While in the field-testing phase of this project, she developed another idea which served as her senior thesis for the Plan II Honors program. This involved a critical evaluation of current methods to predict and track outbreaks and spread of dangerous pathogens like Ebola and Dengue.
Additive manufacture of adaptive materials for communications applications Professor Patrick Grant For any antenna system there is a trade-off between antenna bandwidth wide as possiblesize small as possible and efficiency high as possible.
However, using only the current and long-standing, narrow and passive palette of materials suitable for antennas means that this trade-off is unhelpfully constrained, preventing more radical and advantageous designs such as low profile, low detectability, low power and miniaturized platforms.
This project will undertake high risk, novel research in making novel tunable materials for communication applications using our in-house state-of-the-art additive manufacture equipment. The focus is primarily on materials science and engineering by integrating design, materials and new manufacturing approaches to demonstrate practical ideas for improved antennas.
There will be two integrated areas of materials and manufacture research: Subject to contract this 3-year DPhil in Materials studentship will be funded by Dstl and will provide full fees and maintenance for a student with home or EU fee status. Information on fee status can be found at http: The research is funded by Dstl.
Applications will be considered as and when they are received and this position will be filled as soon as possible, but the latest date for receipt of applications will be 24 August Any questions concerning the project can be addressed to Professor Patrick Grant patrick.
General enquiries on how to apply can be made by e mail to graduate. Further information and an electronic copy of the application form can be found at http: Patrick Grant Super alumina: This will be accomplished by a combination of nanosized 2nd phase additions, grain boundary engineering and customised flaw size distributions produced using ternary additions of sacrificial carbon nanoplatelets or graphene.
The outcome will shift the properties of alumina towards those of SiC whilst retaining its more versatile and cost-effective processability. The properties of the nanocomposites will be understood through a range of advanced macro- and micro-mechanical property measurements and ballistic impact testing.
Any questions concerning the project can be addressed to Professor Richard Todd richard.
The experimental studies will investigate the relationships between applied total strains tensile and compressive, measured by image correlation in 2-D and 3-D and the elastic strains in the graphite crystals measured, for instance, by synchrotron X-ray and neutron diffraction.
The local effects on microstructure and its properties will be examined by correlative Focussed-Ion Beam FIB tomography, electron microscopy, Raman spectroscopy and micromechanical testing at ambient and elevated temperatures.
These studies aim to understand how tensile and compressive deformations are accommodated by competing mechanisms such as micro cracking, basal slip and twinning, and what effects this may have on the coefficient of thermal expansion.
These data will provide inputs for non-linear finite element modelling of the behaviour of graphites at elevated temperatures. The objective is to validate micro-mechanistic models for graphite deformation, and to provide the foundations for future work on irradiated graphites.
Candidates with EU fee status are eligible for a fees-only award, but would have to provide funding for their living costs from another source such as personal funds or a scholarship.A thesis submitted to Nanyang Technological University The optical properties of the nanoparticles were determined from ellipsometric analysis.
The Lorentz-Drude model was used to represent the effective dielectric Optical properties of Au nanoparticles. Prof. Dr. Damjana Drobne is head of Bionanoteam, the Research group for nanobiology and nanotoxicology at the Biotechnical faculty, University of Ljubljana.
With over twenty years of research experience, she is a full professor of Zoology and Toxicology, and the Vice head of the Department of biology. Her group Bionanoteam conducts research in . Some physical properties of PDMS are listed in Table lausannecongress2018.com is optically transparent ( – nm) [,, ], is biocompatible  forms conformal contact (van der Waals contact or molecular contact) and has a low surface free energy (is hydrophobic; contact angle with water ∼°).It has a unique flexibility with a Young’s elastic modulus of E ≈ 1–3 .
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Please expand the article to include this information. Further details may exist on the talk page. (August ). She completed M. Sc. from Amrita University, Kerala and she won first Rank in the University Examination.
She did her M. Sc Project at IIT Bombay under the Guidance of Prof. Debabrata Maiti on the topic “Catalytic palladium nano particle prepared using α-sy nucelin amyloid template”.