UK-France Joint Phd Programme 2016

UK-France Joint PhD programme 2016

The UK-France joint PhD programme aims to develop research in key areas of mutual interest to France and the UK. The programme was agreed at the 2010 Anglo-French Summit as one of the ten priorities in 2011 for the Anglo French Defence Research Group (AFDRG).

Expressions of interest for the programme should be submitted by Friday 4March2016. Further details and an application pack are provided herein.

Programme details

This PhD programme is jointly managed by Direction Générale de l’Armement (DGA) and Defence Science and Technology Laboratory (Dstl).

Ten PhDs were funded in 2015, five from the UK and five from France. To date, 43 PhD projects have been funded since the call began in 2011. These PhDs are investigating a varietyof topics including autonomous underwater vehicles, meta-materials, synthetic biology, sensors,vehicle armour, and human and social sciences. The intention is that (subject to the available budget and the cost of individual proposals) a further five PhDs are expected tobe funded by the UK in this latest call.

The programme is seeking proposals in the following areas of interest:

acoustic and radio-electric waves
biology and biotechnology
defence and security foresight
energy
environment andgeosciences
fluids andstructures
human and systems
information engineering and robotics
information management ‘big data’
materials andnano-technologies
photonics

Acoustic and radio-electric waves

generation and measurement of radiation
wave propagation
detection and imaging
electromagnetic compatibility and bio-electromagnetics
communication in complex and harsh environments
detection, location and identification of objects, which may have a low signature, in complex environment and harsh environments
protection of systems

Biology and biotechnology

•risk analysis and modelling

knowledge and characterization of current and emerging Chemical, Biological and Radiological(CBR) agents
risk modelling, simulation and prediction

•detection, identification (to include Synthetic Biology approaches) of CB agents within complex clinical, environmental samples

multiplex, fast, sensitive, specific and portable technologies
integrated, miniaturized in-field systems

innovative miniaturized DNA sequencing technologies
collection, conservation and preparation of complex samples (at room temperature)
novel tools for rapid phenotypic analysis of antimicrobial susceptibility/resistance
technologies for point of care diagnostics in low resource environments
enhanced tools and techniques for identification of non-nucleic acid based (phenotypic) biomarkers of infection

•protection, decontamination

mild decontamination (phages, synthetic biology, nanoparticles, physical techniques…)
control/modelling of physico-chemical, toxic- filtering media interaction mechanisms

•forensic microbiology to attribute an event to a source

high-throughput sequencing applied to analysis of DNA traces

•medical countermeasures

early diagnosis (exposure biomarkers)
infectious risk (new classes of broad-spectrum antimicrobials)
prevention and treatment of organophosphorus nerve agent poisoning (long-term neurological sequelae)
in-field radiological dosimetry
Physiology and treatment

•UK/France deployed medical interoperability

deployed Medical Laydowns
clinical equipment / tactics, techniques and procedures (TTPs)
casualty classification systems

Defence and security foresight

How the opportunities and risks to defence and security that emerge from future developments in science and technology (S&T) can be better assessed and addressed. The influence of cultural, historical, ethical, economic, societal and political factors on how S&T is developed and utilised in future to present opportunities and threats for defence and security.

the changing balance between civil sector and government driven investment
national and international research collaboration
reliability of transnational infrastructure and supply chains
globalisation of knowledge
differences in processes, approaches and perceptions
recognising and embracing uncertainty and bias
modelling, visualisation and communication of trends, forecasts and results
anticipating and overcoming barriers to the valuable exploitation of new technology for defence and security, avoiding the ‘Valley of Death’

Energy

materials for energy storage pulsed power, transient or permanent (electrochemical, magnetic, thermodynamic, etc.)
advanced materials for electrochemical energy storage (capacitors, supercapacitors, batteries)
concepts of innovative materials for thermal management in electrical engineering
materials that contribute to improve the capacity of fuel cells
new concepts for alternative fuels and synthesis of new fuels

Environment and geosciences

Characterising and understanding the environment is critical to successfully delivering capability from and to the battlespace. Developing faster and more accurate representations of the environment and cost-effective environment data gathering.

bathymetry, gravimetry and geomagnetism: observations, gain in resolution, data reliability and accuracy
marine geology: nature and description of marine sediments, particle transport, bottom evolution
acoustic oceanography: acoustic description of the marine environment, ambient noise, tomography
oceanic circulation: dynamics at low and meso-scale and hydrological characteristics of areas of defence interest
swell and modelling of sea status: observation, modelling
marine biochemistry and biological/physical interactions (in relation with turbidity and bioluminescence)
meteorology and atmosphere physics
integrated climatology by weather type or regime
forecast of local atmospheric phenomena as well as in the low atmosphere layers:
fog and teledetection, coastal fog
cloudiness/rain systems, radiation
atmosphere/ocean interactions in lower atmospheric layers
continental environments
soils:
surface layers, mechanical and sedimentary characterisation
cartography
relation with the water cycle (precipitation/infiltration/runoff), soil behaviour
links with the hydro systems: soils/aquifers relationships, modelling

