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Research Project
Physics Center of Minho and Porto Universities
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Publications
Antimicrobial and Antibiofilm Properties of Fluorinated Polymers with Embedded Functionalized Nanodiamonds
Publication . Nunes-Pereira, João; Costa, Pedro; Fernandes, Liliana; Carvalho, Estela O.; Fernandes, Margarida M.; Carabineiro, S.A.C.; Buijnsters, Josephus; Rial Tubio, Carmen; Lanceros-Mendez, Senentxu
Environmentally resilient antimicrobial coatings are becoming increasingly required for a wide range of applications. For this purpose, nanocomposite thin films of poly(vinylidene fluoride) (PVDF) filled with several types of functionalized nanodiamonds (NDs) were processed by solvent casting. The effects of ND inclusion and functionalization in their morphological, structural, optical, thermal, and electrical properties were evaluated taking into account the type of the nanofiller and a concentration up to 2 wt %. The morphology, structure, and thermal features of the polymer matrix are governed by the processing conditions, and no noticeable changes occurred due to the presence of the ND fillers. The polymer crystallized mainly in the α phase with a crystallinity of ≈60%. In turn, the optical transmittance from 200 to 800 nm and the dielectric constant effectively depended on the ND type and content. The inclusion of the ND particles effectively provided antimicrobial properties to the films, which depended on the ND functionalization. This study thus shows that the incorporation of functionalized NDs into PVDF allows the development of antimicrobial coatings with tailorable optical and dielectric properties, which could be of great importance to face nowadays pandemic crisis scenario.
Property characterization and numerical modelling of the thermal conductivity of CaZrO3-MgO ceramic composites
Publication . Carneiro, Pedro; Maceiras, Alberto; Nunes-Pereira, João; Silva, Pedro Dinho da; Silva, Abilio; Baudin, Carmen
Three composite materials with different CaZrO3/MgO fractions (2/3, 1/2, 1/3) and two single-phase materials
(CaZrO3 and MgO) were fabricated and their thermal conductivity was investigated.
Complete thermal and mechanical characterizations (thermal expansion coefficient, thermal diffusivity, specific heat, hardness and toughness) of the materials were performed. Values of the thermal conductivity up to
480 ◦C of the composites were compared with those calculated with the main analytical models. From the real
microstructures of the three composites, representative volume elements (RVE) were built and used for finite
element modelling (FEM) of thermal conductivity using conductivities of the single-phase materials as inputs.
The FEM results showed no differences for the 3 spatial directions of the RVE, nor for the different edge lengths
(11, 14 and 17 μm).
Results of all analytical models are statistically different from the experimental ones, being those from the
Bruggeman model the closest. Results of the proposed FEM are statistically coincident with the experimental
ones, showing sensitivity to temperature variation.
Dielectric barrier discharge plasma actuators based on thermosetting composites for flow control in wind turbines blades
Publication . Nunes-Pereira, João; Rodrigues, Frederico; Abdollahzadehsangroudi, Mohammadmahdi; Pina dos Santos, Paulo Sérgio; Silva, Marco; Pereira Silva, A; Pascoa, Jose; Lanceros-Mendez, Senentxu
The massive use of fibre reinforced plastics (FRP) in several industrial sectors such as aeronautics,
aerospace, or wind turbines, raises serious environmental concerns with respect to the end-of-life of
these structures, based on their poor recyclability. The low density of FRP gives it outstanding specific
properties, such as strength and stiffness, when compared to materials with high recyclability rates, such
as metals1. FRP find several applications in structures in which the aerodynamic performance is of
extreme importance to guarantee a proper operation. In this sense, to endow these structures with the
ability to control or modulate the flow around their surface could be an extraordinary feature to improve
the performance of the structure, thus saving considerable amounts of energy and increasing its useful
life cycle, contributing in this sense also to reduce the environmental impact of the materials. This work
is focused on the development of dielectric barrier discharge (DBD) plasma actuators supported on fibre
reinforced thermosetting composites, which can be used in manufacturing of wind turbine blades: epoxy
resin and glass, aramid (Fig. 1) and natural flax fibres. DBD plasma actuators are electrohydrodynamic
devices capable of generating induced flows of a few m/s through nonthermal plasma, that can be
successfully leveraged for flow control applications2, 3. The characterization of the system was carried
out in terms of mechanical (flexural strength, strain and stiffness), electrical (power consumption,
capacitance, charge-discharge cycles) and electromechanical (induced flow velocity, electromechanical
power and efficiency) properties. The results showed the multifunctionality of the composites,
demonstrating their suitability for the application, in particular, the epoxy/glass composite with a
bending stress of ≈600 MPa, which obtained an induced flow velocity of ≈2.1 m/s with a power
consumption of ≈15.1 W, when powered by an AC signal of 11 kVpp and 24 kHz.
