Chemistry MChem
2025-26 entryPrepare to work as a researcher in the chemical industry, or to go on to a PhD and an academic career. Over four years, you'll do research training and spend most of your final year working on your own project as part of a team of professional scientists.
Key details
- A Levels AAB
Other entry requirements - UCAS code F105
- 4 years / Full-time
- September start
- Accredited
- Find out the course fee
- Optional placement year
- Study abroad
Explore this course:
Course description
Why study this course?
This course is accredited by the Royal Society of Chemistry for fully meeting the academic criteria for Chartered Chemist (CChem).
Most of the people teaching you will have first-hand experience of industry and business processes, and running spin-out companies.
You’ll learn laboratory skills and techniques in your first and second year in our teaching labs. In your final year, you’ll work on a research project giving you independent research experience working on a real scientific problem. You’ll conduct experiments in our multi-million pound research labs, learning from our academic researchers.
At ºù«Ӱҵ we have a major focus on sustainability. Sustainability modules are part of our core teaching in all our undergraduate courses from the start, and are also available as in-depth specialised options in year three.
We offer a guaranteed summer research placement if you meet the requirements of our Undergraduate Research Scholarship scheme.
Four years of advanced study and hands-on experience will give you the skills of a forward-thinking 21st-century chemist, ready to start your career as a researcher.
The four-year Chemistry MChem degree at the University of ºù«Ӱҵ is the best route if you’re planning your career in scientific research, a PhD and an academic career. Accredited by the Royal Society for Chemistry, this MChem builds from fundamentals to a final year spent mostly working on your own project, as part of a team of research scientists.
Sustainability modules are part of our core teaching, and you’ll learn about this right from the start. And just like our Chemistry BSc, the first two years will be about the concepts and skills you need to eventually unlock a host of advanced topics in your third year.
Your lectures are supported by small group tutorials, where you can delve deeper into complex topics. These small group teaching sessions are led by your personal tutor in first year, and specialists in years two and three, when you’ll explore chemistries environmental, computational, biological and medicinal – plus advanced materials and nanotechnology.
In the fourth year you will have an opportunity to develop your research skills through advanced study, and in a research project – where you’ll join a team working on new discoveries, before graduating, primed for an exciting career.
Accredited by the Royal Society of Chemistry for fully meeting the academic criteria for Chartered Chemist (CChem)
Modules
A selection of modules are available each year - some examples are below. There may be changes before you start your course. From May of the year of entry, formal programme regulations will be available in our Programme Regulations Finder.
Choose a year to see modules for a level of study:
UCAS code: F105
Years: 2023, 2024
In your first year, you'll spend a day a week in the lab, learning essential skills and techniques. You will study topics including the structure of atoms and molecules, how and why chemical reactions happen, and how to identify and analyse different compounds. You'll also look at biological processes that are underpinned by chemistry, and the critical role that chemistry plays in ensuring a sustainable future.
Core modules:
- Chemistry in a Sustainable Future
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Chemistry has a crucial role to play in creating a sustainable world. This module looks at the contributions chemists can make to society, with a particular focus on sustainability and green chemistry. Students will learn where everyday essentials including food and energy come from, and how chemistry can help combat global warming by, for example, making the transition from fossil fuels to renewable energy sources and feedstocks possible. To make the biggest impact on society, students will learn how to explain scientific concepts to a range of audiences by working in groups to produce articles, infographics and other content.
10 credits - Fundamentals of Chemistry
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This is the first module that all of our undergraduate students take, and takes up most of the first year. It covers the fundamental concepts behind the four main branches of chemistry (organic, inorganic, physical and analytical), and teaches practical skills that every chemist needs. Themes include the structure of atoms and molecules, how chemical reactions happen, and how to identify and analyse different chemicals and elements. Topics are covered in lectures, workshops, small group tutorials and in the laboratory.
80 credits - Essential Skills for Chemists
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This module provides first year chemistry students with the broader academic and professional skills required to study chemistry at degree level. The module includes fundamental physics and mathematics, data analysis, computing skills, and searching and using the scientific literature. Students will also undertake a group project on the standards and values expected of a professional chemist.