improving modelling and simulation
combining measurements with modelling

Fluids and structures

complex regimes of fluid or reactive flows
aerodynamics of complex shapes
numerical simulation of multi-fluid or multiphase flows
flow control (simulation, technologies for actuators)

structural strength against heavy and dynamic loads
modelling loads (blast, solid impacts)
structural behaviour (dynamic effects, damage, breaking, ultimate resistance)
solutions for protection (concepts, simulation)
mechanical noises (fluid, solid) in underwater environment
noise generated by submarine systems (coupling between flow and vibration, internal vibro-acoustics)
radiated noise (internal sources of vibration, motion-induced vibration, transient phenomena)

Human and systems

The study of society and the manner in which people behave and impact in the world around us is fundamental in our approach to both defence and security. This is vastly complex, crossing disciplines such as sociology, political studies, psychology, criminology, and economics. To be truly effective in defence and security operations today we need to harness this and are interested in the following priority areas:

to understand our adversaries on the battlefield, and understand the civil populations to which we bring stability and security
to understand the motivating factors that cause someone to support or commit acts of violent extremism
to better identify suspicious behaviours of those who wish to do us harm
improving human resilience against cognitive, mental and social vulnerability
new concepts to improve learning, engineering processes, workspaces, efficiency of interactions and collaborative work
exploiting human and social sciences to enhance defence’s systems or capability requirements
autonomy (semi-autonomous through to full autonomy)
medical applications – eg telemedicine or automated surgery on deployment

end to end supply chain – all elements probably now possible to one degree or another but how can they be made to work as an effective and efficient system? Interfaces, accuracy, where greatest changes would be from traditional approach, incremental adoption or big bang?
repair/maintenance – how to diagnose problems and subsequently repair equipment on deployment
equipment recovery - both remote operated as an interim 2025 goal and fully autonomous for 2035, what functions and processes would benefit most from automation?

augmented reality
engineering support applications – use for training or deployed repair and maintenance, impact on required skillsets/engagement

•data management

the cloud - how can cloud /centralised based systems be exploited for rapid access to data, decision making tools, training aids and Defence publications?
configuration control, single version of the truth, data /information sharing, level of required security?

Information engineering and robotics

• communications and security

• digital signal and image processing and knowledge extraction

• complex systems, robots andcognitive systems

For defence security capabilities (such as command, control, communication and computers, intelligence, surveillance and reconnaissance (C4ISR), critical infrastructure protection, cybersecurity missions), the issue is to drive information communications technologies and the underlying science towards a goal of maximal efficiency for systems, according to the nature of their operating environment (highly complex, partially known, uncooperative, time sensitive / real time) and interfacing constraints.

Digital technologies therefore cover a wide area from tactical (e.g. soldier’s equipment) to strategic (e.g. large C4ISR infrastructures) systems, with the absolute necessity to meet performance requirements everywhere at the subsystem level: sensors, data links, information processing tools… up to global control and monitoring.

• complex information processing

Various data sources: text, multimedia, video, logs, IP flux, software codes, imagery (infrared, visible, hyperspectral, Lidar, Synthetic Aperture Radar (SAR)), radar, sonar. Various applications: observation, intelligence, cyber defence, robotics, environment /behaviour perception, target detection /recognition / identification, navigation and localization, tracking, early warning, situation awareness … Various techniques: signal and image processing, language processing, heterogeneous information fusion, tracking, clustering, [big] data mining, artificial intelligence, machine learning.

• secure, reliable and robust systems

Hardware and software security, data and exchange integrity and authentication, networks supervision, mobile ad hoc networks (MANETs), reliability of software, hybrid and embedded systems.

• embedded/distributed decision

Inter-connected (socio-technical or cyber-physical) systems, increased/adjustable autonomy for robots, decision aid, smart sensors, multi-agent systems (eg robot swarms), behaviour simulations, serious games for training or situation awareness.

Information management ‘big data’

There is the need to capitalize on the pervasive, data rich world in which we live. However this is a task made difficult by the sheer size, heterogeneity, incompleteness and error prone nature of digital data. Key challenges include the detection of relevant data in large (petabyte+) sized samples, deriving meaning from it and presenting it to humans in an understandable form. Innovative proposals are sought to research into this challenging area. As a guide, subject areas may include:

methods to detect “important” data in very large (petabyte plus) data sets
unconventional methods for effectively fusing data captured from a range of open media (video, audio, textual) and data from social graphs
databases and other information to determine key patterns and trends that are ‘of interest’ to national security and defence?
can fused multimodal data with other information tell us whether we have seen something or someone before, or better anticipate events and give near real‐time responses?
methods of determining links between otherwise disparate data sets
methods of combining heterogeneous data and data sets
methods of analysing / synthesising error rich heterogeneous data

