Begin to engage with university chemistry and receive training in teamwork and giving feedback.

Explore how structures and concepts in chemistry are represented and described and learn how to draw and name a variety of molecules.

Become familiar with the simple tools used to predict molecular structures and use theoretical models to explain the bonding in molecules and other chemical structures.

Develop your understanding of the physical and theoretical basis for spectroscopic measurements and examine spectroscopic techniques.

Learn about the major types of reactivity at carbon centres and learn how to rationalise trends in reactivity.

Explore the major theories and methodologies used to interpret chemical reactions and chemical equilibrium at a macroscopic level.

Examine concepts and trends in the chemistry of the s-, p-, d- and f- block elements, and their compounds.

Develop skills for practical chemistry and begin to apply these to investigative practical work.

Become familiar with important mathematical concepts important for the theoretical description of physical phenomena.

Assess the principles that underpin medicinal chemistry and place drug design within a medicinal chemistry context.

Stimulate your professional and intellectual growth in areas including languages, humanities and social sciences.

Appreciate the expectations for your second year of learning and learn about inclusivity and diversity.

Understand what electronic states are and why chemical bonds form, based on approximate quantum mechanical models.

Explore the underlying theories of spectroscopy, and investigate a variety of spectroscopic techniques and applications.

Use thermodynamic quantities to describe the state of a system, phase and interface; and calculate how such quantities change during a chemical transformation.

Build on your knowledge of properties, reactivity and synthesis, and apply it to a wider range of molecular chemical systems.

Extend your knowledge of properties, reactivity and synthesis to consider polymers and biomolecules such as carbohydrates and peptides.

Apply your prior knowledge of synthesis and properties to explain the properties of larger molecules such as bio(macro)molecules or polymers.

Develop your research skills through synthetic, physical/analytical and computational experimental work.

Become familiar with mathematical techniques relevant in the analysis and interpretation of physical theories including electromagnetism.

Further your knowledge of medicinal chemistry in areas including pharmacokinetics and the principles of drug discovery. 

Stimulate your professional and intellectual growth in areas including languages, humanities and social sciences.

Advance your understanding of the financial, strategic, operational and organisational context in which science takes place.

Explore five advanced chemistry topics.

You’ll pick from topics including advanced synthesis, materials chemistry, and soft condensed matter.

Investigate a further five advanced chemistry topics.

You’ll pick from topics including biological chemistry, process chemistry and strategies of drug discovery.

Further develop your skills in practical chemistry and research in a variety of contexts, including project-style lab practicals.

Your I-Explore module offers you choices from a range of subjects hosted outside of the department. 

You will be taught alongside students from other courses with options including business, management and many more.

Deliver a report focusing on your project proposal and a literature review of your chosen research area.

Join one of the department’s academic  research groups to complete a six-month independent research project.

Understand catalyst activity and selectivity through mechanistic (kinetic) studies.

Develop a high-level understanding of the tactics and strategies deployed in complex molecule and natural products synthesis and biosynthesis.

Apply fundamental concepts of chemistry to biological and medical imaging and understand the importance of chemistry in medical imaging.

Learn how to interpret a complex and involved portfolio of data and identify potential strengths and weaknesses within a drug discovery portfolio.

Appreciate current applications and challenges in sustainable chemical processes and products.

Examine various methods for discovering and optimising nanomaterials for a wide variety of applications.

Analyse the structure and dynamics of membranes and lipid assemblies and understand how these regulate key biological processes.

Broaden your understanding of the operation mechanisms of organic electronics devices and the importance of electrodes in their design.

Understand charge generation and flow through a variety of chemical systems of relevance to energy production and storage.

Begin to engage with university chemistry and receive training in teamwork and giving feedback.

Explore how structures and concepts in chemistry are represented and described and learn how to draw and name a variety of molecules.

Become familiar with the simple tools used to predict molecular structures and use theoretical models to explain the bonding in molecules and other chemical structures.

Develop your understanding of the physical and theoretical basis for spectroscopic measurements and examine spectroscopic techniques.

Learn about the major types of reactivity at carbon centres and learn how to rationalise trends in reactivity.

Explore the major theories and methodologies used to interpret chemical reactions and chemical equilibrium at a macroscopic level.

Examine concepts and trends in the chemistry of the s-, p-, d- and f- block elements, and their compounds.

Develop skills for practical chemistry and begin to apply these to investigative practical work.

Become familiar with important mathematical concepts important for the theoretical description of physical phenomena.

