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2. Physical and Chemical Characterization of Plasma Sources for Bio-medical Applications

Author

Cordaro L., Cavazzana R., De Masi G., Fassina A., Zuin M., Giove A., Neretti G., Tampieri F., and Martines E.

Subjects
Plasma Sorces, Plasma Medicine
Abstract

Plasma medicine is a multidisciplinary field of science that uses cold atmospheric pressure plasmas for biomedical purposes. Several applications have been proposed in the last years, including disinfection of bacteria and fungi, wound healing, dermatological diseases and selective killing of cancer cells. Several plasma production schemes and plasma source designs have been proposed, most of which have obtained interesting therapeutic effects on biological samples. However, an overall understanding of the mechanisms that induce such benefices is still missing. Such an understanding is not trivial, considering the multiplicity of possible interactions between complex systems, such as cold plasmas and biological tissues.

Published
2021

3. Inactivation of Eimeria spp. oocysts in aqueous environment assisted by a gas-liquid dielectric barrier discharge

Author

Neretti G., Borghi C. A., Taglioli M., Poglayen G., Morandi B., Galuppi G., Tosi G., AA VV, Slobodan Milosevic , Niksa Krstulovic, Neretti G., Borghi C. A., Taglioli M., Poglayen G., Morandi B., Galuppi R., Tosi G., AAVV, and Neretti G., Borghi C.A., Taglioli M., Poglayen G., Morandi B., Galuppi G., Tosi G.

Subjects
Plasma, Eimerya, oocysts, treatment
Abstract

Among human and animal diseases agents, parasites are those that show, with very few exceptions, an environmental resistance far superior with respect other pathogens [1]. This is due to the complex structure of the wall of their infective stages, that makes them particularly resistant to almost all physical and chemical agents. In this work, a novel technique to inactivate coccidian parasites in liquid environment has been investigated and implemented. A Petri dish filled with 20 ml of water contaminated by Eimeria spp. oocysts has been placed within a plasma reactor constituted by a lower HV exposed electrode and an upper grounded copper strip electrode covered by a ceramic slab (Fig. 1). The reactor has been supplied with sinusoidal and nanosecond-pulsed voltage waveforms varying the application time. In both cases an atmospheric pressure Dielectric Barrier Discharge (DBD) has been ignited in the air gap above the liquid surface and in contact with it [2]. The temperature of the solution and its pH level were not significantly changed by plasma treatment. The concentration of ozone and hydrogen peroxide increase by increasing treatment time [2]. Plasma treatment efficacy has been detected considering a representative population of 100 oocysts. For both discharges, treatment efficacy has been found to be dose dependent (Fig. 2). After an energy dose treatment of about 100 kJ/l, the number of sporulated oocytes are roughly halved with respect the control sample. Results are statistically significant with a p

Published
2017

4. The fourth state of matter chapter II: biocidal effect of plasma against yeast

Author

Galuppi R., Neretti G., RICCHIUTO, ANNA CHIARA, Borghi C. A., Poglayen G., Morandi B., SoIPa, and Galuppi R., Neretti G., Ricchiuto A.C., Borghi C.A., Poglayen G., Morandi B.

Subjects
Annular Plasma Synthetic Jet Actuators (PASJAs), Charged particles, candida guilliermondii
Abstract