Materials andnano-technologies

polymer aging (increased storage life, ability to measure remaining potential life)
structural bonding (maritime domain):

qualification process: test methods, key parameters, criteria
accelerated ageing
Non-destructive evaluation (NDE)/non-destructive testing (NDT) of bonded joint

rubbers, elastomers, adhesives and sealants (aeronautic domain):

accelerated ageing methods
key parameters to evaluated aging
control and measurement of these key parameters

metamaterials:
development of low loss magnetodielectrics for lens synthesis
design and manufacture of metamaterials (especially transformation metamaterials eg pushing envelop of multi-material additive or bottom-up fabrication at microwave through to optical wavelength scales)
autonomous vehicles, focussing on:
modular assembly
power (eg batteries)
electronics integration

nanomaterials
understanding the potential for harm from using nanomaterials in military systems (eg when damaged etc.)
new materials
development of higher temperature aluminium alloys for lightweight small [air] engines
lead-free piezoelectrics for SONAR applications (including single crystal materials)
synthetic biology approaches to develop novel materials for protection or armour applications, self-healing materials, biocompatible materials, materials that have enhanced resistance to corrosion, novel adhesives

novel methods for fabrication of functional materials (eg 3D printing)

Photonics

•sources and laser systems

•imaging systems

•materials for optics

semiconductor vertical-cavity surface-emitting laser (VCSEL) / vertical-external-cavity surface-emitting-laser (VECSEL) devices with phase control
novel use of liquid crystal on silicon (LCOS) devices for laser beam control
high power 2 um laser sources
Infrared fibres for beam delivery, switching and control
chalcogenide glasses for compact infrared optical systems
optical dielectric coatings with eye-centred design for laser protection

•time-frequency metrology

•information and quantum computing

•innovative solutions for detection of hazardous materials

laser source and imaging for detection, identification and diagnosis: broadly tuneable finite impulse response (FIR) (5-14 um) sources, narrow linewidth tuneable sources for gas detection
infrared detector technologies: techniques to reduce noise and increase operating temperature – barrier devices, optical antennas
passive/active spectrometry: Single photon counting detector arrays in the extended-Short Wave Infrared(SWIR) waveband

•use of short pulse lasers

terawatt laser for remote effects
novel sensing and exploitation of quantum effects

These areas represent French and UK scientific prioritiesin the defence domain.

Selection process

The intention is for the successful PhDs to be co-supervised by aFrench and a UK supervisor.

In addition, PhD students (UK or French nationals only) will be expected to spend time at both the UK and French institutes over the course of the PhD. Given this, applicants should have, or demonstrate a plan to develop, strong English and French language skills.

Proposals are requested from universities or appropriate labs in the areas of interest and should propose a suitable candidate (if known at this stage) and a French co-supervisor.

The deadline for expressions of interest is12:00on Friday 4March 2016. Additional key dates are as follows:

7 to 18March – review of applications
21March – write to applicants informing them of the outcome, successful applicantswill now need to prepare a full proposal
12:00 on 8 April – all full proposals to be submitted
11 to 22April – review of full proposals
Mid May – inform applicants of the outcome

Review assessment and criteria

The decision making criteria and some key details relating to them are provided below:

Defence interest

How important is this problem to defence andsecurity and how does it affect current / future capability? What is its operational relevance? In particular, how will this PhD:

enhance the effectiveness of field capabilities, and / or
lead to the creation of completely new concepts / disruptive technologies, and / or
lead to the creation of technologies that inspire new ways of working, and / or
enable agility, flexibility and adaptability?

Scientific quality and innovation

What is the state of the art/possible in this area and how is this proposal new and innovative? What key piece of science does this project seek to develop and what is its value?

Technical / scientific approach

Define:

what hypothesis does this PhD seek to prove/disprove?
what goal does this PhD seek to achieve and, thus, what are its objectives?
how will this PhD know when it has met its goal/objectives?
what is the scientific risk and how will this risk be managed?
what is the scientific risk and how will thePhD manage / mitigate that risk?
what are the outcomes / deliverables of this PhD?

Exploitation

A definition of methods by which the results of the PhD will be exploited in support of thedevelopment of capability.

Track record of PhD supervisors and university

An assessment of the track record of the supervisors and universities in:

delivery to defence
delivery of collaborative programmes with non-UK universities
delivery of research in the proposed field

Application Process

Each proposal is for one PhD, which must have a supervisor from both the UK and French academic institution. There is no limit on the number of proposals that an organisation can be involved with.

Proposals should be submitted to and should include:

completed application form
CV of proposed PhD candidate if known (UK or French National only)
CV of supervisor in the UK
CV of supervisor in France
academic reference from lead PhD supervisor
price breakdown proposal structure including a Gantt chart (or similar)
a single PowerPoint slide which summarises the scope of the proposed work

Contact details

For further information, please contact: