Category : Educational Articles | Author: Sunday Ntente Published on 2024-05-20 11:18:23
The University of Nottingham, Nottingham, England invites online Applications for several Fully Funded PhD Degrees at various Departments. We are providing a list of Fully Funded PhD Programs available at the University of Nottingham, Nottingham, England.
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Eligible candidates may Apply as soon as possible.
(01) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Advances in
diagnostic, prognostic, and treatment opportunities for canine haemangiosarcoma
and osteosarcoma
The project will be based in the Rutland, Mongan, Jeyapalan
Research Group. Haemangiosarcoma (HAS) or malignant endothelioma or
angiosarcoma (AS) is the most common vascular malignancy encountered in dogs,
whilst osteosarcoma is the most common bone tumor identified with a documented
prevalence of approximately 85% of all primary malignancies arising in the
skeleton of this species. We will be using techniques such as
immunohistochemistry and H-scoring, histopathological analysis, RNA sequencing,
qRT-PCR, western blotting, bioinformatics, ELISA, cell culture, statistics, and
literature reviews. A working knowledge of these techniques is therefore
desirable. We will compare subtypes, detect potential biomarkers, undertake
pathway analysis, and identify potential pharmaceutical interactions. We will
be collaborating with researchers from four international universities on this
project.
Deadline: Thursday 23 May 2024
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(02) PhD Degree – Fully Funded
PhD position summary/title: PhD studentship: Development and application of recombinant antibodies to map pathology-related changes in glycosaminoglycans on breast cancer cells
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The PhD student will join an extensive team of scientists delivering a BBSRC strategic Longer and Larger project, GlycoWeb. The team includes research groups from The University of Nottingham, Liverpool University, Manchester University, and the Francis Crick Institute, alongside international (USA and Denmark) and commercial (InterReality Labs) partners. Glycosaminoglycans (GAGs) are a class of biomolecules that decorate the surface of virtually all cells in the body. They play critical roles in a multitude of biological processes, including cell signaling and development, and are known to be dysregulated in diseases, including cancers. Despite their ubiquity and clear importance, we lack a thorough understanding of how the molecular structure of a particular GAG links to its biological function. To compound this problem, there is currently a lack of tools with which to detect and characterize GAGs in tissues and cells.
This studentship will aim to isolate a range of recombinant
antibodies that bind to GAGs, producing highly specific probes. The post will
use the very latest developments in antibody phage display technology, coupling
the binding of vast antibody-phage libraries containing billions of potential
binders with the screening power of next-generation sequencing (a process
termed next-generation phage display, NGPD). The studentship will apply NGPD to
target cell surface GAGs from breast cancer cell populations, identify specific
binders, clone, and express binders, and finally, characterize binding against
breast cancer cell populations and define GAG structures. You will be embedded
within a highly active phage-display group at the University of Nottingham and
have the opportunity to interact with the whole Glycoweb team, visit
collaborator`s labs, and extend your research knowledge and collaborator
network.
Deadline: Wednesday 14 August 2024
(03) PhD Degree – Fully Funded
PhD position summary/title: PhD studentship: Using Next-generation
Nitrogen Sources for Producing Spring Malting Barley and its Impact on Yield
and Grain Malt Quality
An exciting opportunity has arisen to study for a PhD sponsored by Molson Coors Beverage Company and the BBSRC as a part of a collaborative training center (`BARIToNE`) focused on assuring the future sustainable supply of UK malting barley. This project falls under the `reduced inputs` theme of BARIToNE.
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Malted barley is the
single largest dry ingredient in brewing beer. Optimizing barley production and
enhancing the production of tons of barley per hectare while increasing barley
quality simultaneously is essential to developing the most sustainable barley
supply chain globally. Presently, nitrogen fertilizers contribute 50-70% of
greenhouse gas emissions associated with barley production. This project will
assess the impacts that new nitrogen fertilizers will have on barley yield and
malt quality to improve the N-use efficiency (NUE) and hence sustainability of
barley supply. You will also investigate the use of nitrification inhibitors
which can be added to N-based fertilizer to reduce losses and improve use
efficiency. Nitrification inhibitors inhibit the biological oxidation of
ammonium to nitrate, thus extending the time the active nitrogen component of
the fertilizer remains in the soil as ammonium-N.
We hypothesize that barley cultivars will respond differently to these new and different nitrogen fertilizers and nitrification inhibitors that the resulting malt will have end-use quality differences and parameters and that a genetic-by-environment (treatment) interaction will be observed.
This project includes
the opportunity to gain valuable industry experience working with Molson Coors
Beverage Company for a period of 3-6 months. Full training will be given in the
required techniques and practices; this studentship would ideally be suited to
a graduate with skills in plant or crop science and molecular biology.
Deadline: Friday 31 May 2024
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(04) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship – Turning up the heat on soil carbon: Quantifying carbon dynamics and climate resilience of agave production in Mexico
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“Climate change is one of the most significant challenges facing the world today, and agriculture is both a contributor to and a casualty of climate change. The impact of agriculture on the environment has been increasingly scrutinized, as it is responsible for 13% of global greenhouse gas emissions. However, regenerative farming offers a promising solution to reduce the impact of agriculture on climate change and increase the resilience of farming systems to climate change impacts. Our recent work has demonstrated the substantial benefits of adopting regenerative practices in terms of long-term climate resilience. However, the benefits and trade-offs from such transitions are poorly quantified, and there remains little understanding of how such changes can contribute to the decarbonization and increased sustainability of supply chains.