INTRODUCTION. The use of plasma for sanitization purpose is of increasing interest. Annular plasma synthetic jet actuators (PSJAs) had demonstrated their ability to produce and induced tubular flow (Neretti et al., 2017, J. Phys. D: Appl. Phys. 50 015210, 9pp) normal to the surface where the dielectric barrier discharge is ignited. This typology of reactor enhances the transport of reactive species toward the treated samples (Taglioli et al., 2016, Plasma sources Sci. Technol., 25 06LT01-5pp.). Long life charged particles are generated within the plasma region and then can be advected together with the induced flow. In this work the effect of free charges into induced flow have been tested against Candida guilliermondii both in agar plates and in water suspension. MATERIALS AND METHODS. Eighty ml suspension of C. guiliiermondii in saline solution (0.5 Mcfarland opacity) was prepared. The CFU of untreated suspension was determined performing multiple dilution that were plated on Sabouraud Dextrose Agar (SDA) petri dishes that were incubated at 26°C for 48 hours. Aliquots of 100 μl of suspension were spread on the surface of 6 SDA plates (9 cm diameter); aliquots of 20 ml of suspension were put into six 9 cm plates. Agar plates were subjected to induced flow for 30 sec, 2 and 5 minutes and suspension plates for 5, 10 and 15 minutes, both with and without blocking the charges by a grounded metallic mesh. After treating, from each suspension CFU was calculated as previous described, while in the agar plates the colonies were directly counted after incubation. RESULTS AND CONCLUSIONS. The untreated yeast suspension contained 5.21 x 105 CFU/100 μl. In treated samples, the reduction of the CFU of the yeast was related to the treatment time and to presence/absence of free charges. The effect was greater on agar plate than on suspension: at the same time of treatment (5 minutes), only 1-log reduction of CFU were observed on suspension, while 4-log reduction was observed in agar plates. Additional 1-log reduction was observed when free charges have been allowed to reach the sample. On suspension, longer treatment time (15 min) was needed to obtain 2-log reduction without free charges and 4-log reduction with free charges.

Published
2018

5. Schlieren imaging in a dielectric barrier discharge actuator for airflow control.

Author

Cristofolini, A., Neretti, G., Roveda, F., and Borghi, C. A.

Subjects
*DIELECTRICS research, *ELECTRODES, *ACTUATORS, *ELECTROHYDRODYNAMICS, *BOUNDARY layer (Aerodynamics)
Abstract

The operation of a surface dielectric barrier discharge actuator for airflow control has been experimentally investigated. The actuator is constituted by an electrode pair separated by a dielectric Teflon sheet. Several ac supply conditions have been utilized. An electrohydrodynamics interaction was induced in still air, and several fluid-dynamic regimes were obtained. Visualization of the plasma boundary layer during the discharge ignition phase and during the steady state regime was obtained by utilizing a Schlieren diagnostic technique. The vortex morphology and propagation velocities at all supply conditions utilized have been evaluated. Velocity profiles perpendicular to the actuator surface, obtained from Pitot tube measurements, and line intensity profiles, determined by means of Schlieren imaging, have been determined for the steady regime operation. The integral along a line perpendicular to the actuator surface of the light intensity of the Schlieren image has been calculated. The profile obtained is in good agreement with the Pitot velocity profile in all the supply conditions investigated. Numerical simulations were also performed. The calculations confirm the relation between the flow velocity distribution in the boundary layer and the gas density distribution, which is the cause of the Schlieren image. [ABSTRACT FROM AUTHOR]

Published
2012
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6. Electrohydrodynamic interaction induced by a dielectric barrier discharge.

Author

Borghi, C. A., Carraro, M. R., Cristofolini, A., and Neretti, G.

Subjects
ELECTROHYDRODYNAMICS, DIELECTRICS, AIR flow, SPECTRUM analysis, TEMPERATURE, ELECTRIC potential, PHYSICS
Abstract

In the present work an experimental investigation on the electrohydrodynamic (EHD) interaction effect, induced by means of a dielectric barrier discharge on a 1 atm subsonic air flow, is described. The air flow is obtained in an open circuit blowing wind tunnel at different air speeds. A plane plasma panel equipped with a dielectric discharge barrier system is immersed in the flow. A single phase sinusoidal power supply system, a superposition of a single phase sinusoidal system with a dc voltage supply, and a three phase symmetrical power supply configuration are considered. Electric, fluid dynamic, and spectroscopic diagnostic techniques are utilized. Pitot probe measurements are performed in the boundary layer on the plasma panel surface. Schlieren imaging is done to visualize the plasma sheath. Vibrational and rotational temperatures are evaluated by means of spectroscopic techniques. The force induced on the flow by the dielectric barrier discharge acts on the ions of the non-neutral sheath ahead of the plasma filament when travelling on the panel surface only. This causes a reduction of the time interval during which the force is active. The EHD effect and the momentum transfer to the gas flow in the boundary layer are reduced when the flow speed grows. An increase of the supply frequency and of the supply voltage causes an increase of the momentum transfer. In these experiments no significant increase of the efficiency of EHD effect is observed when utilizing the superposition of a dc voltage to a single phase power supply or a three phase power supply. [ABSTRACT FROM AUTHOR]