20 credits
The module has been designed to introduce students to varied methods of learning and teaching used throughout the programme including online self-led activities, lectures and group work.
Optional modules:
A student will take 10 credits (one module) from this group.
- Chemistry in the Biological World Around Us
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Chemistry is the backbone of fundamental biological processes, from healthcare and medicine to countless other features of modern life. This module brings together the four main branches of chemistry (organic, inorganic, physical and analytical) to explain the principles behind the biology we experience in our day-to-day lives. Examples of the kinds of topic that will be described are medicine, nutrition, the molecules that have defined modern biology, and studies of molecules that have shaped and changed the biological world.
10 credits - Chemistry in the Physical World Around Us
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Many of the technologies, products and structures we take for granted in our everyday lives rely on chemistry. This module brings together the four main branches of chemistry (organic, inorganic, physical and analytical) to explain the chemical principles of the world around us. Examples of the kinds of topic that will be described are the chemistry of explosives, molecules that glow, toiletries, cosmetics, laundry and foodstuffs.
10 credits
In your second year, you'll spend two days a week in the lab, as you learn to run more complex experiments. You'll move on to study more advanced topics in organic chemistry (reactions of functional groups, synthesis, biopolymers), inorganic chemistry (main group compounds, transition metal coordination complexes, inorganic solids) and physical chemistry (quantum mechanics, thermodynamics, polymers and colloids).
Core modules:
- Enterprise and Employability
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This module focuses on the ways that chemistry can be applied in business, and for the benefit of society as a whole. Students will analyse and discuss examples of successful and unsuccessful commercial endeavours to learn, for example, how new drugs have been discovered while others have failed. They will then be introduced to the process of developing a business and, working in small groups, students, will develop and present their own idea for a business based on an area of chemistry that they have chosen. As part of this module, students also attend our annual Careers Day, where chemistry students can explore career options and meet with employers who hire chemistry graduates.
10 credits - Environmental, Analytical & Sustainable Chemistry
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Chemistry - in terms of both natural processes and artificial phenomena - has a clear impact on the environment. This module will look at some of ways chemicals interact with the environment, and explore how we can measure the sustainability of a chemical process and potentially improve its green credentials. In this context, students will expand their analytical chemistry skills and their ability to determine structures of compounds. This includes looking at how mixtures of compounds can be separated and how the proportions of their components can be determined. In the lab, students design and conduct their own experiments to investigate a real chemical problem from the world around us.
20 credits - Inorganic Chemistry: Structure, Bonding & Reactivity
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This module is designed to deepen students' understanding of inorganic chemistry, including main group compounds, transition metal coordination complexes and inorganic solids. Students will learn how symmetry principles can be used to explain molecular structure and bonding using molecular orbital theory as well as to analyse the structures of highly ordered crystals. Spectroscopy techniques are taught so that students can learn how to characterise inorganic compounds, while studying the different reactions and properties that these chemicals display. In the lab, students develop their practical skills by synthesising and characterising inorganic compounds, safely and efficiently.
30 credits - Physical Chemistry and Polymer Science
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Chemical structures are based on a number of important physical principles. This module builds up students understanding of the theory behind physical and chemical phenomena. Students will use quantum mechanics to examine the structure and properties of atoms and molecules, and the laws of thermodynamics are used to explain the properties of mixtures and equilibria. Polymers are also introduced and students learn how to prepare and characterise these compounds, which are behind many familiar products and technologies. The theory behind common spectroscopic techniques that are used to investigate molecular structures are also covered. In the lab, students get more experience of the techniques chemists use to gather and analyse data from chemical processes and determine the properties of different materials.
30 credits - Synthetic, Mechanistic and Biological Aspects of Organic Chemistry
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This module builds on students' knowledge of the common functional groups within organic molecules that are responsible for many chemical reactions including aromatic rings, alkenes and carbonyls. Several classes of chemical reactions are studied in detail, with a focus on understanding the mechanisms behind them. Students also learn how to design synthetic routes to prepare molecules. Students will look at biological systems from a chemical perspective, including the structures and functions of biopolymers such as proteins and DNA. In the lab, students further develop the practical skills needed to carry out synthetic organic chemistry, in a safe and efficient manner.