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Agave is an important crop that underpins the tequila supply
chain. Agricultural production can have substantial adverse environmental
impacts, including soil degradation, challenges with water availability, and
significant greenhouse gas emissions. Regenerative agriculture describes a
range of more sustainable farming practices and is of growing interest across
the agriculture sector due to its potential to bring multiple benefits through
carbon sequestration and storage in soils, benefits to biodiversity, and
increased climate resilience. Regenerative practices have significant potential
in agave production, but benefits are poorly quantified, particularly in terms
of impacts on yield and carbon storage, and little is known about how these
will impact supply chains or smallholder farmer livelihoods. This project
addresses this challenge.
Deadline: Friday 31 May 2024
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(05) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Concrete4Change
and the Centre for Sustainable Chemistry
Applications are invited for an industrial-led PhD
studentship aimed at developing new, sustainable, advanced concrete materials
with carbon-negative footprints. To achieve this breakthrough, we will use a
multi-discipline approach incorporating organic and polymer chemistry,
materials science, and leading-edge data analysis, including machine
learning/AI approaches. We are looking to attract applicants from
chemistry/materials chemistry with an innate drive and curiosity to deliver new
solutions to building materials that are needed within the next 10 years.
Deadline: 15 July 2024
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(06) PhD Degree – Fully Funded
PhD position summary/title: The Universities for Nottingham
and the Centre for Sustainable Chemistry – PhD Scholarships available
We invite suitably qualified and highly motivated applicants
from STEM disciplines to apply for a series of multidisciplinary PhD
scholarships hosted by the University of Nottingham and Nottingham Trent
University. In partnership with leading industrial stakeholders, we are
launching a new collaborative approach to PhD projects. Our new PhD projects develop skills targeting
the urgent need in transition to sustainable chemicals manufacturing. Our
projects will define the next generation of multidisciplinary innovators
driving the technologies and chemistries needed for Net-Zero economies.
Deadline: 31 May 2024
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(07) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: synthesis of
molecular energy materials for lithium-sulfur batteries We are seeking to
recruit a highly motivated and enthusiastic PhD student to work on the
synthesis of molecular energy materials. The candidate will work within the
Nottingham Applied Materials and Interfaces Group (www.thenamilab.com) in the
Carbon Neutral Laboratories for Sustainable Chemistry at the University of
Nottingham alongside our `next-generation` batteries research team. We want to
understand the chemistry that underpins advanced energy systems and use this
knowledge to unlock new energy storage technologies for the electrification of
the automotive sector. The target is to enable alternative, sustainable
technologies that can supersede the lithium-ion battery and the group maintains
active research programs in lithium-ion batteries, magnesium batteries,
lithium-air batteries, and lithium-sulfur batteries. Our approach to address
these challenges spans synthetic chemistry, electrochemistry, and device
development and is delivered in collaboration with leading stakeholders in the
energy storage sector.
Deadline: 11 September 2024
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(08) PhD Degree – Fully Funded
PhD position summary/title: PhD Project: 3D printing
next-generation actuators for soft robots and devices. 3D printing of soft
robotics is a growing field, with many applications in biomedical devices,
electronics, and autonomous machines. Actuators to drive these robots utilize
electronic, chemical, pressure, magnetic, or thermal mechanisms, with the
current generation having significant drawbacks, including low energy
efficiency, high operating voltage, or temperature. This project will develop
the materials, methods, and designs necessary to 3D-print the next generation
of soft actuators. The overall aim is to develop and exploit new designs or new
materials to attain large, fast, high-efficiency actuation responses comparable
to living muscles.
An ideal candidate will have an interest in 3D printing and
its applications, knowledge of materials sciences, mechanical engineering, or
digital design, and an inquisitive spirit motivated to develop a world-leading
expertise. They will have a background in engineering, materials science, or
chemistry, but will also be willing to learn new disciplines and innovate to
achieve the project goals. This studentship will prepare you for routes into
both industry and academia and will equip you with skills in photopolymer
chemistry, materials development for 3D printing, device engineering, and
materials processing for additive manufacturing. You will also develop skills
in characterization, including microscopy, mechanical analysis, and advanced
spectrometry techniques.
Deadline: 15 September 2024
(09) PhD Degree – Fully Funded
PhD position summary/title: PhD Project: Functional 3D/4D
Printing of Responsive Structures
3D-printed functional devices interact with their environment, responding to electrical, magnetic, chemical, humidity, temperature, or other signals, including devices that change shape over time, using “4D-printing”. In complex devices, multiple “trigger” stimuli can be encoded, each to its shape-change response; however, these multiple responses are independent of one another. This project will develop new materials and designs for functional 4D-printed devices with fast, self-resetting responses, applicable to biomedical, micromechanical, or optoelectronic applications. The goal will be to build a functional demonstrator device that performs basic comparisons of inputs to select output shape-change responses.