Published
2008
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7. Experimental Activities on the MHD Interaction in a Hypersonic Air Flow Around a Blunt Body

Author

Cristofolini, A., Borghi, C. A., Neretti, G., Passaro, A., Baccarella, D., Antonio Schettino, Battista, F., Andrea Cristofolini, Gabriele Neretti, Carlo Angelo Borghi, Andrea Passaro, Damiano Baccarella, Antonio Schettino, and Francesco Battista

Subjects
APPLIED MAGNETOFLUID DYNAMICS, ELECTRODYNAMICS, HYPERSONIC MHD INTERACTION
Abstract

This paper deals with the design of an experiment devoted to MHD flow control, to be performed in CIRA GHIBLI hypersonic facility. The criteria utilized to define the proper test conditions and to design and realize the model are here described. The expansion in the nozzle has been investigated through numerical simulations in order to have a preliminary estimate of the ionization degree and of the heat fluxes over the test article. Moreover, an MFD code has been used in order to calculate the expected interaction effect, under the assumption of low Rem. The same procedure has been utilized for the design of an MHD test to be performed in the CIRA SCIROCCO facility.

Published
2010

9. Charge distribution on the surface of a dielectric barrier discharge actuator.

Author

Cristofolini, A., Neretti, G., Roveda, F., and Borghi, C.A.

Abstract

The paper considers the charge deposited on the surface of a plasma dielectric barrier discharge (DBD) actuator. The actuator is utilized to induce the electro-hydro-dynamic (EHD) interaction in the aerodynamic boundary layer of one atmosphere air [1,2]. The effect on the EHD interaction of the charge distribution on the actuator surface is studied both experimentally and numerically. [ABSTRACT FROM PUBLISHER]

Published
2012
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10. Real Time Power Control in a High Voltage Power Supply for Dielectric Barrier Discharge Reactors: Implementation Strategy and Load Thermal Analysis

Author

Gabriele Neretti, Arturo Popoli, Silvia Giuditta Scaltriti, Andrea Cristofolini, Neretti G., Popoli A., Scaltriti S.G., and Cristofolini A.

Subjects
feedback control, high voltage, average power, Computer Networks and Communications, Hardware and Architecture, Control and Systems Engineering, power supply, Signal Processing, Electrical and Electronic Engineering, dielectric barrier discharge, plasma
Abstract

Atmospheric-pressure plasma treatments for industrial and biomedical applications are often performed using Dielectric Barrier Discharge reactors. Dedicated power supplies are needed to provide the high voltage frequency waveforms to operate these nonlinear and time-dependent loads. Moreover, there is a growing technical need for reliable and reproducible treatments, which require the discharge parameters to be actively controlled. In this work, we illustrate a low-cost power supply topology based on a push-pull converter. We perform experimental measurements on two different reactor topologies (surface and volumetric), showing that open loop operation of the power supply leads to a temperature and average power increase over time. The temperature increases by Delta T-vol similar to 120 degrees C and Delta T-sup similar to 70 degrees C, while the power increases by Delta P-vol similar to 78% and Delta P-sup similar to 60% for the volumetric (40 s) and superficial reactors (120 s), respectively. We discuss how these changes are often unwanted in practical applications. A simplified circuital model of the power supply-reactor system is used to infer the physical relation between the observed reactor thermal behavior and its electrical characteristics. We then show a control strategy for the power supply voltage to ensure constant average power operation of the device based on real-time power measurements on the high voltage side of the power supply and an empirical expression relating the delivered power to the power supply output voltage. These are performed with an Arduino Due microcontroller unit, also used to control the power supply. In a controlled operation the measured power stays within 5% of the reference value for both configurations, reducing the temperature increments to Delta T-vol similar to 80 degrees C and Delta T-sup similar to 44 degrees C, respectively. The obtained results show that the proposed novel control strategy is capable of following the transient temperature behavior, achieving a constant average power operation and subsequently limiting the reactor thermal stress.