30 credits
In your third year, you'll work on a research project. You'll gather and evaluate data, run your own experiments and present your findings. You'll have a wide range of optional modules to choose from too, with topics ranging from energy storage to chemistry in space.
Core modules:
- Organometallic, Solid State and Coordination Chemistry
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This module will continue to develop students' knowledge and skills in inorganic chemistry, dealing with the properties of compounds in both solution and the solid state. It will cover the synthesis, structures and reactivity of organometallic compounds and their important role in catalysis, along with structural, photophysical and magnetic properties of coordination compounds. The principles of crystallographic structure determination are introduced, with a focus on single crystal X-ray diffraction. Practical work in the lab focuses on developing experimental skills in the study of inorganic compounds, using contemporary synthetic and analytical methods.
20 credits - Chemistry Employability Skills and Projects
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This module is designed to give students more of the practical and transferable skills they need for a career in chemistry, and many graduate jobs. Students systematically gather data from scientific literature and other sources, to practice evaluating and presenting complex information. Work is done independently and in groups, with lots of opportunities for students to reflect on their work and get feedback from their teams. In the lab, students develop their practical skills through an independent chemistry research project.
30 credits - Mechanisms, Pericyclic Reactions and Synthesis
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This module expands students' understanding of organic chemistry. It covers how applications of frontier orbital theory inform on reactivity and how reaction mechanisms are investigated. Synthetic organic chemistry is developed further, with a focus on aromatic and heterocyclic systems and the application of transition metal-mediated cross coupling reactions. Students will learn about key scientific studies in organic chemistry, and put new concepts into practice in our advanced teaching laboratory.
20 credits
- Statistical Thermodynamics, Spectroscopy, Surfaces, Colloids
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This module introduces more advanced concepts in physical chemistry. Students will learn to apply a statistical approach to thermodynamics, explore electronic excited states, and discover the fundamental principles of chemistry at surfaces . Bulk thermodynamic properties will be understood in terms of the properties of individual molecules, allowing equilibrium constants and gas-phase reactions to be calculated from first principles. Electronic levels in polyatomic molecules are studied, to show how spectroscopy provides information on changes in molecular structures, and on the lifetimes of excited states. Students are introduced to the chemistry of colloids and surfaces, including experimental methods for studying adsorption and thermodynamics at gas-solid and liquid-solid interfaces, the role of surface chemistry in heterogeneous catalysis, and the fundamental principles that control the stability and properties of colloidal systems.
20 credits
Optional modules:
A student will take 30 credits (three modules) from this group.
- Chemistry in Space
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The Universe was long considered to be a vast, mostly empty, expanse. Astronomers now know that the Universe is anything but. In certain regions there is extremely interesting chemistry to explore, initiated by starlight and fast-moving particles known as cosmic rays. Approximately 180 different molecules have already been detected in space, ranging from dihydrogen to simple sugars. This module will discuss the methods used to detect these molecules and the models that explain their existence. It will cover astrochemistry, and provide an introduction to extra-terrestrial chemistry and the field of astrobiology - including its potential implications for the development of life on Earth and on other planets.
10 credits - Medicinal Chemistry and Drug Synthesis
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In the last century, medicinal chemistry has revolutionised healthcare, disease outcomes and life expectancy around the globe. This module will explain how medicinal chemistry emerged as a multidisciplinary field, how the biological mechanisms behind disease are identified, and how chemistry is used to target these mechanisms and develop treatments. Students will learn about drug profiles, the rules of drug discovery drug-target interaction surveys, the development of common anticancer drugs such as cisplatin, and some of the synthetic approaches commonly used by medicinal chemists, such as heterocyclic chemistry.
10 credits - Light-Matter Interactions and Applications (for analytical sciences and sustainability)
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Through this module you will be introduced to state-of-the-art advanced optical experimental techniques, from the underlying physical principles to selected analytical applications. Accordingly, after reviewing how light interacts with matter, we will discuss the principles of lasers and their uses in photo-chemistry. We will then discuss a number of advanced optical experimental techniques. We will pay special attention to the insights these techniques provide in terms of the fundamental molecular properties and chemical reactivity. The overall objective is to shed light on modern-day photo-chemistry through its applications in environmental chemistry research, solar energy conversion and sustainability.