Assess the principles that underpin medicinal chemistry and place drug design within a medicinal chemistry context.

Stimulate your professional and intellectual growth in areas including languages, humanities and social sciences.

Appreciate the expectations for your second year of learning and learn about inclusivity and diversity.

Understand what electronic states are and why chemical bonds form, based on approximate quantum mechanical models.

Explore the underlying theories of spectroscopy, and investigate a variety of spectroscopic techniques and applications.

Use thermodynamic quantities to describe the state of a system, phase and interface; and calculate how such quantities change during a chemical transformation.

Build on your knowledge of properties, reactivity and synthesis, and apply it to a wider range of molecular chemical systems.

Extend your knowledge of properties, reactivity and synthesis to consider polymers and biomolecules such as carbohydrates and peptides.

Apply your prior knowledge of synthesis and properties to explain the properties of larger molecules such as bio(macro)molecules or polymers.

Develop your research skills through synthetic, physical/analytical and computational experimental work.

Become familiar with mathematical techniques relevant in the analysis and interpretation of physical theories including electromagnetism.

Further your knowledge of medicinal chemistry in areas including pharmacokinetics and the principles of drug discovery. 

Stimulate your professional and intellectual growth in areas including languages, humanities and social sciences.

Advance your understanding of the financial, strategic, operational and organisational context in which science takes place.

Explore five advanced chemistry topics.

You’ll pick from topics including advanced synthesis, materials chemistry, and soft condensed matter.

Investigate a further five advanced chemistry topics.

You’ll pick from topics including biological chemistry, process chemistry and strategies of drug discovery.

Further develop your skills in practical chemistry and research in a variety of contexts, including project-style lab practicals.

Your I-Explore module offers you choices from a range of subjects hosted outside of the department. 

You will be taught alongside students from other courses with options including business, management and many more.

Join one of the department’s academic  research groups to complete a six-month independent research project.

Understand catalyst activity and selectivity through mechanistic (kinetic) studies.

Develop a high-level understanding of the tactics and strategies deployed in complex molecule and natural products synthesis and biosynthesis.

Apply fundamental concepts of chemistry to biological and medical imaging and understand the importance of chemistry in medical imaging.

Learn how to interpret a complex and involved portfolio of data and identify potential strengths and weaknesses within a drug discovery portfolio.

Appreciate current applications and challenges in sustainable chemical processes and products.

Examine various methods for discovering and optimising nanomaterials for a wide variety of applications.

Analyse the structure and dynamics of membranes and lipid assemblies and understand how these regulate key biological processes.

Broaden your understanding of the operation mechanisms of organic electronics devices and the importance of electrodes in their design.

Understand charge generation and flow through a variety of chemical systems of relevance to energy production and storage.

Begin to engage with university chemistry and receive training in teamwork and giving feedback.

Explore how structures and concepts in chemistry are represented and described and learn how to draw and name a variety of molecules.

Become familiar with the simple tools used to predict molecular structures and use theoretical models to explain the bonding in molecules and other chemical structures.

Develop your understanding of the physical and theoretical basis for spectroscopic measurements and examine spectroscopic techniques.

Learn about the major types of reactivity at carbon centres and learn how to rationalise trends in reactivity.

Explore the major theories and methodologies used to interpret chemical reactions and chemical equilibrium at a macroscopic level.

Examine concepts and trends in the chemistry of the s-, p-, d- and f- block elements, and their compounds.

Develop skills for practical chemistry and begin to apply these to investigative practical work.

Become familiar with important mathematical concepts important for the theoretical description of physical phenomena.

Assess the principles that underpin medicinal chemistry and place drug design within a medicinal chemistry context.

Stimulate your professional and intellectual growth in areas including languages, humanities and social sciences.

Enhance your language skills to prepare for your research abroad. 

For final year study operating in another language, you must take Language for Research Abroad 1 as your optional module.

Appreciate the expectations for your second year of learning and learn about inclusivity and diversity.

Understand what electronic states are and why chemical bonds form, based on approximate quantum mechanical models.

Explore the underlying theories of spectroscopy, and investigate a variety of spectroscopic techniques and applications.

Use thermodynamic quantities to describe the state of a system, phase and interface; and calculate how such quantities change during a chemical transformation.

Build on your knowledge of properties, reactivity and synthesis, and apply it to a wider range of molecular chemical systems.

Extend your knowledge of properties, reactivity and synthesis to consider polymers and biomolecules such as carbohydrates and peptides.

