Fully Supported PhD Program at Ghent
University, Belgium
Fully Supported PhD Program Online applications are being
accepted by Ghent University in Belgium for a number of fully funded PhD
degrees in various Departments. The PhD program at Ghent University in Belgium
that are fully funded are listed below.
Any qualified candidate is encouraged to apply right away.
(1) Fully funded PhD Degree
Summary/title for the
PhD position: PhD Student
Urban settlements in low-lying coastal zones are often
shielded from floods brought on by storm surge and waves by a hybrid soft-hard
coastal defiance barrier. These structures combine a dike (a hard structure)
with a steep slope and a beach with a modest slope. A surf and swash zone
begins to form in front of the dike toe when the water depth at the beach is
shallower (the shallow water case). Longer waves, or "infragravity (ig)
waves," grow in height in this zone as a result of shoaling and energy
transfer from the shorter waves (ss), which diminish wave height through wave
breaking. The wave overtopping is significantly influenced by various
wave-related processes, but this relationship hasn't been well explored. The
goal of the study is to obtain more (quantitative) understanding of how ig
waves affect these processes and how to account for them when designing a
hybrid beach-dike coastal security system. Research teams from Ghent
University, KU Leuven, and the Flanders Marine Institute make up the research
collaboration. The study project is financed by the study Foundation of
Flanders (FWO). This position relates to research activities conducted out by
the Ghent University, the project coordinator.
Deadline:20 Aug
2023
See information and apply
(2)
PhD Degree- Fully Funded
PhD Position Summary
/Tittle:
PhD Student
The aggressive, fatal, and difficult-to-cure brain tumor
glioblastoma still exists. Growing evidence suggests that there is significant tumor
heterogeneity, as well as plasticity in the therapeutic response, which can
result in therapy failure. At the level of a single cell, this manifests as
several cell states that can change into one another in response to particular
environmental factors or therapeutic interventions. For the creation of new,
more potent, and less harmful treatment modalities, a thorough understanding of
the molecular and regulatory mechanisms driving therapy-induced plasticity in
glioblastoma patients is essential. This PhD thesis is incorporated within the Stitching
Tegan Canker interuniversity initiative, which aims to elucidate the molecular
underpinnings of radiation-induced tumor cell plasticity at the single cell
level. Prof. Vanessa Vermeirssen's laboratory, Computational Biology,
Integromics and Gene Regulation, or CBIGR, uses high-throughput biology within
the framework of gene regulatory networks to develop a functional understanding
of gene regulation and signaling towards personalized medicine. Our ultimate
objective is to apply this information to the creation of cutting-edge
treatment or preventive approaches for successful personal healthcare. We are
members of the Department of Biomedical Molecular Biology and the Department of
Bimolecular Medicine at the University of Ghent, where we have established
ourselves as authorities in the fields of molecular biology, omics
technologies, bioinformatics, and cancer. Additionally, we are a partner organization
of the Cancer Research Institute Ghent (CRIG), https://www.crig.ugent.be/en/prof-vanessa-vermeirssen-phd.
Deadline:10 July
2023
View details & Apply
Click Here to View All Fully Funded PhD Positions
(3) Fully funded PhD Degree
PhD Position Summary
/Tittle:
PhD Student
Even for experienced language learners, listening to a
language that is not one's own native tongue can be unexpectedly challenging.
This is particularly true if the speaker has a regional or foreign accent that
is unfamiliar. While listeners can easily adapt to variations in their original
language, it can be more challenging to do so when the language is not their
own. Language learners must be able to comprehend a wide range of accents in
English because of the language's millions of native and non-native speakers. The
project's goal is to investigate how much difficulty EFL students have
understanding speech with regional and non-native accents, what factors
particularly make speech difficult to understand, and how we can teach students
to recognize accented speech in English. To that end, you will conduct
listening studies that will teach us about how non-native listeners perceive
phonological variation and organize training sessions to improve learners'
comprehension of accented speech. You will learn more about the factors that
contribute to intelligibility issues and how training can help by working on
this project.
Deadline:10 July 2023
View details
& Apply
See also
University of Birmingham scholarships in the UK for 2023||Fully Funded
(4)
PhD Degree- Fully Funded
Summary/title for the
PhD position: PhD Student
For a study on textile modelling and characterization, we
are looking for a PhD student. The major goal of this project is to provide a
multi-scale textile modelling framework that enables precise modelling of
textile production processes such yarn unwinding from a bobbin, weft insertion
during weaving, stitching, and tufting. In addition to having a strong
numerical research focus, the experimental research track focuses on advanced
mechanical testing of textile materials and their linkages, both on a lab size
and an industry scale (for example, in-situ measurements on textile machines). We
obtain significantly greater insights into the rate-dependent behavior of
various textile materials, spanning from yarn to fabric, using techniques like
Digital Image Correlation and high speed cameras. The numerical models will
receive input from these measurements and be validated by them. To complete the
mechanical characterization of textile materials and their relationships at
various sizes for this PhD, an experimentalist is needed. The PhD researcher
will work on this extensive research project with a group of 4 researchers,
including 3 PhD students and 1 postdoctoral researcher.