Published
2022
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11. Theoretical and experimental aspects of non-equilibrium plasmas in different regimes: fundamentals and selected applications

Author

Alix Gicquel, Gabriele Neretti, Gianpiero Colonna, Laura Laguardia, Thomas Bieber, Francesco Pegoraro, Andrea Cristofolini, Arturo Popoli, Carlos D Pintassilgo, Khaled Hassouni, Olivier Duigou, Colonna G., Pintassilgo C.D., Pegoraro F., Cristofolini A., Popoli A., Neretti G., Gicquel A., Duigou O., Bieber T., Hassouni K., and Laguardia L.

Subjects
010302 applied physics, Physics, Plasma Density, non-equilibrium plasmas, cold plasmas, non thermal plasmas, plasma modelling, pIC, drift-diffusion models, Divertor, Poloidal Flux, Optical physics, Plasma, 01 natural sciences, Divertors (Fusion Reactors), Atomic and Molecular Physics, and Optics, 010305 fluids & plasmas, Computational physics, Physics::Plasma Physics, 0103 physical sciences, Nuclear fusion, Vibrational temperature, Microwave
Abstract

This paper presents recent activities covering different plasma fields, from both theoretical and experimental point of views. An overview of the present interests of the scientific community is reported here. Starting from a brief description of the role of collisions in astrophysical plasmas, some fundamental aspects of gas discharges modelling, such as superelastic collisions and the basic concept of vibrational temperature, are discussed. Different plasma sources, as DBD and microwave discharges with their own specific applications, are reported. Edge plasmas in nuclear fusion reactors are investigated, focusing on the cooling mechanisms resulting from nitrogen puffing in the divertor region. Graphic abstract: [Figure not available: see fulltext.].

Published
2021

12. A multi-stage model for dielectric barrier discharge in atmospheric pressure air

Author

Arturo Popoli, Gabriele Neretti, Andrea Cristofolini, Cristofolini A., Popoli A., and Neretti G.

Subjects
plasma processing, Materials science, Atmospheric pressure, plasma modelling, Mechanical Engineering, Dielectric barrier discharge, dielectric barrier discharge, Condensed Matter Physics, plasma actuator, Electronic, Optical and Magnetic Materials, Multi stage, Mechanics of Materials, Physics::Plasma Physics, Electrical and Electronic Engineering, Composite material, DBD plasma
Abstract

In this paper, a multi-stage numerical methodology for the description of the Dielectric Barrier Discharge physics in air is discussed. The behavior of the heavy species is computed using drift-diffusion equations. Electrons are taken into account by solving a non-linear formulation of electrostatics. The physical effects of the steamer discharges are modelled by means of a simplified 0D approach. The model also includes a semi-implicit 0D model for the assessment of the elementary chemical processes occurring in air. The developed methodology is employed for the simulation of a volumetric Dielectric Barrier Discharge reactor. The obtained species number density and surface charge deposition rates and are shown and discussed.

Published
2020

14. Self-Tuning High-Voltage and High-Frequency Sinusoidal Power Supply for Dielectric Barrier Discharge Plasma Generation

Author

Gabriele Neretti, Mattia Ricco, Neretti G., and Ricco M.

Subjects
high-voltage on-board diagnostics, Materials science, Computer Networks and Communications, non-thermal plasma, High-voltage on-board diagnostic, lcsh:TK7800-8360, Dielectric barrier discharge, dielectric barrier discharge, 01 natural sciences, 010305 fluids & plasmas, Generator (circuit theory), 0103 physical sciences, Electrical and Electronic Engineering, 010302 applied physics, business.industry, lcsh:Electronics, Electrical engineering, High voltage, 500 kHz, Power (physics), Lissajous curve, high-voltage generator, self-tuning frequency, Hardware and Architecture, Control and Systems Engineering, Modulation, Signal Processing, business, Voltage
Abstract