10 credits - Properties of Inorganic Materials
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Many of the materials we encounter are solids, ranging from minerals and metals, to semiconductors and molecular crystals. These materials have diverse properties - mechanical strength, electrical conductivity, light absorption - that mean they can be used in lots of different ways, such as electronics or energy generation and storage. This module will look at the electronic, thermal, optical and mechanical properties of inorganic materials and cover microscopic, spectroscopic and diffraction techniques used to characterise solids. It will also illustrate how inorganic materials are used in, for example, semiconductor technology and energy conversion.
10 credits - Structure and Mechanism of Biomolecule Function
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Understanding the many functions of proteins is a fundamental problem for chemists to help solve, and can lead to new drugs and treatments. This course covers protein function, from ligand binding to enzyme catalysed reactions. Students look at the structure of protein-ligand interactions and the main biophysical techniques used to quantify energy flows in protein-drug interactions. They also learn about kinetic methods of analysis that shed light on enzyme mechanisms, and how these experimental approaches are used to design effective enzyme inhibitors, leading to new drugs. There is also training in core data analysis techniques.
10 credits
- Supramolecular Chemistry
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Supramolecular chemistry is the study of chemistry 'beyond the molecule'. Rather than using covalent chemistry to build ever more complex molecules, supramolecular chemists make use of the weaker interactions between ions and molecules to build sophisticated assemblies of molecules. Students will learn how complementary interactions can be used for molecular recognition and to drive the self-assembly of well defined molecular structures such as grids, helicates and cages in solution. They will also learn how these assemblies can act as sensors, catalysts, molecular machines and as responsive and self-healing materials.
10 credits
- Sustainable Chemistry, Energy Generation and Storage
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The environmental impact of rising levels of greenhouse gas emissions is prompting society to explore new methods to generate, use and store energy. This module will build on the sustainability students have already learned, to cover a number of modern approaches to energy generation and storage. There will be a particular focus on how biomass can be used to produce renewable chemicals and fuels, photovoltaics and alternative energy sources, fuel cells, nuclear energy, actinide availability and devices for energy storage. Examples are drawn from cutting-edge academic research and the latest applications in industry.
10 credits - Synthetic Approaches in Chemical Biology
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The ability to synthesise biomolecules has led to many of the most significant developments in molecular and chemical biology. This module looks at how biomolecules are created, from both biological and chemical perspectives. Student's knowledge will build up from understanding the central dogma and basic chemistry of life, to exploring important chemical biology techniques such as DNA sequencing, polymerase chain reaction, protein overproduction and site directed mutagenesis. Topics also include the production of novel biomolecules for bioconjugation, rational design, directed evolution, antibody production, and the new discoveries that synthetic biology might open the door to.
10 credits - Molecular Modelling
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Theoretical modelling has been firmly established in the modern chemistry research toolbox, thanks to its ability to probe molecular structures at a level of detail that is inaccessible to experiments. Modelling also allows us to explain experimentally observed properties of molecules and materials and to predict properties of new molecules. This course will build on existing knowledge of quantum chemistry and then follow on to introduce classical molecular modelling - a powerful method for computer modelling of the structures and dynamics of large (bio) molecules. Hands-on workshops will give students an opportunity to use computers to investigate chemical systems.
10 credits
In your fourth year, you’ll join one of our research groups to work on a project that addresses an unanswered question in chemistry. You’ll expand your knowledge and experience with lecture modules on specialist topics ranging from advanced organic synthesis to nanochemistry and sustainability in polymer science.
Core modules:
- Research Skills in Chemistry
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For this module, students complete an extended research project on a topic at the cutting edge of chemistry. Students work alongside professional scientists as a member of one of the School of Mathematical and Physical Sciences' research groups. They receive specialist training to help them develop the advanced practical skills they need for their project, and have access to state-of-the-art equipment and facilities. They also put their previous research training and existing careers skills into practice through literature searches, communicating their work and presenting their findings.
75 credits
Optional modules:
A student will take 45 credits (three modules) from this group.
