- UCAS course code
- F3FA
- UCAS institution code
- M20
Master of Physics (MPhys)
MPhys Physics with Astrophysics
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Duration: 4 years
Year of entry: 2025
UCAS course code: F3FA / Institution code: M20
- Key features:
Scholarships available
Accredited course
- Typical A-level offer: A*A*A including specific subjects
- Typical contextual A-level offer: A*AA including specific subjects
- Refugee/care-experienced offer: AAA including specific subjects
- Typical International Baccalaureate offer: 38 points overall with 7,7,6 at HL, including specific requirements
Fees and funding
Fees
Tuition fees for home students commencing their studies in September 2025 will be £9,535 per annum (subject to Parliamentary approval). Tuition fees for international students will be £36,500 per annum. For general information please see the undergraduate finance pages.
Policy on additional costs
All students should normally be able to complete their programme of study without incurring additional study costs over and above the tuition fee for that programme. Any unavoidable additional compulsory costs totalling more than 1% of the annual home undergraduate fee per annum, regardless of whether the programme in question is undergraduate or postgraduate taught, will be made clear to you at the point of application. Further information can be found in the University's Policy on additional costs incurred by students on undergraduate and postgraduate taught programmes (PDF document, 91KB).
Scholarships/sponsorships
The University of Manchester is committed to attracting and supporting the very best students. We have a focus on nurturing talent and ability and we want to make sure that you have the opportunity to study here, regardless of your financial circumstances.
For information about scholarships and bursaries please visit our undergraduate student finance pages and our Department funding pages .
Course unit details:
Fluid Mechanics and Phase Transitions
| Unit code | PHYS30352 |
|---|---|
| Credit rating | 10 |
| Unit level | Level 3 |
| Teaching period(s) | Semester 2 |
| Available as a free choice unit? | No |
Overview
The fluid mechanics component of this unit focuses on the fundamental principles governing flow behaviour of Newtonian fluids across scales, with applications from astrophysics and environmental science to quantum fluids. The course will introduce the continuum mechanics framework, which models fluids at a macroscopic level, and delve into key concepts such as viscous and inviscid flows. The unit emphasizes both the mathematical complexity of fluid mechanics and its wide-ranging applications across disciplines. The unit also explores the emergence of order in simple models of interacting systems, offering insights into how complex behaviours arise from basic principles. Through this course, students will develop a deeper appreciation of the underlying physical mechanisms that govern phase transitions and their applications across diverse scientific disciplines.
Pre/co-requisites
| Unit title | Unit code | Requirement type | Description |
|---|---|---|---|
| Statistical Mechanics | PHYS20352 | Pre-Requisite | Compulsory |
Aims
This unit introduces fundamental concepts in two key areas of physics: fluid mechanics and phase transitions. These topics recur in many areas of modern physics research beyond Condensed Matter Physics, and the unit equips students with the knowledge and analytical tools to understand their significance.
Learning outcomes
On the successful completion of the course, students will be able to:
ILO 1
Describe and use key concepts in fluid dynamics to solve the Navier-Stokes equations in specific scenarios.
ILO 2
Apply key concepts to the viscous limit, such as Stokes settling and inertialess swimming, and to the inviscid limit, such as Bernoulli's equations, vorticity, irrotational flow and lift force.
ILO 3
Apply mean-field theories to describe phase transitions in simple interacting models.
ILO 4
Use Landau theory to describe phase transitions in condensed matter.
Teaching and learning methods
Two one hour, live in-person lectures per week where the core material will be delivered with examples. The recordings of these lectures will be available on Podcast and linked to the course online page. The lectures are accompanied by lecture notes and for some of the material explanatory videos. This is augmented by a set of weekly problems with solutions. Problems will also be released for example classes, where students will be able to work on them together for three hours over the course of the semester. A Piazza discussion forum is also provided where students can ask questions with answers provided by other students and the unit lead.
Assessment methods
| Method | Weight |
|---|---|
| Written exam | 100% |
Recommended reading
Guyon E, Hulin J-P, Petit L. and Mitescu C.D., Physical hydrodynamics, (OUP)
Steven H. Simon, The Oxford Solid State Basics (OUP)
Acheson, D.J. Elementary Fluid Dynamics, (OUP)
Davidson, P. Incompressible Fluid Dynamics (OUP)
J. M. Yeomans, Statistical Mechanics of Phase Transitions (Clarendon Press)
H. Nishimori, G. Ortiz, Elements of Phase Transitions and Critical Phenomena (Oxford Graduate Texts)
Study hours
| Scheduled activity hours | |
|---|---|
| Lectures | 24 |
| Independent study hours | |
|---|---|
| Independent study | 76 |
Teaching staff
| Staff member | Role |
|---|---|
| Alessandro Principi | Unit coordinator |
| Anne Juel | Unit coordinator |