MSc in Quantum Technologies

Quantum technologies (across quantum computing, sensing and communications) have the potential to bring transformative changes across different sectors from scientific research to industrial applications.

The MSc in Quantum Technologies will provide you with the central technical background in these technologies, combined with hands-on practical training through short modules and research experience through an extended four-month project.

At the end of the course, it is expected that you will have achieved the following learning objectives:

• to have a technical overview of the principles underpinning quantum technologies
• to understand the principles of quantum computing, sensing and communications
• to have an overview of the state-of-the-art in hardware for quantum technologies
• to have further detailed knowledge of specific topics within quantum technologies and their applications (through chosen option courses)
• to appreciate the challenges and opportunities of translating quantum technologies to applications across different setups
• to complete short training in transferable skills including presenting work
• to have practical hands-on experience in practical techniques underpinning quantum technologies chosen from options ranging from laboratory techniques and control systems to programming of quantum computers
• to have demonstrated competence in completing and presenting a research project, both in written and oral form

Course structure

The academic year is split into three terms of eight weeks but work on the MSc course continues throughout the year and is not restricted just to term time.

During the three terms of the course, you will choose from modules on various aspects of quantum technologies. 

Core modules

There are two seminar-based compulsory modules comprising an Industry Seminar and a Graduate Public Engagement element. The Industry Seminar is assessed by a coursework report.

Term one (Michaelmas term)

• Quantum Mechanics for Quantum Technologies (optional for students with previous quantum mechanics courses)
• Introduction to Quantum Technologies

Term two (Hilary term)

• Quantum Technologies and their applications
• Hardware for Quantum Technologies

Terms one and two (Michaelmas and Hilary)

• Industrial Seminar
• Quantum Technologies Practical Training

Summer term (Trinity term) and summer vacation

• Quantum Technologies Project, with a dissertation to be submitted on the first Tuesday in September

Optional modules

The options that are offered may vary from year to year as the course develops, and according to the interests of teaching staff. These modules will be available in terms one and two (Michaelmas and Hilary), typical modules will include: 

• Quantum Processes and Computation
• Quantum Information
• Materials for Quantum Technologies
• Experimental Techniques Seminar
• Quantum Optics and Atomic Physics
• Additional Quantum Technologies Practical Training
• Many-body Physics

Research project

You will work on a four-month research project and will be placed either within a University research team, or at an industrial partner organisation.

The course will be strongly connected to the emerging international quantum technologies industry, with regular industry seminars highlighting the opportunities and challenges of translating these technologies across different sectors, as well as entrepreneurship and IP management. Some projects will be directly connected to or based within industry research teams.

Attendance

The majority of research projects are expected to be based in Oxford and the surrounding area, but some may be based further afield. Any student who prefers to be allocated a project based in or near Oxford will be given that option. 

Resources to support your study

Academic Resources

The University of Oxford has over 70 academics working in quantum science and technologies and related areas, including in Physics, Engineering Science, Materials, Computer Science, Mathematics, and Chemistry. You will benefit from teaching laboratory facilities during practical training components, and the resources of these research teams (including laboratory and computing facilities), and those of our industrial partners, during the four-month project phase of the course.

Non-Academic Resources

There is a range of welfare and academic support available in the Department of Physics. The Course Director and Graduate Administrator are available to offer support and signpost, and there are several support networks in the department, all of which are available to our graduate students.

Oxford Physics Gender Equity Network (OPGEN), which is run by a committee drawn from across the students, academics and staff in the Department of Physics and organises events and campaigns to promote gender equity in the department.

The Graduate Liaison Committee (GLC). The GLC’s purpose is to discuss issues that may concern graduate students in the department such as the quality of graduate courses, availability of skills training, accessibility to library and IT services, and general student welfare.

The Graduate Peer Support Network, which is a subgroup of the informal mentoring network Physics Thrive.

Mental health first aiders are an initial point of contact for students experiencing a mental health issue or emotional distress. They are members of staff of our department, and have completed a two-day mental health first-aid training course, accredited by Mental Health England. They are trained to recognise the symptoms of mental ill health, provide initial help and guide a person towards appropriate professional help. Mental Health First Aiders are not trained to be therapists, but they are taught how to respond in a crisis.

In addition to the resources available within the department, there is additional support available via the Oxford University Student Union (OUSU) and your college.

New students will also be welcome in the wider Oxford Physics community, with multiple opportunities of mutual support and social interactions. 

Supervision

The allocation of graduate supervision for this course is the responsibility of the Department of Physics and it is not always possible to accommodate the preferences of incoming graduate students to work with a particular member of staff. Under exceptional circumstances a supervisor is often found outside the Department of Physics.

All projects will be supervised by experts in quantum technologies and underpinning areas across different Mathematical, Physical, Engineering and Life Sciences (MPLS) departments. 

You will be matched with a supervisor ahead of your final dissertation project. Some projects may be based with industry partners, in which case a university-side supervisor will also be appointed for the project. Students can typically expect to interact with University supervisors regularly, eg weekly or, in some cases (such as where the project is based in industry), monthly. Most supervisors run an extended research group, including several DPhil students and post-docs, who interact frequently (usually on a daily basis in laboratory or office settings). 

Assessment

You will be assessed for all taught modules, research and business case studies, and individual dissertations. 

There will be one combined exam for the core modules, which will be held at the beginning of the second term (Hilary term).  

Elective modules will be assessed as appropriate to the module, which will be a combination of examinations, mini-projects, reports and/or presentations.

A dissertation of 20,000 words, completed independently under the guidance of an expert supervisor, focusing on the four-month research project and approved by the supervisor and MSc Course Director will be submitted at the end of the course.

Graduate destinations

We anticipate graduates will go onto leading positions within the growing quantum technological landscape, whereby it is expected that many graduates will seek employment with a company or national facility they have interacted with during the course. It will also provide a strong foundation for students to transition to post-graduate research in quantum technologies, focusing on any of the strands within the course; this approach is likely most applicable for students wishing to change to a more practical doctorate than their undergraduate degree. 

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