- Communication for Sustainability Researchers
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The recent growth of knowledge and debates about sustainable development led to research in sustainability, however and to some extent paradoxically, there is often a lack of consensus on what sustainability really means. For example, in the context of Sustainable Energetic Resources, this could either mean: (i) renewables, (ii) minimization of usage, (iii) source reduction (like the redesign of manufacturing processes). Another example could be in the implementation of recycling policies, when these are actually referring to reuse and repair, which are all distinct concepts.
15 credits
Furthermore a full account on what makes a process or development sustainable, should consider multiple factors like: technical and scientific advances in the area, ecological, economic and societal principles, and ethical investments as a whole.
This module will provide students with the tools that are needed to argue, judge and select a chemical or physical process or even the effect of a policy in terms of life cycle assessment. That is: by investigating specific case studies, students will evaluate all stages and the lifetime of products, their environmental impacts as well as services, manufacturing processes, to create and formulate decision-making aimed to determine if the implementation of a sustainable process or not.
This unit aims to allow students to work as a part of a team to investigate a relevant and debated topic in sustainability, and to be able to present their findings to a general audience by means of a magazine-like article and a video. The scope is to assemble and create a piece of work soundly rooted in matter of facts, for which the students will need to carry out a detailed and updated literature involving data gathering, with the goal to address research questions in sustainability and be able to write publishable material of interest for the general public. - Advanced Materials Chemistry
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This module explains how structural, electronic, thermal, chemical and other properties of materials can be harnessed to help solve technological and environmental challenges. The functional materials covered are based on supramolecular assembly, leading predominantly to crystalline materials. Students learn about design strategies, molecular properties, and material function, using concepts from coordination and solid-state chemistry, organic chemistry and thermodynamics. The role of materials properties in applications such as sensing, molecular separations, gas adsorption, catalysis, drug delivery, propulsion, gas generation and blasting will be discussed in the context of energy, health care, transport, engineering and the environment.
15 credits
Module Aims:
A1. introduce a variety of materials developed and used in state-of-the-art research and technology with a focus reflecting current research interests at the University of ºù«Ӱҵ such as supramolecular materials, metal-organic frameworks and energetic materials.
A2. explain the chemical principles behind the design and synthesis of these different classes of materials.
A3. explain how the chemical structure of these materials enables their function and properties.
A4. describe how the properties lead to the materials' applications in various areas such as sensing, molecular separations, gas adsorption, catalysis, drug delivery, propulsion, gas generation and blasting. Â
A5. relate the importance of materials chemistry in tackling modern technological and environmental challenges. - Biophysical Chemistry
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This module covers the concepts and techniques to study the physical properties of biological macromolecules. The content aims to explain how thermodynamic concepts and advanced spectroscopic measurements allow biomolecule structures, function and interactions to be investigated. Students will learn about methods for analysing ensembles of many molecules as well as measurements on single biomolecules. Biophysical approaches to studying proteins and nucleic acid structures, and the mechanism of DNA damage recognition are taught as is the development of molecules for diagnostics, therapeutics and theranostics.
15 credits - Catalysis and Asymmetric Synthesis
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Chemists' ability to synthesise organic molecules with defined stereochemistry is the backbone of many useful applications, from medicines to new materials. Modern methods of organic synthesis rely on sophisticated and efficient chemical reactions that create exquisite levels of functional group selectivity and stereochemical control. This module will explain the cutting edge processes that achieve these objectives, in the context of catalysis and stereoselective synthesis. There is a focus on transformations that are promoted by a sub-stoichiometric amount of catalyst. Concepts behind controlling stereochemistry in important synthetic chemical reactions will also be explained.
15 credits
Module Aims:
A1. Provide students with knowledge and appreciation of advanced organic chemical reactions involving main group and transition metal catalyst systems, as well as organocatalysts.
A2. Provide students with the knowledge and skills to understand how organic reactions can be designed to generate desired products selectively.
A3. Make students aware of the uses of these reactions in the context of modern organic synthesis. - Chemistry of Light
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Understanding processes caused by light is key in chemistry, physics, biology and engineering, and has recently led to many major scientific breakthroughs. This course explains how light and matter interact in molecules, nanostructures and materials. It will explain photoinduced electron and energy transfer - essential processes in nature and everyday life - using examples of natural and artificial photosynthesis. Modern techniques for studying light-induced processes, on time-scales from seconds to femtoseconds, are also covered. The theory is taught in the context of applications in photocatalysis, photonics and optoelectronics, solar energy conversion, and light-induced processes in medicine.