Comparative Evaluation of Dielectric Materials for Plasma Actuators Active Flow Control and Heat Transfer Applications
Publication . Rodrigues, Frederico; Nunes-Pereira, João; Abdollahzadehsangroudi, Mohammadmahdi; Pascoa, Jose; Lanceros-Mendez, Senentxu
Dielectric Barrier Discharge (DBD) plasma actuators are
simple devices with great potential for active flow control applications.
Further, it has been recently proven their ability for
applications in the area of heat transfer, such as film cooling of
turbine blades or ice removal. The dielectric material used in
the fabrication of these devices is essential in determining the
device performance. However, the variety of dielectric materials
studied in the literature is very limited and the majority of the
authors only use Kapton, Teflon, Macor ceramic or poly(methyl
methacrylate) (PMMA). Furthermore, several authors reported
difficulties in the durability of the dielectric layer when the actuators
operate at high voltage and frequency. Also, it has been
reported that, after long operation time, the dielectric layer suffers
degradation due to its exposure to plasma discharge, degradation
that may lead to the failure of the device. Considering
the need of durable and robust actuators, as well as the need of
higher flow control efficiencies, it is highly important to develop
new dielectric materials which may be used for plasma actuator
fabrication. In this context, the present study reports on the experimental
testing of dielectric materials which can be used for
DBD plasma actuators fabrication. Plasma actuators fabricated
of poly(vinylidene fluoride) (PVDF) and polystyrene (PS) have
been fabricated and evaluated. Although these dielectric materials
are not commonly used as dielectric layer of plasma actuators,
their interesting electrical and dielectric properties and the
possibility of being used as sensors, indicate their suitability as
potential alternatives to the standard used materials. The plasma
actuators produced with these nonstandard dielectric materials
were analyzed in terms of electrical characteristics, generated
flow velocity and mechanical efficiency, and the obtained results
were compared with a standard actuator made of Kapton. An
innovative calorimetric method was implemented in order to estimate
the thermal power transferred by these devices to an adjacent
flow. These results allowed to discuss the ability of these
new dielectric materials not only for flow control applications
but also for heat transfer applications.
Effect of Polymer Dissolution Temperature and Conditioning Time on the Morphological and Physicochemical Characteristics of Poly(Vinylidene Fluoride) Membranes Prepared by Non-Solvent Induced Phase Separation
Publication . Cardoso, V. F.; Botelho, Gabriela; Morão, António; Nunes-Pereira, João; Lanceros-Mendez, Senentxu
This work reports on the production of poly(vinylidene fluoride) (PVDF) membranes
by non-solvent induced phase separation (NIPS) using N,N-dimethylformamide (DMF) as solvent
and water as non-solvent. The influence of the processing conditions in the morphology, surface
characteristics, structure, thermal and mechanical properties were evaluated for polymer dissolution
temperatures between 25 and 150 C and conditioning time between 0 and 10 min. Finger-like pore
morphology was obtained for all membranes and increasing the polymer dissolution temperature
led to an increase in the average pore size ( 0.9 and 2.1 m), porosity ( 50 to 90%) and water contact
angle (up to 80 ), in turn decreasing the PVDF content ( 67 to 20%) with the degree of crystallinity
remaining approximately constant ( 56%). The conditioning time did not significantly affect the
polymer properties studied. Thus, the control of NIPS parameters proved to be suitable for tailoring
PVDF membrane properties.
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Funding agency
Fundação para a Ciência e a Tecnologia
Funding programme
6817 - DCRRNI ID
Funding Award Number
UIDB/04650/2020