Deadline:
Sep 30, 2023
View details & Apply
(5) PhD Degree- Fully Funded
PhD Position Summary
/Tittle:
PhD Student
The FNGN Lab (Functional Genomics Lab) is accepting
applications for a fully-funded, one-year computational/bioinformatics PhD
position with the potential for a three-year extension (after a favorable
evaluation) to study the regulatory landscape of genes associated with
neurodevelopmental disorders (NDDs). The FNGN Lab is a member of RARE-MED, a
multidisciplinary partnership launched in 2019 at Ghent University for
fundamental and translational research in precision medicine for rare diseases.
Although recent advances in technology have significantly increased diagnostic
yield and identified a number of novel NDD-associated genes, many disease genes
remain unidentified, and the non-coding region of the genome has also received
little attention. Therefore, the FNGN lab's goals are twofold: (1) to find and characterize
novel candidate genes linked to NDDs; and (2) to decipher regulatory mechanisms
that play a key role in both normal and abnormal neurodevelopment. The
objective of this PhD thesis is to pinpoint and define the regulatory
components that control how NDD genes are expressed early in the course of
human brain development. We'll use neural organoids, flow cytometry, and
advanced (single-cell) multi-omics methods like scRNA-seq and scATAC
seq to do this. Additionally, the PhD candidate will put up novel (single-cell)
technologies to evaluate 3D chromatin topologies in brain organoids. Your
computational work will be empirically evaluated in collaboration with members
of the experimental lab to increase our understanding of (the regulation of)
genes.
End date: July 31, 2023
View details & Apply
(6) Fully funded
PhD Degree
PhD Position Summary
/Tittle:
PhD Student
The type A influenza virus (AIV), which has 18 hemagglutinin
(HA) and 9 neuraminidase (NA) subtypes, is what causes avian influenza (AI).
Gallinaceous poultry that are exposed to the high pathogenicity strains (HPAI)
H5 and H7 develop severe systemic illness. High pathogenicity strains can
spread zoonotic diseases. With a total of 3777 recorded HPAI detections and
roughly 22 900 000 infected poultry birds in 31 European countries, the
2020–2021 AI epidemic appears to be one of the worst HPAI outbreaks to have hit
Europe. In Europe, biosecurity is the main preventive control tool, although on
some farms, such those that raise free-range housed chickens, AIV infection can
occur due to flaws in biosecurity systems. For nations without AI, viral
eradication is the chosen approach when HPAI outbreaks take place. The
situation is the same in Europe, where campaigns to eradicate them are compelled
by law. The Animal Health Law (EU 2016/429), which was just passed, allows the
European Union's member states to incorporate preventive vaccination against
HPAI in their domestic regulations. A versatile vaccination platform that
enables quick manufacture and confers a high level of protective immunity
against influenza virus strains is required because genetic drift and shift
lead influenza A virus to experience rapid molecular alterations. Inactivated
viruses or live attenuated vaccines are used in the majority of influenza
vaccine production. They take a long time to produce and use eggs to develop
the influenza virus, which increases the possibility of mutation, which may
reduce the effectiveness of the vaccine. In contrast to vaccinations based on viral
vectors, messenger RNA (mRNA) vaccines are capable of strongly stimulating the
adaptive immune system, can be quickly created, and can be produced in large
quantities using a generic method that is far less expensive. Due to their
capacity for self-replication, as-mRNAs exhibit higher and longer levels of
mRNA expression as well as increased in vivo immunogenicity, which may help
them overcome the limitations of the current influenza vaccines. Only
antibodies against the inserts are created after vaccination, therefore
serological monitoring of field infection using DIVA tests that look for
antibodies against other AI proteins will be possible. Based on these traits, as-mRNA
vaccines can support a sensible emergency and/or control measure to fend off AI
diseases.
End date: July 31, 2023
View details & Apply
(7) Fully funded PhD Degree
PhD Position Summary
/Tittle:
Fellow doctoral
The Department of Interdisciplinary Study of Law, Private
Law, and Business Law's new research group on "Law and Diversity" is
seeking a full-time (100%) doctorate fellow (M/F/X) in the area of law and diversity,
including the law of persons. The researcher's employment will be based on the
initial grant that was given to Dr. Pieter Cannot by the Special Research Fund
of Ghent University.
End date: June 30, 2023
View details & Apply
(8) Fully funded PhD Degree
PhD Position Summary
/Tittle:
PhD Student
We are thrilled to offer a highly motivated scientist a
one-of-a-kind and demanding chance to join our team as a PhD candidate in the
field of acoustics and photonics for biomedical research. This job will be
based in a joint initiative between Lille University (IEMN, France) and Ghent
University (Faculty of Pharmaceutical Sciences, Belgium), as part of the ERC
beginning grant project DYE-LIGHT, which is overseen by Prof. Félix Savage. If
selected, you will collaborate closely with the Ghent Group of Nano medicines
(Professors Stefan De Smelt and Félix Savage) and the IEMN (Professor Michael Badoni),
two of the top research organizations in the area. Your research will primarily
concentrate on the experimental creation of acoustic tweezers for in-vivo
biomedical applications. In order to capture, move, and arrange small items
remotely in vivo or in vitro, acoustic tweezers use ultrasonic acoustic waves
and a nonlinear phenomenon known as the acoustic radiation force. For in-vitro
manipulation, the Lille team created some specialized tweezers [1, 2]. You will
also investigate photonics to trap and displace small objects in vitro and in
vivo using unique light-based techniques created by the team of Ghent [3-5].
Comparing, improving, and modifying these technologies for in vivo applications
will be the goal in order to show off their exceptional potential for minimally
invasive microsurgery.
End date: July 31, 2023
View details & Apply
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