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08 PhD Degree-Fully Funded at Brunel University, London, England

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Brunel University, London, England invites online Application for number of  Fully Funded PhD Degree at various Departments. We are providing a list of Fully Funded PhD Programs available at Brunel University, London, England.

Eligible candidate may Apply as soon as possible.


(01) PhD Degree – Fully Funded

PhD position summary/title: Electrical properties and performance of conducting polymer composites

Applications are invited for a PhD studentship for the Successful international applicant will receive an annual stipend of £16,000 plus payment of their full-time international tuition fees for a period of 36 months (three years).

Home candidate will receive the annual stipend of £19,214 plus payment of their full-time home tuition fees for a period of 36 months (three years).

The successful applicants will join the internationally recognised researchers in the Department of Brunel Composites Centre at Brunel University London (BUL). This exciting research projects

will be based in Cambridge at NSIRC. It is a state-of-the-art postgraduate engineering facility established and managed by structural integrity specialist TWI, working closely with lead academic partner Brunel University, the universities of Cambridge, Manchester, Loughborough, Birmingham, Leicester and a number of leading industrial partners. NSIRC aims to deliver cutting edge research and highly qualified personnel to its key industrial partners.

Deadline :  31 May 2024

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(02) PhD Degree – Fully Funded

PhD position summary/title: Mechanisms of Interoception and Stress in Medically Unexplained Symptoms

Throughout history, the interrelatedness of mind and body has been known to physicians and patients for millennia. Despite this, treating conditions that involve complicated iterations of this relationship has proved difficult and continues to constitute a barrier to the effective care of many patients in the medical system. One contributing factor is that many physicians and mental health professionals still have a dichotomous view of medical conditions as belonging to either pathologies of the “body” or of the “mind” .Medically Unexplained Symptoms refers to physical symptoms or conditions that do not have an identifiable organic cause or clear disease classification. Multiple psychological and biomedical theories have been proposed to explain MUS, highlighting dysfunctional stress responses across various physiological axes (such as the hypothalamic-pituitary-adrenal axis, inflammatory responses, and cardiovascular responses) and interoceptive dysregulation. The knowledge regarding the interaction between these mechanisms is still incomplete. Existing research often focuses on a single mechanism, stress test, physiological stress axis, or a specific MUS condition, leading to fragmented understanding.The overall aim of this project is to investigate mechanisms of MUS by means of multimodal data, by combining MRI, EEG and ECG, and behavioural paradigms which will aim to explore Interoceptive mechanisms and attentional biases. We will use an ’emotional stress induction’ procedure, to explore Interoception, central brain networks and attentional bias before and during emotional stress.The PhD student will play a crucial role in conducting in-depth research on the interplay between mind and body in conditions like Medically Unexplained Symptoms. Their responsibilities will include:- Conducting a comprehensive review of existing literature on MUS, related psychological and biomedical theories, and multimodal data research methods.- Assisting in the design and development of experimental protocols, particularly those involving MRI, EEG, and ECG data collection, as well as behavioural paradigms for exploring interoceptive mechanisms and attentional biases.- collecting and analysing multimodal data from study participants. This may involve operating MRI and EEG equipment, processing, and interpreting data- Preparing research papers and reports based on the findings of the study for publication in scientific journals and conferences.The PhD student’s work will be critical in advancing our understanding of MUS and may potentially contribute to the development of more effective treatment approaches for patients with these conditions. The project offers an exciting opportunity for the student to gain valuable research experience and make meaningful contributions to the field of medical science and patient care. Prospective PhD students with a background in Neuroscience, Psychology, or Neuroimaging are strongly encouraged to apply for the project. However, having this specific background is not an absolute requirement for consideration. The selection process will involve an interview with the Supervisor, during which candidates will have the opportunity to showcase their enthusiasm and interest in the topic of the project.

Deadline : 03/08/2025

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(03) PhD Degree – Fully Funded

PhD position summary/title: Simulation and experimental research of two different bending processes: free-form (3D) bending and roll stretch (2D) bending

Typically, steel has often been used as the primary material in structural automotive components. However, there is a need to reduce vehicle emissions which demands car manufacturers to focus on next-generation electric vehicle (EV) production. This can be achieved by designing and manufacturing lightweight vehicles by replacing steel components with extruded aluminum alloys due to their high mechanical properties and low density. Constellium UK, and its extrusion development of high-strength and high-crash alloys, play an important role in enclosure structure designs for EVs.

There are applications where the bending of extrusions is a necessary cold forming step included in the process route to produce automotive components such as enclosure structures. The free-form bending technology, often known as 3D bending is a novel bending process that opens new and unique opportunities concerning the complexity of geometrical shapes (extrusions) and innovative designs, reducing production process times, assembly efforts and consequently costs. This is a process that opens new and unique scenarios concerning the complexity of geometrical shapes (extrusions) and innovative designs, reducing production process times, assembly efforts and consequently costs.

Deadline : 28/06/2024

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(04) PhD Degree – Fully Funded

PhD position summary/title: Developing a comprehensive management approach to PFAS – The London NERC DTP

The widespread use and prolonged environmental persistence of the per- and polyfluoroalkyl substances (PFAS) have led to their ubiquitous detection in waterbodies worldwide. These “forever chemicals” are found in everyday consumer goods (from textiles and cleaning products to cookware) and therefore, wastewater serves as a major pathway through which PFAS enter aquatic environments. Conventional wastewater treatment plants (WWTPs) have low removal efficiencies for PFAS, while in many cases, higher PFAS concentrations are reported in the effluents than in the influents. Advanced treatment processes are more effective at removing PFAS compared to conventional methods; however, they come at much higher costs, increased operational carbon emissions, and varying effectiveness in removing PFAS precursor compounds. At the same time, residential drinking water is a primary source of human exposure to PFAS as drinking water treatment technologies or water blending techniques do not eliminate these chemicals. The costs of cleaning up wastewater and drinking water contaminated with PFAS are borne by water companies, which also lose important revenue streams due to the disposal of sludge contaminated by PFAS to landfills at increasing landfill tax rates. Ultimately, these costs are passed onto customers or taxpayers who routinely and disproportionately experience the long-term costs of exposure to PFAS and environmental degradation. Therefore,the overall aim of this PhD project is to develop a comprehensive PFAS management approach that will decouple the urban water cycle from PFAS inputs.