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An ideal candidate will have an interest in 3D printing and
its applications, knowledge of materials sciences and/or digital design, and an
inquisitive spirit motivated to develop a world-leading expertise. They will
have a background in engineering, materials science, or chemistry, but will
also be willing to learn new disciplines and innovate to achieve the project
goals. This studentship will prepare you for routes into both industry and
academia and will equip you with skills in photopolymer chemistry, materials
development for 3D printing, device engineering, and materials processing for
additive manufacturing. You will also develop skills in characterization,
including microscopy, mechanical analysis, and advanced spectrometry
techniques.
Deadline: 15
September 2024
(10) PhD Degree – Fully Funded
PhD position summary/title: PhD project: Functional
Structural Color Devices through 3D Printing
Small, repetitive structures with spacings on the nanometer
scale can refract and reflect light to create structural colors, which are
being explored to produce anti-counterfeit markings, dye-free color images,
humidity and chemical sensors, anti-glare coatings, and optical filters. This
project will develop additive manufacturing of devices with actively controlled
structural color. You will develop the materials, methods, and designs
necessary to 3D-print the next generation of structural color devices,
integrating optically and electronically active materials, including 0D and 2D
nanomaterials.
An ideal candidate will have an interest in 3D printing and
its applications, knowledge of materials sciences and/or digital design, and an
inquisitive spirit motivated to develop a world-leading expertise. They will
have a background in engineering, materials science, or chemistry, but will
also be willing to learn new disciplines and innovate to achieve the project
goals. This studentship will prepare you for routes into both industry and
academia and will equip you with skills in photopolymer chemistry, materials
development for 3D printing, device engineering, and materials processing for
additive manufacturing. You will also develop skills in characterization,
including microscopy, mechanical analysis, and advanced spectrometry
techniques.
Deadline: 15 September 2024
(11) PhD Degree – Fully Funded
PhD position summary/title: PhD Project: 3D-Printed
Micro-Robots for Medical Applications
The field of medical therapeutics has valuable applications for mobile devices for efficient drug delivery, called micro-robots. Recently, 3D printing has been used to manufacture such devices with functional features that enable them to respond to environmental cues, including temperature, pH, light, magnetic fields, and ultrasound. This project will develop the materials, methods, and designs necessary to 3D-print the next generation of medical micro-robots, exploiting combinations of functions to achieve the advanced control necessary for complex and customizable micro-robots to provide personalized healthcare solutions.
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An ideal candidate will have an interest in 3D printing and
its applications, knowledge of materials sciences and/or digital design, and an
inquisitive spirit motivated to develop a world-leading expertise. They will
have a background in engineering, materials science, or chemistry, but will
also be willing to learn new disciplines and innovate to achieve the project
goals. This studentship will prepare you for routes into both industry and
academia and will equip you with skills in photopolymer chemistry, materials
development for 3D printing, device engineering, and materials processing for
additive manufacturing. You will also develop skills in characterization,
including microscopy, mechanical analysis, and advanced spectrometry
techniques.
Deadline: 15 September 2024
(12) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship in
Electromagnetic Compatibility for 25kV Rail Systems, funded by Network Rail
Applications are invited for a Network Rail-funded, 3.5-year
PhD program to address key challenges in the rail industry. The successful
candidate with be based at the University of Nottingham but will have the
opportunity to collaborate with engineers from Network Rail and spend time at
their offices.
This PhD will investigate modeling techniques that can help
engineers understand electromagnetic compatibility issues in railway 25kV AC
overhead lines. This will include developing models, mathematical techniques,
and software tools that can predict how the power distribution lines, on-train
power converters, and trackside systems interact, and then use these tools to
understand how EMC issues can be mitigated.
Deadline: 07 August 2024
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(13) PhD Degree – Fully Funded
PhD position summary/title: PhD Opportunities in Mechanical
and Aerospace Systems (MAS) Research Group
There are some exciting opportunities based within the MAS
Research Group within the Faculty of Engineering (FoE) which conducts cutting-edge
research in the fields of transport and energy, focusing on future
sustainability challenges. We use simulations and experimental techniques to
develop the knowledge & understanding of the underlying engineering science
and enable new products, processes, and tools. MAS works closely with
industrial partners and other research organizations to deliver world-leading
research and innovation from the fundamental to applied.
Deadline: 31 July 2024
(14) PhD Degree – Fully Funded
PhD position summary/title: PhD studentship in advanced
rotor-stator interactions through bearings
Ball bearings and roller bearings play crucial roles in most rotating machines. Their design and selection involve a complex mix of considerations including component life under normal running conditions, power losses, vibrations in the machine, and the ability to carry exceptional loads when/if these loads come to exist. These bearings, collectively called rolling-element bearings, are key parts of aero-engines, centrifuges, wind turbines, electric motors, range extenders, fans, pumps, and compressors, etc. and they serve in almost every industry imaginable ranging from renewable energy through oil-and-gas exploitation and transport.
The way that rolling element bearings affect the vibrations
of the machine in which they serve is a rich area for study. At the first
level, they provide a stiff connection between the stationary and rotating
parts of a spinning machine with very little intrinsic damping. However, their
full behavior is much more complex than this. Their characteristics are
currently estimated and modeled under the assumption that they carry steady
forces but these methods do not account for the complexity of the dynamic
environment of a multi-rotor machine such as a gas turbine engine. Interactions
of the bearings and the rotors cause many of the complex vibration responses
that are used for the diagnosis of engine faults. However, these diagnostic
methods are limited in their real-world application due to the complexity and
limited measurements of the engines.
Deadline: 14 August 2024
(15) PhD Degree – Fully Funded
PhD position summary/title: PhD scholarship: Developing a Miniaturized
End-effector for Repair in Confined Spaces (UK Atomic Energy Authority
sponsored)
Applicants are invited to undertake a 3-year PhD program in
partnership with the UK Atomic Energy Authority (UKAEA) to address key
challenges in on-platform repair automation. The successful candidate will be
based at the Rolls-Royce University Technology Centre in Manufacturing and
On-Wing Technology (http://www.nottingham.ac.uk/utc),
Department of Mechanical, Material, and Manufacturing Engineering, Faculty of
Engineering. The department has an excellent international reputation for
high-quality theoretical and experimental research funded by the EPSRC, IUK,
EU, and the manufacturing industry.
This project will be part-funded by the UK Atomic Energy
Authority`s RACE (Remote Applications in Challenging Environments, https://www.race.ukaea.uk) robotics and
remote handling center. RACE was founded in 2014 as part of the UKAEA`s Fusion
Research and Development Program to design and test robots for operating in
some of the most challenging environments imaginable. UKAEA`s wider mission is
to lead the commercial development of fusion power and related technology and
position the UK as a leader in sustainable nuclear energy.
Deadline: 25 July 2024
(16) PhD Degree – Fully Funded
PhD position summary/title: PhD opportunity in flow crystallization
with in situ X-ray diffraction.
We are pleased to announce a PhD opportunity in flow crystallization
with in situ X-ray diffraction. This multi-disciplinary PhD will combine
reactor design, crystallization, crystal engineering, and data science. You`ll
be joining a group of students developing a variety of flow apparatus for
tailored needs.
At Diamond Light Source, the UK`s national synchrotron, we
have developed a world-leading in situ flow crystallization apparatus that
enables us to monitor what we are crystallizing as it is crystallizing. By
coordinating the flow of crystals within the crystallizer tubing with the
movement of the whole crystallizer as the crystals pass the X-ray beam, we can maximize
the data that can be obtained from this dynamic environment. However, there are
still great challenges to be overcome.
Deadline: 19 July 2024
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(17) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Extra-long
compliant snake robot capable of self-localization for inspection in fusion
power plants
Applicants are invited to undertake a 3-year PhD program in
partnership with the UK Atomic Energy Authority (UKAEA) to address key
challenges in robotic deployment systems enabling repair automation. The
successful candidate will be primarily based at the Rolls-Royce University
Technology Centre in Manufacturing and On-Wing Technology, (http://www.nottingham.ac.uk/utc),
Department of Mechanical, Material and Manufacturing Engineering, Faculty of
Engineering. The department has an excellent international reputation for
high-quality theoretical and experimental research funded by EPSRC, IUK, EU,
and the manufacturing industry. There is an opportunity to be hosted by UKAEA`s
Culham Campus for part of the project.
Deadline: 30 July 2024
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(18) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Rolls Royce
sponsored PhD scholarship – Micromechanics and in-depth materials analysis of
advanced aerospace materials upon the manufacturing process
Applications are invited to undertake a 3-year PhD program
in partnership with industry to address key challenges in on-platform
manufacturing engineering. The successful candidate will be based at the
Rolls-Royce University Technology Centre (UTC) in Manufacturing Technology and
On-Wing Technology (https://www.nottingham.ac.uk/utc/index.aspx
) at the University of Nottingham. Having state-of-the-art purpose-built
facilities, the UTC offers a world-class environment for the realization of high-impact
research projects.
The Rolls-Royce-funded Studentship is the result of the
expanding manufacturing activities sponsored at the Rolls-Royce UTC dealing
with in-depth investigations of the response of advanced aerospace materials to
various manufacturing operations in the scope of robust manufacture of safety-critical
aero-engine components.
The project will deal with the micromechanics and in-depth
materials analysis of advanced aerospace materials upon manufacturing
operations to understand the material`s response to the manufacturing process
to efficiently support the manufacture of aerospace components. This will
involve using a wide range of sophisticated testing and analysis techniques
including not only the study of the conventional manufacturing process of
advanced aerospace materials but also the state-of-the-art materials
investigation such as Scanning electron microscope (SEM), X-ray diffraction
(XRD), Electron backscatter diffraction (EBSD), Transmission electron microscope
(TEM) and in-situ micromechanics.
Deadline: 30 June 2024
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(19) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Rolls-Royce
sponsored PhD scholarship – Computer vision and robot control for performing
on-wing repair of aero-engines
Rolls-Royce University Technology Centre (UTC) in Manufacturing
and On-Wing Technology, The University of Nottingham.
Applicants are invited to undertake a 3-year PhD program in
partnership with industry to address key challenges in on-platform
manufacturing engineering. The successful candidate will be based at The
Rolls-Royce University Technology Centre (UTC) in Manufacturing and On-Wing
Technology at the University of Nottingham.
This project is about the technical needs of Rolls-Royce to
develop smart and robotic solutions to enable in-situ/on-wing repair and
maintenance of gas turbine engines.
At the Rolls-Royce UTC at the University of Nottingham, we
have developed robotic systems capable of navigating into crammed/hazardous
environments and performing inspection and active operations such as machining.
This is driven by the need to complete repair tasks without disassembly of
industrial installations. We developed a series of continuum robots in both
short and long versions.
Deadline: 30 June
2024
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(20) PhD Degree – Fully Funded
PhD position summary/title: Fully Funded Coating PhD
Studentship with Rolls Royce Thermally Sprayed Coatings to Inhibit Bondcoat –
Ceramic Matrix Composite (CMC) Interactions
The aerospace industry is committed to moving towards
environmentally friendly solutions using space-age materials like CMCs, mainly
made of silicon carbide (SiC) fiber in a SiC matrix. The CMCs only have a
density of 3.21 g/cc, significantly improving weight and performance to reach
NetZero in Aviation and hydrogen economy; however, CMCs rely extensively on a
multi-layered coating system called EBC: a bottom layer of silicon and a top
layer of ytterbium disilicate to protect them from steam.
This PhD project will focus on the design and development of
Brand-new strategies for Surface Engineering and Coatings Solutions for CMCs,
including using the UK`s only high-power axial injection Suspension Plasma
Spray (SPS), >1300 C temperature testing in flowing steam, coating characterization
with electron backscattered diffraction, transmission electron microscopes and
Raman spectroscopy. SPS is a coatings deposition technique where material
feedstock is injected in a plasma jet, melted, and accelerated towards a
substrate, where it rapidly solidifies and forms a coating. This is a hugely
exciting project for an enthusiastic researcher who wishes to forge an academic
or industry career in the aerospace sector.
Deadline: 03 July 2024
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(21) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Rolls-Royce
sponsored PhD scholarship – Laser Beam Processing of Aerospace Materials
Applications are invited to undertake a 3-year PhD program
in partnership with industry to address key challenges in manufacturing
engineering. The successful candidate will be based at the Rolls-Royce
University Technology Centre (UTC) in Manufacturing and On-Wing Technology at
The University of Nottingham.
We are seeking applicants for an anticipated October 2024
start, or earlier (depending on the candidate availability, on a project with
Rolls-Royce plc. The Rolls-Royce funded Studentship is the result of the
expanding its on-platform repair activities sponsored at the Rolls-Royce UTC
dealing with investigations on the development of the bespoke high-tech laser
beam processing methods for surface treatment and repair of aero-engine
components.
The project will deal with the study of a new laser
processing method to enable in-situ surface treatment and repair of safety-critical
rotating parts and further understand the correlation between surface quality,
metallurgical characteristics, and functional performance of the components and
the key process parameters. The project will deal with the design of special
process setups, testing its working principles and performances followed by an assessment
of the part quality; this will involve the development of laser beam processing
on specific aerospace materials, and a model to understand the fundamental mechanisms
of the process to identify optimal operating conditions and followed by surface
analysis techniques (e.g. Scanning electron microscope, X-ray diffraction for
residual stress measurements, Electron Back-Scattered Diffraction and
Transmission Electron Microscopy).
Deadline: 30 June
2024
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(22) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Rolls-Royce
sponsored PhD scholarship – Design and simulation of stiffness-adjustable
robotic systems for performing on-wing repair of aero-engines
Applicants are invited to undertake a 3-year PhD program in
partnership with industry to address key challenges in on-platform
manufacturing engineering. The successful candidate will be based at The
Rolls-Royce University Technology Centre (UTC) in Manufacturing and On-Wing
Technology at the University of Nottingham.
This project is about the technical needs of Rolls-Royce to
develop automatic and hybrid tooling solutions to enable in-situ/on-wing repair
and maintenance of gas turbine engines.
At the Rolls-Royce UTC at the University of Nottingham, we
have developed robotic systems capable of navigating into crammed/hazardous
environments and performing inspection and active operations such as machining.
This is driven by the need to complete repair tasks without disassembly of
industrial installations.
Deadline: 30 June 2024
(23) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Next-generation
bio-instructive materials for healthcare applications
The care and management of wounds is an ever-increasing
challenge with greater numbers of hard-to-heal wounds associated with microbial
biofilms driven by aging populations and increased prevalence of diabetes
creating additional burdens on international healthcare systems. Recently,
droplet microfluidics has been used to develop crosslinked, functionalized 3D
polymer microparticles to promote wound healing. This project aims to create a functionalized,
bioresorbable microparticle system that can promote wound healing over 21 days.
Using hydrogel materials also opens the possibility of adding an active agent
in the core for further functionality, which could be explored during this
project.
An ideal candidate will have an interest in microfluidics,
healthcare applications, and the knowledge of materials science alongside a
strong motivation to develop a world-leading expertise. The successful
candidate will have a background in chemical engineering, chemistry, materials
sciences, or a related field but be willing to learn new disciplines to achieve
the project goals. You will develop skills in materials characterization
including advanced spectrometry techniques such as NMR and ToF-SIMS as well as
microscopy and chemical synthesis techniques.
Deadline: 28 June 2024
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(24) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship – High-Speed
Railway Degradation Modelling
Applications are invited for this 4-year PhD project, from
suitably qualified graduates to work in the Resilience Engineering Research
Group, based in the Faculty of Engineering, University of Nottingham. The
University has worked with Network Rail, as its Strategic University Partner in
Infrastructure Asset Management, for over 10 years and our Research Group specializes
in the development of models to support the asset management process.
Deadline: 11 June 2024
(25) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Rolls-Royce
sponsored PhD scholarship – Mechatronics system for hybrid manufacturing
processing
Applicants are invited to undertake a 3-year PhD program in
partnership with industry to address key challenges in on-platform
manufacturing engineering. The successful candidate will be based at The
Rolls-Royce University Technology Centre (UTC) in Manufacturing and On-Wing
Technology at the University of Nottingham.
At the Rolls-Royce UTC, we are developing the next
generation of robots and their sensing solutions to perform tasks in
challenging working environments. This project is related to the development of
smart mechanisms and sensing to support the aforementioned tasks with the
following actions:
•Develop the principles and theories for governing the
scalability principles for building foldable and reconfigurable end-effectors
that can access geometrically complex workspaces under positional restrictions.
•Develop smart control algorithms that will allow the
end-effectors to communicate with the central control system and coordinate
tasks with other end-effectors and host robots.
•Smart sensing systems to support automated manufacturing
and maintenance, repair & overhaul. We refer here not only to conventional
sensing, e.g. vision, and orientation, that are commonly integrated on the
end-effectors, but to advanced (e.g. tactile, sound-based, shape) solutions
that enhance the perception of the end-effectors so that versatile tasks can be
performed.
Deadline: 30 June 2024
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(26) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Cancer cell
diagnostics using biomechanics and artificial intelligence
The prognosis of cancer is an extremely challenging task.
Treatments often deliver a different outcome on similar patients. Currently,
there is a major global push to develop technologies that allow the inclusion
of a larger and wider range of biomarkers. These are key to ensuring treatments
are appropriate for patients. One potential biomarker is given by the
mechanical properties of cells and tissue; however, these remain largely uncharacterized.
By using phonon microscopy and artificial intelligence, you
will have the opportunity to demonstrate the existence, relevancy, and
applicability of mechanical biomarkers in the determination of the state and
progression of cancer cells by the use of novel imaging, and sensing
techniques. You will work with both experts in cancer and optoacoustic
instrumentation to deliver new insights into the mechanical properties of
cancer and their relationship with disease progression.
Deadline: 07 June 2024
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(27) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Super-optical
resolution imaging using a phonon probe microscope
We are seeking PhD students who are motivated, curious, and
passionate about scientific research. Together we will make technological
advances in imaging research technologies that can close in maximum resolution
currently achievable with non-invasive imaging techniques. These are extremely
relevant for biomedical applications, particularly if they lead to the characterization
of mechanical properties.
Imaging and characterizing biology is an extremely difficult
task. Understanding biological cells as the building blocks of life is
fundamental for biology and healthcare. Cells however exhibit very little
intrinsic contrast when imaged with light and due to their dimensions, are very
difficult to study alive and unperturbed. The short wavelengths (i.e. UV) or
fluorescent dyes required to resolve fine features of cells are damaging.
Therefore, imaging cell subcomponents at high resolution often requires
electron microscopes which can only image dead and dehydrated cells.
Alternatively, sound carries less energy than light so short acoustic
wavelengths (~300nm) are not damaging to living tissue.
Deadline: 07 June 2024
(28) PhD Degree – Fully Funded
PhD position summary/title: PhD Project – High-Speed Railway
Degradation Modelling
Applications are invited for this 4-year PhD project, from
suitably qualified graduates to work in the Resilience Engineering Research
Group, based in the Faculty of Engineering, University of Nottingham,
University Park. The University of Nottingham has worked with Network Rail, as
its Strategic University Partner in Infrastructure Asset Management, for over
10 years and our Research Group specializes in the development of models to
support the asset management process.
High-speed railway infrastructure is a complex arrangement
of systems and structures, which includes: track, switches, drainage, signaling,
power supply, and communications, in addition to the civil structures
comprising earthworks, tunnels, bridges, and stations. As the railway is utilized, these assets
will wear and their condition will deteriorate. This can mean that they pose an unacceptable
risk of accidents occurring, such as derailments or train collisions, or the
expenditure to undertake interventions to improve their condition will become
excessive. To ensure that the railway is
both safe and cost-effective, plans must be in place to renew the poorly
performing elements at the appropriate time. To support the process of deciding
when renewals will take place, mathematical models are needed to indicate the
contribution that the assets make to the safety risk, and also the expected
costs of their maintenance.
Deadline: 07 June 2024
(29) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Ultra-thin
opto-acoustic fibre optic probe for cancer characterization.
Develop an ultra-thin, bio-compatible, fiber optic
ultrasound instrument and a model to predict the mechanical properties of soft
matter. This novel device, based on the interaction between acoustic interface
waves with the sample will provide mechanical property information across a
range of length scales allowing measurements on cells through to tissue. The
devices will be compatible with fiber optic delivery and proof of concept
experiments in vitro on micro-tumors will be demonstrated, paving the way for the
development of currently unmet clinical applications.
Deadline: 01 June 2024
(30) PhD Degree – Fully Funded
PhD position summary/title: 3-year PhD studentship: 3D
printing of low dimensional materials for sensing
Applications are invited for a fully funded PhD studentship
(3 years) within the Faculty of Engineering at the University of Nottingham.
The student will work with an interdisciplinary supervisory team with expertise
in 3D printing, functional low-dimensional materials, and sensing.
We seek to use 3D printing to create novel multi-material
functional structures capable of new ways of sensing underlying material
properties. We will use low-dimensional materials, including graphene,
perovskites, and nanodiamonds incorporated into polymers, ceramics, and glasses
and we will use 3D printing to form them into geometrically complex structures.
We will explore how low-dimensional materials behave when included within a 3D
printed matrix, and we will use their functionality to design and create
sensors that can be used for, e.g., examining tissue health or failure in
structures under load.
Deadline: 31 May 2024
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(31) PhD Degree – Fully Funded
PhD position summary/title: 3-year PhD studentship:
Functional Devices and Structures through 3D Multi-material Printing Scale-Up
Inkjet printing allows multiple materials to be 3D-printed
simultaneously, rather than sequentially, allowing for highly complex
structures and devices. Discovering the interactions of these materials and how
to leverage this advanced manufacturing process will open new opportunities:
structures and devices with mechanical and chemical properties that vary across
dimensions; fully 3D-printed electronics integrated into structural components;
and devices with mechanical or electrical responses encoded into their
structure. However, we don`t yet know how to design these complex printed parts
and are still developing new leading-edge materials to grant them new
capabilities.
In this PhD studentship, you will develop the materials,
methods, and designs necessary to 3D-print never-before-created devices. You
will investigate how to control the 3D distribution of differing functional
materials, aiming to create graded properties, graded chemistries, and
3D-integrated components. In this role, you will develop new engineering
solutions only possible through multi-material additive manufacturing. You will
have access to the equipment and expertise of the Centre for Additive
Manufacturing (CfAM), one of the largest 3D printing research groups in the
world. Here, you will take advantage of unique leading-edge multi-material
inkjet 3D printing equipment, only available at CfAM, which will open new
opportunities to scale up your research of designs and materials.
Deadline: 01 June
2024
(32) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Autonomous
Bioactivity Searching
This 36-month funded PhD studentship will contribute to
cutting-edge advancements in automated drug discovery through the integration
of high data-density reaction/bioanalysis techniques, laboratory automation
& robotics, and machine learning modeling. This exciting project involves
the application of innovative methods such as high-throughput experimentation
to expedite the synthesis (and bioanalysis) of life-saving pharmaceuticals. The
subsequent data will then be used to populate machine learning models to
predict which molecules to synthesize next, to maximize the binding affinity of
the molecules to a target protein. The research will be conducted using
state-of-the-art equipment, including both commercial tools and bespoke
in-house apparatus. As a key member of our team, you will play a pivotal role
in advancing the frontiers of drug discovery, laboratory automation, and the modeling
of chemical data.
Deadline: 31 May 2024
(33) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Design and
fabrication of multi-metal components for nuclear fusion applications
The vision for next-generation Additive Manufacturing (AM)
is to control the composition of every deposited volume to make functional
materials (FMs) directly from digital designs. These FMs could replace
assemblies that are currently made by joining multiple components and could
also significantly enhance performance by engineering the mechanical properties
at a small scale. For fusion energy, the
most immediate application of this technology will be in the creation of two
metal parts (e.g., W-Cu) that can act as either plasma-facing components or
heat-transfer interfaces.
The objective of this PhD project is to address the
knowledge gap around metallic FMs and establish new design methods for
multi-metal AM. To achieve this, the project will focus on determining the
structural and thermal behavior of the interface regions of the printed
component, where dissimilar materials are in contact.
The project builds on the Centre for Additive Manufacturing
(CfAM)`s expertise in applying computational materials science techniques to
laser AM. The PhD student will be able to conduct research using a
state-of-the-art multi-beam laser powder bed fusion platform equipped with a
multi-metal deposition system (a one-of-a-kind facility in the UK). This partnership with UKAEA is intended to
ensure the multi-metal AM technology is guided appropriately toward a high-end
application and to see that the technology more broadly is developed in a way
that aligns with the UK`s fusion science and advanced manufacturing goals.
