Build your laboratory and computing skills and receive training in a range of experimental techniques covering several areas of physics.

Become familiar with the key concepts of vector calculus and use them to provide a foundational introduction to electricity and magnetism.

Develop your understanding of the mathematics and physics of motion in space and time and advance your knowledge of classical mechanics.

Gain an in-depth knowledge of oscillation and waves and appreciate their importance in multiple areas of basic physics.

Further develop your understanding of several practical aspects of physics and carry out a project in either practical physics, computational physics, or a blend of the two.

Build your knowledge of circuit design and learn how to build simple circuits.

Learn to think "like a mathematician" and understand the mathematics underlying notions of limits and infinity, with particular emphasis on the underpinnings of Calculus.

Carry out experiments exploring complex physical phenomena and advance the skills developed in Year 1 laboratory and computing.

Receive a grounding in the structure of matter at the microscopic and macroscopic levels and explore thermodynamics and statistical physics.

Analyse various topics in electromagnetism (EM) and develop your knowledge of linear differential equations (DEs).

Study the formal framework of quantum mechanics and apply this knowledge to atomic physics to explain the structure and behaviour of hydrogen and more complex atoms.

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.

Spend time in a local school, supporting teaching whilst gaining experience of the science education children experience.

Become familiar with the structure and evolution of the Sun and other stars, and learn about the key physical principles that determine the state of the planets in our own Solar System.

Review several mathematical techniques fundamental for performing computations across physics and necessary for a proper formulation of its foundations.

Understand the application of core physical concepts to the Earth system, and develop a critical, practical awareness of global environmental change.

Undertake three experimental investigations and develop a broad range of practical and intellectual skills.

Examine the physics of elementary particles and nuclei, explore concepts associated with symmetries and use relativistic kinematics to calculate simple interactions.

Test your problem-solving ability using the basic principles of physics before applying them to unfamiliar situations.

Cover the fundamentals of the physics of solids and explore how the properties of solids are determined by microscopic physics.

Obtain a mathematically rigorous understanding of laser physics and examine the basic mechanisms of laser action and how real-world lasers operate.

Analyse a range of clinical imaging modalities and radiotherapies and understand the physical principles underlying the interactions of x-ray radiation with tissue.

Investigate the principles and practice of instrument science and use a prototyping system to build and characterise key instrument components.

Discover the broad range of physical phenomena which determine the behaviour of plasmas and the importance of collective effects.

Study how the co-operative behaviour of many simple constituents can lead to the emergence of new physics, and investigate continuous phase transitions.

Explore why the 21st century could be 'the century of complexity' and examine how interactions between many small but interacting parts can lead to the emergence of dramatic results on large scales.

Acquire the mathematical techniques and conceptual background required to understand the foundations of quantum mechanics.

Build your understanding of the finite difference methods used to solve differential equations in physics.

Apply physical concepts from your earlier studies to explain the formation, existence, and appearance of astronomical objects.

Become fluent in the language of representation theory and confident in its applications to non-relativistic quantum mechanics.

Complete a research project that tackles an open problem in physics for which the answer is not yet known or settled.

Carry out a research investigation that places an emphasis on your ability to discern, contextualise and critically analyse the research of others.

Develop your communication, teamwork and leadership skills and learn how to develop a successful research proposal from initial idea to presenting a bid.

Carry out a substantial research project embedded in a research group, under the guidance of research-active staff.

The project is the most substantial element of the degree and provides first-hand insight into how scientific research operates while developing your transferable skills.

Discover why quantum field theory (QFT) is essential to understand nature at smallest scales and understand the use of fields to describe fundamental particle physics.

Study the “Standard Model” (SM) of particle physics and assess both its advantages and limitations.

Develop your understanding of general relativity (GR), Einstein's theory of gravity, and understand the new, relativistic world view of four-dimensional Lorentzian spacetime.

Learn the basics of modern cosmology, and study the foundations of the Hot Big Bang theory.

Explore the fundamental concepts of shocks and gain a thorough understanding of compressible flow and its importance in supersonic motion.

Unpick the key physical theories that control the properties of different space plasmas and plasma phenomena.

Analyse the fundamental principles and applications of quantum information and their realisation.

Assess key laser applications and commercially important lasers and build your understanding of nonlinear optical phenomena and contemporary applications.

Deepen your knowledge of the properties required for the Lagrangian of a field theory, and explore how symmetries are represented mathematically and reflected in physical observables.

Understand the concept of topology in condensed matter physics using examples of current interest.

Examine quantum mechanics using light, atoms and their interactions, and learn how quantum optics can provide tools to develop quantum technology.

Broaden your appreciation of the optics of small metallic nanoparticles and nanoantennas.

Analyse modern information theory, from the laws of probability to the storage and transmission of (digital) information. 

Develop your entrepreneurial and organisational skills and consider how to establish a technology-based enterprise that maximises your physics education.

Explore how electronic, photonic and magnetic devices work and gain insight into some of the latest research developments in nanomaterials and device physics.

Review the basic structure of an atmosphere and the climate system, and use fundamental thermodynamics to derive expressions.