15 credits - Methods and Models in Theoretical Chemistry
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The principles of theoretical chemistry can explain and predict chemical phenomena across all the main branches of chemistry (organic, inorganic, physical, analytical), and can shed light on molecular aspects of physics and biology. A wide range of methods and models are covered, including density functional theory, coupled cluster, time-dependent quantum mechanics, and more. Students are taught to assess these methods and models' suitability for different tasks, and put the theory into practice by using them to interpret chemical phenomena in hands-on projects.
15 credits - Modern Industrial Catalysis
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Reactions catalysed by metals are hugely important in the chemical industry, where they are used to produce bulk chemicals at large scales and fine chemicals at smaller ones. This module explains the heterogeneous and homogeneous catalytic processes behind some of the most economically important chemical reactions. It covers the chemical basis of these process, and their advantages and disadvantages of heterogeneous and homogeneous systems. There is a focus on reaction mechanisms and the role of the metal centre, and fundamental physical processes such as adsorption and reaction kinetics. Concepts are illustrated by analysing, in detail, catalytic reactions including hydrogenation, oxidation, carbonylation and polymerisation.
15 credits
Module Aims:
A1. Describe and explain the physical and chemical basis of homogeneous and heterogeneous metal-catalysed processes
A2. Illustrate the importance of metal-catalysed reactions in industrial chemical production
A3. Discuss the mechanisms of catalytic processes, and the experimental evidence upon which these are based
A4. Demonstrate recent developments in the field with state-of-the-art examples from the literature - Pharmacology, Medicinal Chemistry and Drug Design
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The discovery and development of new drugs requires a multidisciplinary approach, bringing together anatomy, physiology, pharmacology and toxicology. In this module, students learn about these areas as they build on their organic and medicinal chemistry knowledge from earlier in their degrees. It covers concepts including pharmacodynamics, pharmacokinetics and basic toxicology, and looks in detail at strategies for optimising the pharmacodynamic, pharmacokinetic properties of drugs. There is also a focus on computing technologies, including computer-aided drug design tools and quantitative structure:activity relationship models. Students learn about the fundamental chemistry behind the synthesis of specific drugs throughout the module.
15 credits - Sustainability technologies
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Our current carbon intensive technologies support our materials rich way of life and in order to maintain our living standards we need to decarbonise those technologies. We need to make better use of both fossil-based and renewable resources, and move towards a zero-waste, circular economy. Topics include the current status of the industry, life-cycle analysis, non-fossil fuel and feedstocks, and reuse, remanufacturing and recycling, which will find applications for the areas of: fine chemicals and commodities; plastic and polymers; and other materials for construction. This module aims to: 1. Introduce students to life cycle analysis and how LCAs can be used to determine the sustainability of a process or product. 2. Provide students with a broad, critical, overview of the methods through which polymer science can be made more sustainable. 3. Discuss and explain to reduce waste and environmental impact for large scale manufacturing processes for commodities and construction materials
15 credits
The content of our courses is reviewed annually to make sure it's up-to-date and relevant. Individual modules are occasionally updated or withdrawn. This is in response to discoveries through our world-leading research; funding changes; professional accreditation requirements; student or employer feedback; outcomes of reviews; and variations in staff or student numbers. In the event of any change we'll consult and inform students in good time and take reasonable steps to minimise disruption.
Learning and assessment
Learning
You'll learn through lectures, small group tutorials and workshops, practical sessions in the lab and research projects.
Assessment
You will be assessed through laboratory work, coursework, online quizzes, examinations, essays and other written work.
Programme specification
This tells you the aims and learning outcomes of this course and how these will be achieved and assessed.
Entry requirements
With Access ºù«Ӱҵ, you could qualify for additional consideration or an alternative offer - find out if you're eligible.
The A Level entry requirements for this course are:
AAB
including Chemistry
- A Levels + a fourth Level 3 qualification
- ABB including Chemistry + B in the EPQ; ABB including Chemistry + A in AS or B in A Level Further Maths
- International Baccalaureate
- 34 with 5 in Higher Level Chemistry
- BTEC Extended Diploma
- DDD in Applied Science (including the units Applications of Inorganic Chemistry, Applications of Organic Chemistry, Industrial Chemical Reactions, Practical Chemical Analysis)
- BTEC Diploma
- DD in Applied Science + A in A Level Chemistry
- Scottish Highers + 1 Advanced Higher
- AAABB + B in Chemistry
- Welsh Baccalaureate + 2 A Levels
- B + AA including Chemistry
- Access to HE Diploma
- Award of Access to HE Diploma in a relevant subject covering sufficient Chemistry units, with 45 credits at Level 3, including 36 at Distinction and 9 at Merit. Applicants are considered individually and must provide a course syllabus
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GCSE Maths grade 6/B
The A Level entry requirements for this course are:
ABB
including Chemistry
- A Levels + a fourth Level 3 qualification
- ABB including Chemistry + B in the EPQ; ABB including Chemistry + A in AS or B in A Level Further Maths
- International Baccalaureate
- 33 with 5 in Higher Level Chemistry
- BTEC Extended Diploma
- DDD in Applied Science (including the units Applications of Inorganic Chemistry, Applications of Organic Chemistry, Industrial Chemical Reactions, Practical Chemical Analysis)
- BTEC Diploma
- DD in Applied Science + B in A Level Chemistry
- Scottish Highers + 1 Advanced Higher
- AABBB + B in Chemistry
- Welsh Baccalaureate + 2 A Levels
- B + AB including Chemistry
- Access to HE Diploma
- Award of Access to HE Diploma in a relevant subject covering sufficient Chemistry units, with 45 credits at Level 3, including 30 at Distinction and 15 at Merit. Applicants are considered individually and must provide a course syllabus
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GCSE Maths grade 6/B
You must demonstrate that your English is good enough for you to successfully complete your course. For this course we require: GCSE English Language at grade 4/C; IELTS grade of 6.5 with a minimum of 6.0 in each component; or an alternative acceptable English language qualification
Equivalent English language qualifications
Visa and immigration requirements
Other qualifications | UK and EU/international
If you have any questions about entry requirements, please contact the school/department.
Graduate careers
School of Mathematical and Physical Sciences
Our courses have been created with your future in mind. All of our modules have been designed to give you skills that will help you find and succeed in your chosen career - problem solving, team working, fact finding, data analysis, critical thinking, communication, project management.
As part of your course, you'll develop your own idea for a chemistry business and pitch it as part of a team. On our Skills For Success training programme you can get experience of public speaking, presenting a poster, hosting a debate or producing a video. At our annual careers day you can explore career options, meet with employers who hire chemistry graduates and get tips from former students to help you take your next steps after graduation.
Some of the biggest employers of our students are pharmaceutical companies (such as GSK), where chemists develop new medicines, and consumer goods companies (such as Unilever and Reckitt), which make many of the products you see on supermarket shelves. Graduates can also go behind the scenes, creating the chemicals and materials that make industrial manufacturing possible.
The science industry doesn’t only employ scientists though - big companies like Unilever and AstraZeneca need graduates who understand science to work in communications, market research and business development roles.
What if I want to work outside science?
A chemistry degree from the University of ºù«Ӱҵ can take you far, whatever you want to do. We have graduates using their scientific minds in everything from finance to computer programming.
School of Mathematical and Physical Sciences
Research Excellence Framework 2021
The School of Mathematical and Physical Sciences is leading the way with groundbreaking research and innovative teaching. We provide our students with the skills and knowledge to support them in a wide range of careers.
Chemistry courses at the University of ºù«Ӱҵ are built around cutting-edge science that’s addressing global challenges. Four Nobel Prize winners have been ºù«Ӱҵ chemistry students or researchers. Our researchers work on a broad range of contemporary scientific challenges, ranging from antimicrobial resistance and environmental sustainability to cancer treatments and new technological solutions for industry.
Chemistry students are based in the Dainton and the Richard Roberts Buildings, which has lecture theatres, teaching labs and world-class research facilities. It's across the road from the UK’s number one students’ union and 24/7 library facilities at the Information Commons and the Diamond, and a short walk from the city centre.