Deadline: 31 May 2024
(34) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Joint modeling
of latent trajectories for dynamic prediction of competing outcomes in patients
with liver disease
Liver disease is a common cause of illness and death that is
increasing in Western countries such as the UK and Denmark, particularly for
people under 65 years old. However, the population of liver disease patients
consists of people who differ concerning both their cause of disease and
additional factors such as co-existing conditions and their general medical
history. Consequently, disease progression varies substantially: some patients
may die early from their liver disease, others might be more at risk of death
from causes unrelated to liver disease, whereas for other patients their liver
disease does not impact overall survival.
Modelling links between patient data on past and current
medical history (e.g. blood test measurements collected over time) and liver
disease progression helps clinicians to identify variables associated with
different disease patterns and, ultimately, will allow predictions to be made
for key patient outcomes such as survival/mortality.
This studentship combines novel methods in dynamic
prediction, longitudinal data analysis, survival and competing risk models, and
latent class modeling within a probabilistic framework. The goal is to develop
methods to significantly change how we care for patients with liver disease by
identifying whether patients would benefit from specialist care, which
specialty, and when or when not to intervene within the reality of a
resource-stretched healthcare system.
Deadline: 31 July 2024
(35) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Assessing the
impact of deep shafts in urban areas
Construction of large and deep shafts in urban areas is
necessary for various construction activities, such as tunnel construction
where shafts serve as integral components of the tunnel construction and often
operational phases. As tunnels are constructed ever deeper due to the
congestion of underground space, so must the shafts be sunk to deeper levels.
Shafts may suffer stability issues as a result of various factors, which can,
in the worst case, result in catastrophic failures, or more typically in ground
movements. These ground movements, which can have serious and detrimental
effects on nearby existing structures and infrastructure in urban areas, are
the topic of this PhD project.
The PhD student will work with Professor Alec Marshall and
Dr Charles Heron of the Nottingham Centre for Geomechanics alongside Dr Benoit
Jones from INBYE Engineering. The PhD studentship will be partly funded by the
British Tunnelling Society (BTS). The successful candidate will benefit from
the direct involvement of industry through Dr Jones and representatives of the
BTS – ensuring that this PhD project is directly relevant to today`s industry
needs and ensuring that project outcomes have an immediate impact on industry
practices.
Deadline: 31 May 2024
(36) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Novel
subsurface Raman microscopy technologies to enable the development of
next-generation drug and implant therapies
In this project, the student will develop various approaches
to allow deep Raman spectroscopy. These approaches will rely on computer modeling
of light propagation in tissue to understand how to deliver and collect
efficiently light from the desired region of interest into tissue. This
information will then be used to design and build optimized instruments, which
will then be used to carry out experiments. The project will explore the use of
spatial light modulators and implantable wireless optoelectronics to maximize
the penetration depth, spatial resolution, and sensitivity to the required
molecular markers.
This project is based on a long-term research collaboration
between the biophotonics Group (School of Physics and Astronomy), School of
Life Sciences, and School of Pharmacy, currently funded by the National Centre
for Replacement, Refinement, and Reduction of Animals in Research (NC3Rs https://www.nc3rs.org.uk ). Thus, this
project is an excellent opportunity for interdisciplinary training. Funding
includes a stipend, tuition fees, research consumables, and travel to
international conferences.
Deadline: 03 July 2024
(37) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Mandatory ESG
Reporting, Capital Allocation and the Green Behavior of Firms
Therefore, this PhD project investigates the impact of
mandatory ESG reporting on firms` capital access, capital allocation, and green
behavior, including but not limited to environmental performance and green
innovation. It also explores how these effects change when combined with
environmental regulations and innovation incentives.
The project will employ statistical analysis and econometric
modeling of panel data at the firm level to address the research questions.
Data will be collected from various sources, including existing databases,
satellite-derived data, and web scrapping, all requiring advanced data
manipulation and coding skills. The PhD student will work with Dr Jing Zhang
and Professor Robert Elliott, gaining opportunities to develop and enhance
their proficiency in research, advanced quantitative methods, data skills, and
machine learning methods for effectively handling micro-level panel data,
providing valuable skills for future careers.
Deadline: 12 June 2024
About The University of Nottingham, Nottingham, England –Official
Website
The University of Nottingham is a public research university
in Nottingham, England. It was founded as University College Nottingham in 1881
and was granted a royal charter in 1948. The University of Nottingham belongs
to the research-intensive Russell Group association.
Nottingham`s main campus (University Park) with Jubilee
Campus and teaching hospital (Queen`s Medical Centre) are located within the
City of Nottingham, with several smaller campuses and sites elsewhere in
Nottinghamshire and Derbyshire. Outside the UK, the university has campuses in
Semenyih, Malaysia, and Ningbo, China. Nottingham is organized into five
constituent faculties, within which there are more than 50 schools,
departments, institutes, and research centers. Nottingham has more than 46,000
students and 7,000 staff across the UK, China, and Malaysia and had an income
of £792.2 million in 2021–22, of which £131.4 million was from research grants
and contracts. The institution`s alumni have been awarded one Nobel Prize, a
Fields Medal, and a Gabor Medal and Prize. The university is a member of the
Association of Commonwealth Universities, the European University Association,
the Russell Group, Universitas 21, Universities UK, and the Virgo Consortium,
and participates in the Sutton Trust Summer School program as a member of the
Sutton 30.