In this paper a high-voltage sinusoidal power supply controlled by Arduino DUE micro-controller is described. This generator can feed a dielectric barrier discharge (DBD) load with sinusoidal voltages up to 20 kV peak and frequencies in the range 10&ndash, 60 kHz, with a maximum output power of 200 W. Output voltage can be produced either in a continuous mode, or with on/off modulation cycles, according to treatment/application requirements. This power source is equipped with on-board diagnostics used to measure the output voltage and the charge delivered to the load. With a sample frequency of 500 kHz, Arduino DUE allows to evaluate both the high voltage and the average power feeding the discharge without the use of an expensive external measurement setup. Lissajous techniques are utilized to calculate discharge average power in a quasi-real-time manner. When a load is connected to high-voltage terminals, a self-tuning procedure is carried out to obtain the best working frequency. This parameter allows to minimize power-electronic component stress and to maximize generator efficiency.

Published
2019

15. Ozone yield limit in low temperature plasmas based on thermodynamics

Author

Linsheng Wei, Deng Haizhong, Gabriele Neretti, Yafang Zhang, Wei L., Deng H., Neretti G., and Zhang Y.

Subjects
010302 applied physics, Ozone, Materials science, Plasma Physics, chemistry.chemical_element, Thermodynamics, Plasma, Electron, 010501 environmental sciences, 01 natural sciences, Oxygen, Atomic and Molecular Physics, and Optics, Spectral line, chemistry.chemical_compound, Distribution function, chemistry, Yield (chemistry), 0103 physical sciences, 0105 earth and related environmental sciences, Dimensionless quantity
Abstract

To investigate ozone yield limit in low temperature plasmas, a detailed thermodynamic model is developed to calculate theoretical ozone yield for the first time. Theoretical ozone yield is calculated both from overall reaction and detailed reactions. In the former case, the highest theoretical ozone yield of 1211±2 g kWh−1 is obtained when final gas temperature equals the initial one, and all energy is effectively utilized to synthesize ozone. When final gas temperature is not equal to the initial one, theoretical ozone yield increases with the increase of oxygen admixture ratio and oxygen conversion ratio as well as the decrease of final gas temperature. Theoretical ozone yields are 921.22 g kWh−1 and 487.54 g kWh−1 in pure oxygen and in synthetic air respectively at final gas temperature of 400 K and oxygen conversion ratio of 10%. When detailed reactions and electron energy distribution function is considered, theoretical ozone yield rapidly increases by enhancing reduced field. Oxygen admixture ratio also has non-negligible effects on ozone yield. A higher oxygen admixture ratio leads to higher energy efficiency. The theoretical ozone yields are 238.92 g kWh−1 and 191.14 g kWh−1 in pure oxygen and in synthetic air at reduced field of 300 Td respectively. Graphical abstract: [Figure not available: see fulltext.].

Published
2019

16. Influence of the voltage waveform's shape and on-time duration on the dissolved ozone produced by a DBD bubble reactor

Author

Carlo Angelo Borghi, Alexander H. Shaw, Alexander R.P. Wright, Felipe Iza, Paolo Seri, H.C. Hemaka Bandulasena, Gabriele Neretti, and Seri, P., Wright, A., Shaw, A., Iza, F., Bandulasena, H., Borghi, C.A., Neretti, G.

Subjects
010302 applied physics, Ozone, Materials science, Bubble, Plasma, Mechanics, Sawtooth wave, Nonthermal plasma, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, chemistry.chemical_compound, chemistry, non-thermal plasma, ozone, voltage waveform, water, bubbling reactor, Duty cycle, 0103 physical sciences, Waveform, Voltage
Abstract

