revised	24-Mar-23