Deadline : 17/06/2024

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(05) PhD Degree – Fully Funded

PhD position summary/title: Funding for the Executive Dean’s PhD Studentship. A Comprehensive Characterisation of Mentally-Disordered Offenders and Prediction of Treatment Outcomes

Forensic mental health patients, the majority of whom have schizophrenia and/or antisocial personality disorder (ASPD), tend to have highly variable outcomes, with some experiencing lengthy stays and high rates of reoffending following discharge. Knowledge of the patient characteristics which are associated with good or poor clinical outcomes would serve to identify areas of unmet need and potential treatment targets. Throughout this doctoral programme, the student will develop proficiency in mental illness and personality disorder symptomatology assessment, neuropsychological testing, cognitive and experimental psychology methodologies, brain imaging techniques, and advanced statistical analyses.

Deadline : 10/06/2024

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(06) PhD Degree – Fully Funded

PhD position summary/title: Funding for the Executive Dean’s PhD Studentship: Lineage tracing of blood stem cell development in embryo-like gastruloids

The overarching aim of this project is the optimisation of culture conditions for the scalable generation of haematopoietic stem cells (HSCs) in vitro from pluripotent sources. This paves the path for on-demand laboratory production of HSC and blood cells, overcoming the limitations of voluntary blood donations and tissue compatibility, and addressing an unmet clinical need.

The project brings together established PIs’ expertise in regulation of haematopoiesis and HSCs and in biophotonics and live imaging solutions. It is truly interdisciplinary and will provide the successful candidate with solid exposure to molecular biology, stem cell biology, organoid bioengineering, and advanced live microscopy, expanding their future employability and career choice.

Deadline : 10/06/2024

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(07) PhD Degree – Fully Funded

PhD position summary/title: Funding for the Executive Dean’s PhD Studentship in Experience-based codesign for effective physical activity interventions with working age adults living with multiple long-term conditions

MLTC is the co-existence of two or more chronic conditions. In the UK, the majority of people living with MLTC are less than 65 years old, with 2.5 million people out of paid work due to MLTC.

Physical activity is an effective intervention for managing MLTC, but there is limited research in working-age populations. Increased physical activity levels in working-age people with MLTCs may be related to remaining in and/or returning to paid work.

This studentship will explore and understand the experiences of physical activity in diverse working-age adults living with MLTCs, and use experience-based co-design to develop an inclusive physical activity intervention to support this group to live well. The studentship will address this using rigorous qualitative methodologies, including creative co-production methods.

Deadline : 10/06/2024

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(08) PhD Degree – Fully Funded

PhD position summary/title: Fully funded studentship in Plastivore Plasticity: characterising metabolic flexibility in an emerging biotechnological system to manage plastic waste

Applications are invited from high-calibre and passionate students seeking to pursue an exciting career in analytical and environmental science research, with a focus to tackle a growing concern with respect to managing plastic waste.

Pollution is now considered an environmental emergency alongside biodiversity loss and climate change. There are many forms of pollution but it predominantly concerns the issue of chemical and plastic waste. In particular, plastic waste represents a very complex societal challenge; the benefits provided by plastics are indisputable but we have seen concerning impacts in the environment from the micro- to macro-scale.

An emerging and ground-breaking biotechnological system involves the use of insect larvae to biodegrade plastics and has been observed for several species (Coleoptera and Lepidoptera), but focus has been given to, Galleria mellonella (Greater Wax Moth) which recently was demonstrated to degrade plastics like polyethylene (PE) and polystyrene (PS) converting them to proteins, lipids and frass. This biodegradation pathway could enable the re-use of by-products (e.g. breakdown of polymers into respective monomers) and provide a future solution to the plastic waste emergency. However, whilst biodegradation has been observed, the use of plastic as a food source has limited understanding regarding the toxicological effects in these plastivore insects and the metabolic plasticity associated with a plastic-rich diet. How does metabolic flexibility via plasticity and redundancy enable these insects to use plastics as a sole carbon source? The potential toxicity could influence the survival of these organisms to be used at scale and must be characterised if these insects are to become a viable solution to the plastic waste crisis.

Deadline : 10/06/2024

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About Brunel University, London, England- Official Website

Brunel University London (BUL, and often known simply as Brunel) is a public research university located in the Uxbridge area of London, England. It was founded in 1966 and named after Isambard Kingdom Brunel, the Victorian engineer and pioneer of the Industrial Revolution. In June 1966, Brunel College of Advanced Technology was awarded a royal charter and became Brunel University; in 2014 the university formally adopted the name Brunel University London (BUL). The university is considered a British plate glass university.

Brunel is organised into three colleges, a structure adopted in August 2014. Brunel’s three constituent Academic Colleges include the College of Business, Arts and Social Sciences; the College of Engineering, Design and Physical Sciences; and the College of Health, Medicine and Life Sciences.

Brunel has over 16,150 students and 2,500 staff, and an annual income of £271.3 million (2021–22), of which £22.4 million was from research grants and contracts, with an expenditure of £311.9 million. The university won the Queen’s Anniversary Prize in 2011. BUL is a member of the Association of Commonwealth Universities, the European University Association, and Universities UK.



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