Design and manufacture of complex three-dimensional electrical steels 

This project offers an exciting opportunity to undertake industrially linked research with engineering teams of the Manufacturing Technology Centre (MTC) and academics within the Power Electronics, Machines and Control (PEMC) research group at the University of Nottingham. The project will be supported by the state-of-the-art electric motor manufacturing platforms at both locations. 

Project description

Electrification is a main enabler for decarbonised transportation. Ambitious roadmaps to achieve the “Net Zero” target by 2050 in the UK require step-change performance of electrical motors from a state-of-the-art continuous power density of 2-5 kW/kg to 10-25 kW/kg by 2035. Incremental improvements in electrical machines built from simple stacks of 2D laminations will not suffice to bridge the power density gap required for next generation electric vehicle traction or aerospace propulsion. A radical approach to how electrical machines can be designed and built with 3D architectures that enable significantly boosted electromagnetic, mechanical, and thermal performance is yet to be developed.

The project will motivate you to revolutionise electrical machine design and development based on programmable 3D electrical steel technology enabled by advanced manufacturing processes and emerging magnetic materials for applications across automotive, aerospace, and power generation. Starting from modelling and parametric design of complex 3D laminated and hybrid cores, you will design and develop new motor topologies and experimentally characterise their magnetic, mechanical, and thermal performance. The optimised design for manufacturing workflow will be demonstrated on application-relevant prototypes, evidencing improvements in power density, efficiency, and manufacturability over conventional 2D solutions.

Candidate requirements

• You should have a 1st or high 2:1 degree in electrical/mechanical engineering, physics, mathematics, or related scientific disciplines
• Skills in numerical tools and programming are desirable (MATLAB, python, C++ etc)
• Any experience or capabilities in engineering design or manufacturing methods would be advantageous

Funding and eligibility

• A three-year fully funded studentship
• A generous tax-free annual stipend of £25,000 plus full-time home tuition fees paid
• An additional £2,000 per annum for consumables and travel

Due to funding restrictions this position is available for UK home candidates only. As sponsored by MTC, the successful candidate would need to pass the sponsors own security checks before starting the PhD.

How to apply

Closing date: 27 February 2026

PhD Start date: 5 October 2026

For further information please email Professor Chris Gerada (University of Nottingham) at chris.gerada@nottingham.ac.uk and and Will Pollitt (MTC) at Will.Pollitt@the-mtc.org 

Facilities

The MTC is an independent Research and Technology Organisation aimed at de-risking and accelerating the adoption of disruptive technologies within the UK manufacturing sphere. Supported by the UK government, the MTC works closely with industrial partners and other research organisations to deliver world leading innovation across all levels of the UK’s industrial landscape, from SMEs and start-ups to OEMs and large-scale global manufacturers.

PEMC is home to Driving the Electric Revolution Midlands Industrialisation Centre and the UK Electrification of Aerospace Propulsion Facilities, which have received over £20m of funding in the last three years. PEMC – at 5000m² with state-of-the-art facilities for research into electrification technologies, hosting 21 academics, 60 post-doctoral researchers and over 80 PhD students, will be made available for this project.

The university actively supports equality, diversity and inclusion and encourages applications from all sections of society.