Deepen your knowledge of how modern optical communications technologies operate, and explore the operations of optical fibre networks.

Build your laboratory and computing skills and receive training in a range of experimental techniques covering several areas of physics.

Become familiar with the key concepts of vector calculus and use them to provide a foundational introduction to electricity and magnetism.

Develop your understanding of the mathematics and physics of motion in space and time and advance your knowledge of classical mechanics.

Gain an in-depth knowledge of oscillation and waves and appreciate their importance in multiple areas of basic physics.

Further develop your understanding of several practical aspects of physics and carry out a project in either practical physics, computational physics, or a blend of the two.

Build your knowledge of circuit design and learn how to build simple circuits.

Learn to think “like a mathematician” and understand the mathematics underlying notions of limits and infinity, with particular emphasis on the underpinnings of Calculus.

You’ll have the option to take a language module relevant to your year abroad destination. 

There are different levels of language modules available depending on your ability (this will be assessed prior to beginning your degree).

Your language module will be taken for credit but will not count toward your final degree grade.

Carry out experiments exploring complex physical phenomena and advance the skills developed in Year 1 laboratory and computing.

Receive a grounding in the structure of matter at the microscopic and macroscopic levels and explore thermodynamics and statistical physics.

Analyse various topics in electromagnetism (EM) and develop your knowledge of linear differential equations (DEs).

Study the formal framework of quantum mechanics and apply this knowledge to atomic physics to explain the structure and behaviour of hydrogen and more complex atoms.

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.

Alternatively, you will continue with your Horizons Language module, building on your first year studies.

Spend time in a local school, supporting teaching whilst gaining experience of the science education children experience.

Become familiar with the structure and evolution of the Sun and other stars, and learn about the key physical principles that determine the state of the planets in our own Solar System.

Review several mathematical techniques fundamental for performing computations across physics and necessary for a proper formulation of its foundations.

Understand the application of core physical concepts to the Earth system, and develop a critical, practical awareness of global environmental change.

Undertake three experimental investigations and develop a broad range of practical and intellectual skills.

Examine the physics of elementary particles and nuclei, explore concepts associated with symmetries and use relativistic kinematics to calculate simple interactions.

Test your problem-solving ability using the basic principles of physics before applying them to unfamiliar situations.

Cover the fundamentals of the physics of solids and explore how the properties of solids are determined by microscopic physics.

Discover why quantum field theory (QFT) is essential to understand nature at smallest scales and understand the use of fields to describe fundamental particle physics.

Study the “Standard Model” (SM) of particle physics and assess both its advantages and limitations.

Develop your understanding of general relativity (GR), Einstein's theory of gravity, and understand the new, relativistic world view of four-dimensional Lorentzian spacetime.

Learn the basics of modern cosmology, and study the foundations of the Hot Big Bang theory.

Explore the fundamental concepts of shocks and gain a thorough understanding of compressible flow and its importance in supersonic motion.

Unpick the key physical theories that control the properties of different space plasmas and plasma phenomena.

Analyse the fundamental principles and applications of quantum information and their realisation.

Assess key laser applications and commercially important lasers and build your understanding of nonlinear optical phenomena and contemporary applications.

Deepen your knowledge of the properties required for the Lagrangian of a field theory, and explore how symmetries are represented mathematically and reflected in physical observables.

Understand the concept of topology in condensed matter physics using examples of current interest.

Examine quantum mechanics using light, atoms and their interactions, and learn how quantum optics can provide tools to develop quantum technology.

Broaden your appreciation of the optics of small metallic nanoparticles and nanoantennas.

Analyse modern information theory, from the laws of probability to the storage and transmission of (digital) information. 

Develop your entrepreneurial and organisational skills and consider how to establish a technology-based enterprise that maximises your physics education.

Explore how electronic, photonic and magnetic devices work and gain insight into some of the latest research developments in nanomaterials and device physics.

Review the basic structure of an atmosphere and the climate system, and use fundamental thermodynamics to derive expressions.

Deepen your knowledge of how modern optical communications technologies operate, and explore the operations of optical fibre networks.

Obtain a mathematically rigorous understanding of laser physics and examine the basic mechanisms of laser action and how real-world lasers operate.

Analyse a range of clinical imaging modalities and radiotherapies and understand the physical principles underlying the interactions of x-ray radiation with tissue.

Investigate the principles and practice of instrument science and use a prototyping system to build and characterise key instrument components.

Study how the co-operative behaviour of many simple constituents can lead to the emergence of new physics, and investigate continuous phase transitions.

Explore advanced concepts in classical physics and build your appreciation of the role played by symmetries in fundamental physics.

Explore why the 21st century could be 'the century of complexity' and examine how interactions between many small but interacting parts can lead to the emergence of dramatic results on large scales.

Acquire the mathematical techniques and conceptual background required to understand the foundations of quantum mechanics.

Build your understanding of the finite difference methods used to solve differential equations in physics.

Discover the broad range of physical phenomena which determine the behaviour of plasmas and the importance of collective effects.

Apply physical concepts from your earlier studies to explain the formation, existence, and appearance of astronomical objects.