Facilities
We have three large teaching labs where you'll spend a lot of time during your degree: one for organic chemistry, one for inorganic chemistry and one for physical chemistry. Each lab has specialist analytical equipment, including nuclear magnetic resonance, infrared and ultraviolet spectroscopy, and gas-, liquid- and size-exclusion chromatography. Our advanced lab is used for the group research project you'll complete in your third year, with large fume cupboards and workbenches to make collaboration easy.
We are also home to a number of multi-million pound research laboratories. These include the Lord Porter Ultrafast Laser Spectroscopy Laboratory, which is used in studies ranging from energy transport in molecules and materials to artificial photosynthesis, and our Soft Matter Analytical Laboratory, where scientists can study samples that are 100 times smaller than the width of a human hair.
University rankings
Number one in the Russell Group
National Student Survey 2024 (based on aggregate responses)
92 per cent of our research is rated as world-leading or internationally excellent
Research Excellence Framework 2021
University of the Year and best for Student Life
Whatuni Student Choice Awards 2024
Number one Students' Union in the UK
Whatuni Student Choice Awards 2024, 2023, 2022, 2020, 2019, 2018, 2017
Number one for Students' Union
StudentCrowd 2024 University Awards
A top 20 university targeted by employers
The Graduate Market in 2023, High Fliers report
A top-100 university: 12th in the UK and 98th in the world
Times Higher Education World University Rankings 2025
Student profiles
Fees and funding
Fees
Additional costs
The annual fee for your course includes a number of items in addition to your tuition. If an item or activity is classed as a compulsory element for your course, it will normally be included in your tuition fee. There are also other costs which you may need to consider.
Funding your study
Depending on your circumstances, you may qualify for a bursary, scholarship or loan to help fund your study and enhance your learning experience.
Use our Student Funding Calculator to work out what you’re eligible for.
Additional funding
School scholarships are available for this course, for further details see our funding and scholarships page.
ºù«Ӱҵ’s Experience ºù«Ӱҵ Scholarships includes a number of scholarships that are guaranteed to go to students in the School of Mathematical and Physical Sciences.
You can also be awarded an Undergraduate Research Scholarship to fund a summer research placement if you get AAA or above at A Level, or equivalent, and maintain an average grade of 70 per cent or higher.
Placements and study abroad
Placements
If you know you want to do a placement we also offer Chemistry with an Industrial Placement Year at both BSc and MChem levels that you can apply for via UCAS. Our students have completed placements at organisations including Dow Chemical Company (chemical industry), GSK (pharmaceutical industry), Merck KGaA (science and technology) and RB (consumer goods, formerly Reckitt Benckiser).
Another great way to gain extra experience is by applying to join the ºù«Ӱҵ Undergraduate Research Experience scheme. This gives you the chance to spend around six weeks working in one of our research groups over the summer. It's a unique opportunity to pursue research in an area that you’re excited about, and can help inform your future career aspirations.
We can guarantee you a summer research placement if you meet the requirements of our Undergraduate Research Scholarship scheme. Please find more information under 'Fees and funding'.
Study abroad
Visit
University open days
We host five open days each year, usually in June, July, September, October and November. You can talk to staff and students, tour the campus and see inside the accommodation.
Subject tasters
If you’re considering your post-16 options, our interactive subject tasters are for you. There are a wide range of subjects to choose from and you can attend sessions online or on campus.
Offer holder days
If you've received an offer to study with us, we'll invite you to one of our offer holder days, which take place between February and April. These open days have a strong department focus and give you the chance to really explore student life here, even if you've visited us before.
Campus tours
Our weekly guided tours show you what ºù«Ӱҵ has to offer - both on campus and beyond. You can extend your visit with tours of our city, accommodation or sport facilities.
Apply
The awarding body for this course is the University of ºù«Ӱҵ.
Recognition of professional qualifications: from 1 January 2021, in order to have any UK professional qualifications recognised for work in an EU country across a number of regulated and other professions you need to apply to the host country for recognition. Read and the .
Any supervisors and research areas listed are indicative and may change before the start of the course.