Apply your prior knowledge of synthesis and properties to explain the properties of larger molecules such as bio(macro)molecules or polymers.

Develop your research skills through synthetic, physical/analytical and computational experimental work.

Become familiar with mathematical techniques relevant in the analysis and interpretation of physical theories including electromagnetism.

Further your knowledge of medicinal chemistry in areas including pharmacokinetics and the principles of drug discovery. 

Represent Imperial across a variety of different events and activities.

This work will help you develop skills in communication, teamwork, planning, and marketing.

Stimulate your professional and intellectual growth in areas including languages, humanities and social sciences.

Advance your understanding of the financial, strategic, operational and organisational context in which science takes place.

Enhance your language skills to prepare for your research abroad. 

For final year study operating in another language, you must take Language for Research Abroad 2 as your optional module.

Explore five advanced chemistry topics.

You’ll pick from topics including advanced synthesis, materials chemistry, and soft condensed matter.

Investigate a further five advanced chemistry topics.

You’ll pick from topics including biological chemistry, process chemistry and strategies of drug discovery.

Further develop your skills in practical chemistry and research in a variety of contexts, including project-style lab practicals.

Your I-Explore module offers you choices from a range of subjects hosted outside of the department. 

You will be taught alongside students from other courses with options including business, management and many more.

Enhance your language skills to prepare for your research abroad. 

For final year study operating in another language, you must take Language for Research Abroad 3 as your optional module.

Begin to engage with university chemistry and receive training in teamwork and giving feedback.

Explore how structures and concepts in chemistry are represented and described and learn how to draw and name a variety of molecules.

Become familiar with the simple tools used to predict molecular structures and use theoretical models to explain the bonding in molecules and other chemical structures.

Develop your understanding of the physical and theoretical basis for spectroscopic measurements and examine spectroscopic techniques.

Learn about the major types of reactivity at carbon centres and learn how to rationalise trends in reactivity.

Explore the major theories and methodologies used to interpret chemical reactions and chemical equilibrium at a macroscopic level.

Examine concepts and trends in the chemistry of the s-, p-, d- and f- block elements, and their compounds.

Develop skills for practical chemistry and begin to apply these to investigative practical work.

Become familiar with important mathematical concepts important for the theoretical description of physical phenomena.

Assess the principles that underpin medicinal chemistry and place drug design within a medicinal chemistry context.

Stimulate your professional and intellectual growth in areas including languages, humanities and social sciences.

Enhance your language skills to prepare for your research abroad. 

For final year study operating in another language, you must take Language for Research Abroad 1 as your optional module.

Appreciate the expectations for your second year of learning and learn about inclusivity and diversity.

Understand what electronic states are and why chemical bonds form, based on approximate quantum mechanical models.

Explore the underlying theories of spectroscopy, and investigate a variety of spectroscopic techniques and applications.

Use thermodynamic quantities to describe the state of a system, phase and interface; and calculate how such quantities change during a chemical transformation.

Build on your knowledge of properties, reactivity and synthesis, and apply it to a wider range of molecular chemical systems.

Extend your knowledge of properties, reactivity and synthesis to consider polymers and biomolecules such as carbohydrates and peptides.

Apply your prior knowledge of synthesis and properties to explain the properties of larger molecules such as bio(macro)molecules or polymers.

Develop your research skills through synthetic, physical/analytical and computational experimental work.

Become familiar with mathematical techniques relevant in the analysis and interpretation of physical theories including electromagnetism.

Further your knowledge of medicinal chemistry in areas including pharmacokinetics and the principles of drug discovery. 

Stimulate your professional and intellectual growth in areas including languages, humanities and social sciences.

Advance your understanding of the financial, strategic, operational and organisational context in which science takes place.

Enhance your language skills to prepare for your research abroad. 

For final year study operating in another language, you must take Language for Research Abroad 2 as your optional module.

Explore five advanced chemistry topics.

You’ll pick from topics including advanced synthesis, materials chemistry, and soft condensed matter.

Investigate a further five advanced chemistry topics.

You’ll pick from topics including biological chemistry, process chemistry and strategies of drug discovery.

Further develop your skills in practical chemistry and research in a variety of contexts, including project-style lab practicals.

Your I-Explore module offers you choices from a range of subjects hosted outside of the department. 

You will be taught alongside students from other courses with options including business, management and many more.

Enhance your language skills to prepare for your research abroad. 

For final year study operating in another language, you must take Language for Research Abroad 3 as your optional module.