Postgrad LIVE! Study Fairs

Birmingham | Edinburgh | Liverpool | Sheffield | Southampton | Bristol

University of Bristol Featured PhD Programmes
University College London Featured PhD Programmes
University of Glasgow Featured PhD Programmes
University College London Featured PhD Programmes
University of Manchester Featured PhD Programmes

Engineering Doctorate (EngD) Short pulse lasers for machining composite materials (Rofin-Sinar)

  • Full or part time
    Prof D Reid
  • Application Deadline
    Applications accepted all year round
  • Funded PhD Project (European/UK Students Only)
    Funded PhD Project (European/UK Students Only)

Project Description

Project not available to non UK/EU applicants.

The EngD is an alternative to a traditional PhD aimed at students wanting a career in industry. Students spend about 75% of their time working directly with a company in addition to receiving advanced-level training from a broad portfolio of technical and business courses. On completion students are awarded the PhD-equivalent EngD.

The automotive and aerospace industries are utilising a higher proportion of composite materials, such as carbon fibre reinforced plastic (CFRP), to improve efficiency and reduce carbon emissions. Machining CFRP at the required productivity rates whilst maintaining material integrity is an ongoing challenge. Most mechanical and laser based techniques tend to reduce the material integrity at the required processing speeds. In particular, machining demonstrations with high power fibre and CO2 lasers produced large heat affected zones (HAZ). Alternative approaches utilising pulsed laser systems, in either the nanosecond or picosecond regime, reduce the HAZ but are either limited in average power or are complex and expensive systems. This project will aim to develop and demonstrate a laser-based technology that is capable of overcoming the current limitations.

High absorption in both the carbon fibres and the surrounding polymer matrix should ensure the CO2 laser is an ideal choice for machining composite material. Typical commercial CO2 lasers operate in a long pulse regime of >5µs at high average powers. However, the long pulses create a large HAZ which reduces the material integrity. Q-switched lasers with pulse widths <300ns are available but at typical average powers of 500W average power at pulse widths 500W average power at pulse widths <250ns.The final system will be used to develop optimised machining strategies for CFRP. This will be supported by modelling undertaken within the project.

The combination of high average power and short pulse width in a cost effective, reliable architecture is not currently available. By developing this laser system this project will generate a solution suited to machining a range of composite materials.

This project gives the student the opportunity to work within an established and dynamic development team that has a long history of innovation and success in creating products suited to a range of industries.

Information for applicants:

The ideal candidate will have or expect to obtain a 1st or 2:1 class degree in Physics or an optics/ photonics related subject. They will have practical experimental experience and have the ability to work within a diverse team. They will also be self-motivated and innovative.

Experience undertaking research, modelling complex systems or laser technology/ processing experience would be an advantage.

Funding Notes

This 4-year (including CDT taught-courses) project is funded jointly by Rofin-Sinar and by the CDT in Applied Photonics, run by Heriot-Watt University. The annual stipend is £21,277, which includes an enhancement from Rofin-Sinar. A substantial consumables and equipment budget is provided by a concurrent EPSRC grant. Travel funding for conference presentations is also available.

Email Now

Insert previous message below for editing? 
You haven’t included a message. Providing a specific message means universities will take your enquiry more seriously and helps them provide the information you need.
Why not add a message here
* required field
Send a copy to me for my own records.

Your enquiry has been emailed successfully





FindAPhD. Copyright 2005-2018
All rights reserved.