In this study we examine both the effect of changing the applied voltage waveform shape and the modulation on-time on the amount of ozone dissolved within a liquid in a dielectric barrier discharges (DBD) bubble reactor. In this device, the discharge forms at the gas–liquid interface allowing for effective transfer of the plasma effluent into the liquid. To produce different voltage waveforms, a multilevel inverter power supply capable of generating arbitrary waveforms without switching-on and switching-off transients has been used. Of the four waveforms used in the study (sinusoidal, sawtooth, square and short-pulse), the square waveform was found to be the most efficient at producing the highest ozone concentration for a fixed peak voltage and average power. To determine the effect of the modulation on-time, the number of cycles during the on-time were increased from 1 up to 1000, adjusting the off-time accordingly to maintain the same duty cycle. Shorter on-time periods were found to be more efficient. Experimental and computational results indicate that the time between subsequent discharges is critical for increased ozone generation efficacy, as this needs to be long enough for ozone produced in one discharge event to diffuse away from the discharge region before the next discharge event occurs, thereby avoiding its partial destruction in the plasma. This insight provides a valuable criterion for the optimization of DBD reactors used in novel biomedical, agricultural and environmental applications.

Published
2019

17. Characterization of a plasma source for biomedical applications by electrical, optical, and chemical measurements

Author

Cristina Paradisi, Roberto Cavazzana, Carlo Angelo Borghi, Emilio Martines, Paolo Seri, Matteo Taglioli, Matteo Zuin, Paola Brun, Gabriele Neretti, L. Cordaro, Ester Marotta, Barbara Zaniol, Francesco Tampieri, Neretti, Gabriele, Tampieri, Francesco, Borghi, Carlo Angelo, Brun, Paola, Cavazzana, Roberto, Cordaro, Luigi, Marotta, Ester, Paradisi, Cristina, Seri, Paolo, Taglioli, Matteo, Zaniol, Barbara, Zuin, Matteo, Martines, Emilio, Neretti, G, Tampieri, F, Borghi, C, Brun, P, Cavazzana, R, Cordaro, L, Marotta, E, Paradisi, C, Seri, P, Taglioli, M, Zaniol, B, Zuin, M, and Martines, E

Subjects
010302 applied physics, reactive oxygen species, Schlieren, reactive oxygen specie, Materials science, Polymers and Plastics, Chemical measurement, Analytical chemistry, Plasma, Condensed Matter Physic, plasma medicine, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Characterization (materials science), atmospheric plasma jet, optical emission spectroscopy, 0103 physical sciences, Optical emission spectroscopy, Plasma medicine
Abstract

This paper reports the characterization of a low-power, atmospheric pressure plasma source developed for and successfully tested in applications of plasma medicine. The source produces plasma by ionizing a helium flow containing traces of air. The effluent gas is thus enriched in reactive oxygen and nitrogen species as well as helium metastable excited states. Electrical measurements, Schlieren imaging, OES and various chemical analyses and probes enabled us to fully characterize the plasma source and to determine some fundamental parameters for treating living samples such as the power feeding the discharge, the optimal source to target distance, the maximum exposure time, and to identify the major chemical species responsible for the biological action on exposed living matter.

Published
2018

18. Measurement of the charge distribution deposited by an annular plasma synthetic jet actuator over a target surface

Author

Carlo Angelo Borghi, A. C. Ricchiuto, Gabriele Neretti, Neretti, G., Ricchiuto, A.C., and Borghi, C.A.

Subjects
010302 applied physics, Materials science, Acoustics and Ultrasonics, Target surface, Electronic, Optical and Magnetic Material, Non-thermal plasma, Charge density, Plasma, Dielectric barrier discharge, Condensed Matter Physic, Nonthermal plasma, Condensed Matter Physics, Acoustics and Ultrasonic, 01 natural sciences, Synthetic jet actuator, 010305 fluids & plasmas, Electronic, Optical and Magnetic Materials, Surfaces, Coatings and Films, Electro hydro dynamic, 0103 physical sciences, Charge distribution, Atomic physics, Plasma actuator
Abstract

