Metamaterials-based microwave devices for simultaneous wireless information and power transfer
Applications are invited for a 3.5-year PhD studentship. The studentship will start on 1 October 2025.
Project description
Project overview
The integration of simultaneous wireless information and power transfer (SWIPT) is a critical enabler for next-generation electric vehicles (EVs) and smart city infrastructures. However, current hardware solutions for SWIPT systems are hindered by inefficiencies and practical limitations. This PhD project aims to revolutionise SWIPT systems by leveraging the unique properties of metamaterials. By incorporating cutting-edge technologies such as graphene and advanced periodic structures, this research will explore the development of innovative wireless devices to enhance the performance of SWIPT systems.
The integration of simultaneous wireless information and power transfer (SWIPT) is a critical enabler for next-generation electric vehicles (EVs) and smart city infrastructures. However, current hardware solutions for SWIPT systems are hindered by inefficiencies and practical limitations. This PhD project aims to revolutionise SWIPT systems by leveraging the unique properties of metamaterials. By incorporating cutting-edge technologies such as graphene and advanced periodic structures, this research will explore the development of innovative wireless devices to enhance the performance of SWIPT systems.
Objectives
- Design and fabricate novel devices like metasurfaces and IRSs for SWIPT applications.
- Create adaptive solutions that adjust to varying frequencies, and environmental conditions.
- Develop smart algorithms to maximise energy transfer and information transmission efficiency.
Methodology
The project combines theoretical modelling, simulations, and experimental validation using tools like CST Microwave Studio and Matlab. The candidate will fabricate prototype devices, test them, and integrate them into SWIPT systems.
The project combines theoretical modelling, simulations, and experimental validation using tools like CST Microwave Studio and Matlab. The candidate will fabricate prototype devices, test them, and integrate them into SWIPT systems.
Expected outcomes
The project will produce efficient, practical SWIPT systems with novel metamaterial devices, enhanced adaptability, and validated performance. Results will lead to high-impact publications and advancements.
The project will produce efficient, practical SWIPT systems with novel metamaterial devices, enhanced adaptability, and validated performance. Results will lead to high-impact publications and advancements.
Candidate requirements
A master’s degree (or equivalent) in Electrical Engineering, Physics, or a related field. Strong background in electromagnetics, or wireless communication systems. Experience with simulation tools (e.g., CST, HFSS) and/or experimental characterisation of electromagnetic devices is a plus. Excellent analytical and problem-solving skills, with a strong interest in interdisciplinary research. Proficiency in English and the ability to publish research in high-impact journals.
A master’s degree (or equivalent) in Electrical Engineering, Physics, or a related field. Strong background in electromagnetics, or wireless communication systems. Experience with simulation tools (e.g., CST, HFSS) and/or experimental characterisation of electromagnetic devices is a plus. Excellent analytical and problem-solving skills, with a strong interest in interdisciplinary research. Proficiency in English and the ability to publish research in high-impact journals.