CH416-15 Energy

Department: Chemistry
Level: Undergraduate Level 4
Module leader: Ross Hatton
Credit value: 15
Module duration: 10 weeks
Assessment: 20% coursework, 80% exam
Study location: University of Warwick main campus, Coventry

Introductory description

A transformation in the way that we produce and use energy has just begun that is going to unfold over the next 2-3 decades, motivated primarily by the urgent need to address the threat posed by climate change. Following an introduction to the wider context, the chemistry of a series of technologies, spanning energy generation, energy storage and energy use will be discussed.

Module web page

Module aims

To provide an overview of the science that underpins key renewable energy generation and storage technologies.
To show how materials chemistry is playing a critically important role in the advancement of emerging energy technologies.
To connect the science in this area with broader environmental, economic, social and policy issues.
To develop student critical thinking and communication skills by giving a short talk critically evaluating the scientific literature in a cutting edge area of energy materials research.

Outline syllabus

This is an indicative module outline only to give an indication of the sort of topics that may be covered. Actual sessions held may differ.

Introduction to the wider context: climate change, sustainability and energy security and
the central role chemists/materials scientists will play in addressing the challenges in this area.
Advanced concepts in solid state chemistry building on years 1 and 2: direct/indirect
semiconductors, molecular semiconductors, excitons etc.
The solar resource; semi-conductor p-n junctions applied to photovoltaics (PV); the
motivation for reverting to thin film PV; operational principles behind perovskite PV, dye-
sensitised PV and organic PV (three disruptive classes of emerging PV technologies) and an
explanation as to why these cells operate differently to a conventional pn junction PV. Key
advances in materials development.
Fuel cells; basic principles of catalytic operation; proton exchange fuel cells; oxygen ion
exchange fuel cells; key materials issues.
Solid state batteries; electrochemical principles, different types of batteries (primary,
secondary); alkaline and lithium ion batteries; key materials issues.
Inorganic materials for batteries, solid-oxide fuel cells and electrocatalysis
Hydrogen; methods of generation (e.g. photoelectrolysis and chemical); importance of
storage and transport; importance of new materials (e.g. porous framework materials).
Bioenergy; biomass as a fuel; bioenergy sources including crops and waste; production of
gaseous and liquid fuels from biomass.

Learning outcomes

By the end of the module, students should be able to:

Appreciate the connection behind the science and technology of energy, and environmental, economic, social and policy issues.
Appreciate the complexity of the renewable energy challenge and the central role that chemists do/will play in this growing area.
Understand the underpinning science behind the operation of different types of photovoltaic device, particularly leading emerging photovoltaic technologies.
Understand the underlying principles behind different types of fuel cell.
Understand the underlying principles behind the operation of solid state batteries.
Understand the underlying principles behind bioenergy and the use of biomass for biofuels.
Understand the underlying principles and challenges in the area of hydrogen storage.

Indicative reading list

-Introductory Nanoscience Physical and Chemical Concepts / Masaru Kuno London and New York : Garland Science 2012.
-Polymer electronics [electronic resource] / edited by Hsin-Fei Meng. Singapore : Pan Stanford Publishing, c2013.
-A Comprehensive guide to Solar Energy Systems [electronic resource] Elsevier Academic Press, Chapter 12 Organic Photovoltaics
-“Biofuels” eds. W. Soetert, E.J. Vandamme, Wiley, 2009

Research element

Research topic for oral presentation

Interdisciplinary

Spans physical, materials, organic and inorganic chemistry.

Subject specific skills

Problem solving
Critical thinking
Oral communication
Teamwork
Information literacy and research skills

Transferable skills

Problem solving
Critical thinking
Oral communication
Teamwork
Information literacy and research skills

Study time

Type	Required
Lectures	24 sessions of 1 hour (16%)
Practical classes	(0%)
Other activity	6 hours (4%)
Private study	105 hours (70%)
Assessment	15 hours (10%)
Total	150 hours

Private study description

N/A

Other activity description

2 x 1 hour guest lecture (included in total number of lectures) The purpose of the guest lectures will be to enhance the learning experience rather than add to the amount of directly assessed material. The aim is to give a different perspective on some of the topics covered during the internally delivered lectures
3 x 1 hour example workshops
3 x 1 hour revision workshops

Costs

No further costs have been identified for this module.

You do not need to pass all assessment components to pass the module.

Assessment group D2

	Weighting	Study time	Eligible for self-certification
Assessment component
Presentation	20%	15 hours	No
A 12 minute presentation done in pairs (approximately 6 minutes each) plus 5 minutes questions, in front of two academics and the rest of the CH416 cohort. Student pairs assigned a topic to research and present on (examples below) as a pair. Findings presented in the form of an oral presentation that can be understood and is interesting to a 3rd year undergraduate audience. This will be followed by 5 minutes allocated for questions. There is a penalty for going over time. The presentation must make reference to the primary scientific literature. Assessed on presentation content/planning, presentation delivery and your responses to questions. Examples of presentation topics (which change each year) Sodium-ion batteries Explain why there is growing interest in the development of sodium-ion batteries AND outline the current status and key research challenges in this exciting field. As a starting point see ‘A battery technology worth its salt’ Chemistry World, 16 (11) 2019, 48. Carbon neutral synthetic fuels from sunlight It is possible to use sunlight to produce hydrocarbon fuels. Explain why there is growing interest in this approach AND outline the current status and key research challenges in this nascent field. As a starting point see ‘Solar made hydrocarbon fuels’ Materials World 27(10) 2019, 37
Reassessment component is the same
Assessment component
Online Examination	80%		No
~Platforms - AEP Online examination: No Answerbook required
Reassessment component is the same

Feedback on assessment

Individual feedback on presentations and cohort level examination feedback provided via
Moodle.

Past exam papers for CH416

Pre-requisites

To take this module, you must have passed:

All of

CH273-15 Properties of Solutions and Foundations of Electrochemistry and Statistical Mechanics

Anti-requisite modules

If you take this module, you cannot also take:

CH3F7-15 Energy

Courses

This module is Optional for:

UCHA-F110 Undergraduate Master of Chemistry (with Industrial Placement)
- Year 4 of F110 MChem Chemistry (with Industrial Placement)
- Year 4 of F112 MChem Chemistry with Medicinal Chemistry with Industrial Placement
Year 5 of UCHA-F107 Undergraduate Master of Chemistry (with Intercalated Year)
UCHA-F109 Undergraduate Master of Chemistry (with International Placement)
- Year 4 of F109 MChem Chemistry (with International Placement)
- Year 4 of F111 MChem Chemistry with Medicinal Chemistry (with International Placement)
UCHA-4M Undergraduate Master of Chemistry Variants
- Year 4 of F105 Chemistry
- Year 4 of F110 MChem Chemistry (with Industrial Placement)
- Year 4 of F109 MChem Chemistry (with International Placement)
- Year 4 of F125 MChem Chemistry with Medicinal Chemistry
Year 5 of UCHA-F127 Undergraduate Master of Chemistry with Medicinal Chemistry(with Intercalated Year)