Annular plasma synthetic jet actuators demonstrated their ability to produce a tubular flow normal to the surface where the dielectric barrier discharge (DBD) is ignited. These fluid-dynamic actuators enhance the delivery of reactive species towards the target to be treated. In these actuators, long life charged particles are generated within the plasma region and then carried on by the induced flow. In this work, the potential distribution induced by charges deposited over an insulating target has been measured. Surface DBD actuators, made with different dielectric materials, have been supplied by different sinusoidal voltages at a constant average power supplying the discharge. Actuators with the exposed electrode connected to both the high voltage potential and grounded have been tested. The charge distribution accumulated on a target surface perpendicular to the flow has been measured at different time intervals with the plasma on. Charges advected by the flow are always positive. The potential distribution on the target surface generated by the charges has been measured. For both configurations, firstly an M-shaped distribution develops and, later on, it becomes bell-shaped. A charge build-up mechanism has been found to be faster when the exposed electrode is connected to the high voltage terminal. The target has been placed at a variable distance from 1 to 5 cm from the actuator surface. At a distance of 5 cm, induced potentials are two times smaller than those with the target at 1 cm. Measurements allow us to estimate a charge flux toward the target on the order of 1011 particles (cm2 s)−1. The results presented in this work show that the presence of charged particles in the jet flow outside the plasma could be an important factor to be accounted for when these plasma actuators are used for treatment purposes (indirect plasma treatment).

Published
2018

19. Geometry optimization of linear and annular plasma synthetic jet actuators

Author

Gabriele Neretti, Paolo Seri, Matteo Taglioli, Alexander H. Shaw, Carlo Angelo Borghi, Felipe Iza, Neretti, G, Seri, P., Taglioli, M., Shaw, A., Iza, F., and Borghi, C.A.

Subjects
Materials science, Acoustics and Ultrasonics, Pitot tube, 02 engineering and technology, Dielectric barrier discharge, Condensed Matter Physic, Acoustics and Ultrasonic, 01 natural sciences, Schlieren imaging, 010305 fluids & plasmas, law.invention, Flow separation, Optics, law, 0103 physical sciences, Plasma actuator, Plasma processing, business.industry, Electronic, Optical and Magnetic Material, Non-thermal plasma, Laminar flow, Mechanics, Electrohydrodynamic, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Plasma actuator geometry, Electronic, Optical and Magnetic Materials, Surfaces, Coatings and Films, Synthetic jet, 0210 nano-technology, business
Abstract

The electrohydrodynamic (EHD) interaction induced in atmospheric air pressure by a surface dielectric barrier discharge (DBD) actuator has been experimentally investigated. Plasma synthetic jet actuators (PSJAs) are DBD actuators able to induce an air stream perpendicular to the actuator surface. These devices can be used in the field of aerodynamics to prevent or induce flow separation, modify the laminar to turbulent transition inside the boundary layer, and stabilize or mix air flows. They can also be used to enhance indirect plasma treatment effects, increasing the reactive species delivery rate onto surfaces and liquids. This can play a major role in plasma processing and chemical kinetics modelling, where often only diffusive mechanisms are considered. This paper reports on the importance that different electrode geometries can have on the performance of different PSJAs. A series of DBD aerodynamic actuators designed to produce perpendicular jets has been fabricated on two-layer printed circuit boards (PCBs). Both linear and annular geometries were considered, testing different upper electrode distances in the linear case and different diameters in the annular one. An AC voltage supplied at a peak of 11.5 kV and a frequency of 5 kHz was used. Lower electrodes were connected to the ground and buried in epoxy resin to avoid undesired plasma generation on the lower actuator surface. Voltage and current measurements were carried out to evaluate the active power delivered to the discharges. Schlieren imaging allowed the induced jets to be visualized and gave an estimate of their evolution and geometry. Pitot tube measurements were performed to obtain the velocity profiles of the PSJAs and to estimate the mechanical power delivered to the fluid. The optimal values of the inter-electrode distance and diameter were found in order to maximize jet velocity, mechanical power or efficiency. Annular geometries were found to achieve the best performance.

Published
2017

21. The fourth State of Matter and its biocidal effect: Plasma vs Coccidia

Author

MORANDI, BENEDETTO, POGLAYEN, GIOVANNI, BORGHI, CARLO ANGELO, GALUPPI, ROBERTA, NERETTI, GABRIELE, TAGLIOLI, MATTEO, Tosi, G., AAVV, SOIPA, Morandi, B., Poglayen, G., Borghi, C.A., Galuppi, R., Neretti, G., Taglioli, M., and Tosi, G.

Subjects
Plasma, Coccidia
Published
2016

22. The effect of plasma surface modification on biodegradation rate and biocompatibility of a poly(butylene succinate)-based copolymer

Author

SERI, PAOLO, BORGHI, CARLO ANGELO, GIORDANO, EMANUELE DOMENICO, NERETTI, GABRIELE, TAGLIOLI, MATTEO, FABBRI, MARTINA, GAMBERINI, RITA, GIGLI, MATTEO, GOVONI, MARCO, LOTTI, NADIA, MUNARI, ANDREA, Rimini, B., Seri, P., Borghi, C.A., Giordano, E., Neretti, G., Taglioli, M., Fabbri, M., Gamberini, R., Rimini, B., Gigli, M., Govoni, M., Lotti, N., and Munari, A.

Published
2015

26. Wind tunnel experiments on a NACA0015 airfoil equipped with vectorizable dielectric barrier discharge plasma actuators

Author

Gabriele Neretti, Seri Paolo, Carlo Angelo Borghi, Alessandro Talamelli, Alessandro Rossetti, Andrea Cristofolini, AIAA, Borghi C.A, Cristofolini A., Neretti G., Seri P., Talamelli A., and Rossetti A.

Subjects
Airfoil, Leading edge, Lift coefficient, Materials science, PLASMA, business.industry, Stall (fluid mechanics), Dielectric barrier discharge, Mechanics, FLOW CONTROL, Flow control (fluid), Aerospace engineering, business, Plasma actuator, Wind tunnel
Abstract

This work reports an experimental investigation performed in wind tunnel facility on a NACA0015 airfoil equipped with a set of vectorizable fluid-dynamic DBD plasma actuators. The ability of the actuators to recover the stall condition with free stream velocities in the range 5-23 m/s has been investigated. The discharge has been generated by feeding the actuators with a sinusoidal voltage waveform with a frequency of 15 kHz and voltages up to 7.5 kV peak. The actuator positioned on the leading edge exhibits highest ability in the stall recovery. Unsteady actuation obtained by alternatively switching on and off the discharge is more effective in the stall recovery when compared with a steady actuation. The frequency that optimizes the stall recovery has been found to be a function of the velocity with the power of 1.5. This result leads to the determination of a constant Strouhal number if the boundary layer thickness is used as characteristic length. Finally the lift coefficient, obtained when the plasma actuator has been turned on, has been found to be a linear function of the applied voltage.

Published
2014

27. Mhd flow control experiment in air: Test article design

Author

Eduardo Trifoni, Carlo Angelo Borghi, Damiano Baccarella, Andrea Passaro, Andrea Cristofolini, Gabriele Neretti, Baccarella, D., Passaro, A., Cristofolini, A., Neretti, G., and Trifoni, E.

Subjects
Engineering, Electromagnet, business.industry, Airflow, Mechanical engineering, Aerospace Engineering, Plasma, Computational fluid dynamics, law.invention, Magnetic field, Flow control (fluid), law, Space and Planetary Science, Control and Systems Engineering, Aerospace engineering, Magnetohydrodynamics, business, Wind tunnel
Abstract

An advanced flow control experiment, concerning magnetohydrodynamics (MHD) interaction over a blunt body, has been designed by Alta, CIRA and Department of Electrical Engineering (DIE) of University of Bologna and to be realized in CIRA's plasma wind tunnel "Scirocco" under a technology research program (TRP) funded by the European Space Agency (ESA). This work is a further step of the researches performed during the last decade by Alta and DIE in the field of MHD interaction. This experimental campaign foresees the employment of a 50 kW electromagnet, enclosed into an insulated blunt-shaped metallic TPS convectively cooled and electrically insulated by a ceramic coating. The test article has been designed for an air flow with nominal stagnation conditions of p0=2 bar and h0=22 MJ/kg, but several other conditions are planned to be investigated. The aim of the experimental campaign, along with a better understanding of the physical phenomena occurring within an highly ionized shock layer with an applied magnetic field, is the comparison of the collected data with the numerical predictions of CFD codes developed by CIRA. © 2011 by the American Institute of Aeronautics and Astronautics, Inc. All rights reserved.

Published
2011

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