Characterization of an Atmospheric Pressure Plasma Jet Using Optical Emission and Cavity Ringdown Spectroscopy

Clark, Shane Moore

04 May 2018

Cold plasma is useful in numerous medical applications, largely because of the highly-reactive chemical species generated in the discharge. The hydroxyl radical (OH) is of these species and has significant biological importance. An atmospheric pressure plasma jet (APPJ) was constructed in the form of a plasma pencil, and relative and absolute measurements were made of OH in both its first excited ground state—OH(A) and OH(X), respectively—using optical emission spectroscopy and cavity ring-down spectroscopy (CRDS). The total number of OH radicals were found to be constant in the plume and within the range given by relative measurements made on similar devices in the literature.

atmospheric pressure plasma jet

cavity ringdown

spectroscopy

cold plasma

Desenvolvimento e caracterização de jatos de plasma em pressão atmosférica e sua aplicação para deposição / Development and characterization of plasma jets in atmospheric pressure and its application for deposition

Castro, Alonso Hernan Ricci [UNESP]

26 June 2017

Submitted by ALONSO HERNAN RICCI CASTRO null (alonso_elfisico@yahoo.com) on 2017-08-17T17:22:54Z No. of bitstreams: 1 Castro_AHR_PHD.pdf: 57242725 bytes, checksum: 36378feb1c1464a31ab9ed5824539173 (MD5) / Approved for entry into archive by Luiz Galeffi (luizgaleffi@gmail.com) on 2017-08-23T17:50:32Z (GMT) No. of bitstreams: 1 castro_ahr_dr_guara.pdf: 57242725 bytes, checksum: 36378feb1c1464a31ab9ed5824539173 (MD5) / Made available in DSpace on 2017-08-23T17:50:32Z (GMT). No. of bitstreams: 1 castro_ahr_dr_guara.pdf: 57242725 bytes, checksum: 36378feb1c1464a31ab9ed5824539173 (MD5) Previous issue date: 2017-06-26 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Este trabalho teve como objetivo o estudo dos parâmetros que influenciam o comportamento de um jato de plasma em pressão atmosférica e sua aplicação em deposição de filmes poliméricos. Com esta finalidade, foram utilizadas duas diferentes configurações de eletrodos em jatos de argônio: um de eletrodo anular externo e outro com eletrodo cilíndrico interno. Também foram utilizadas três geometrias diferentes de bocal de saída do jato (cônico fechado, reto e cônico aberto), usando um eletrodo cilíndrico interno. Os jatos de plasma de argônio operam em modo filamentar, com os filamentos se espalhando por todo o volume do tubo dielétrico, disposto coaxialmente ao eletrodo. Neste trabalho também foi desenvolvido um jato de plasma para a deposição de filmes poliméricos, constituído de um eletrodo de alta tensão em forma cilíndrica localizado no eixo longitudinal do jato, e um eletrodo aterrado na forma de anel que está fixado ao redor do bocal do jato. O estudo foi iniciado com a comparação de dois métodos utilizados para o cálculo da potência. Para os dois jatos de plasma observou-se que o método mais adequado para calcular a potência de descarga é o método da figura de Lissajous, que fornece um erro experimental menor que 3 %. Após realizar a caraterização elétrica dos jatos de plasma, pode-se observar que a potência e a forma de onda da corrente dependem de diferentes parâmetros, que são apresentados em ordem da maior a menor influência da distância bocal-substrato, do fluxo de gás, do tipo de substrato e da geometria do bocal. A deposição de filmes poliméricos foi influenciada pela geometria do jato de plasma e do fluxo dos gases. Os filmes depositados sem movimento do substrato apresentam uma taxa de deposição de 1 m/min. A análise XPS mostrou que os filmes são constituídos em sua maioria por grupos alifáticos C-C/C-H e em menor proporção por hidroxila, éster e ácido carboxílico. Mediante a implementação de uma plataforma móvel foi possível depositar filmes poliméricos em uma grande área, o que amplia a gama de aplicações dos jatos de plasma desenvolvidos neste trabalho. / The goal of this work was to study the parameters which influence the electrical behavior of a atmospheric pressure plasma jet and its application for polymeric films deposition. For this purpose, two different configurations of electrodes were used in argon jets: one with an external annular electrode and the other with an internal cylindrical electrode. Also, three different jet nozzle geometries were adopted using an internal cylindrical electrode: tapered nozzle, straight nozzle and enlarged nozzle. The argon plasma jets operate in filament mode, with the filaments spreading throughout the volume of the dielectric tube, arranged coaxially to the electrode. On this work, a plasma jet system was developed to deposit polymer films, this system consists of a cylindrical high voltage electrode located in the longitudinal axis of the jet, and a grounded electrode in the form of a ring that is fixed around the nozzle of the jet. The study started comparing both methods for calculation of the power of plasma jets. Afterwards, it was concluded that the best method was the Lissajous method giving 3 % of experimental error. After electrical characterization of the plasma jet it was found that the power and current were influenced by different parameters, presented in order of their importance: distance, gas flow, type of substrate and nozzle geometry. The polymer films deposition was influenced by the plasma jet geometry and the gas flow. The films deposited without movement have 1 m/min of deposition rate. The XPS analysis shows that the films are made mostly from aliphatic groups C-C/C-H and in lesser extension by hydroxyl, ester and carboxylic acid. Through implementation of mobile platform was possible to deposit polymer films over larger area.

Jato em plasma a pressão atmosférica

Filmes poliméricos

Atmospheric pressure plasma jet

Polymeric films

Optical and Mass Spectrometric Studies of a Helium Dielectric-Barrier Atmospheric-Pressure Plasma Jet Used as an Ambient Desorption Ionization Source

Heywood, Matthew Spencer

06 March 2012

Recently there has been a surge in the field of mass spectrometry centered around the concept of rapid analysis of target analytes with minimal or no sample preparation. The target analyte undergoes desorption from its surface of origin and is subsequently ionized under ambient conditions. The technique is termed ambient desorption/ionization mass spectrometry (ADI-MS). Since the introduction of ADI-MS in 2004, there has been an explosion of research based around the development of novel ambient desorption/ionization (ADI) sources with the capability of desorbing and ionizing a variety of target analytes from various sampling surfaces. One type of ADI source uses the properties of an electrical discharge, typically a helium gas plasma, for desorption and ionization. For electrical-discharge-based sources, ionization is the result of an atmospheric pressure chemical ionization (APCI) process. The initiation of the APCI process it generally attributed to the Penning ionization of atmospheric nitrogen (N2) by highly energetic helium metastable species (Hem). In this work, I describe the direct imaging of the densities of helium metastable atoms in atmospheric pressure plasma jet (APPJ) of a helium-based dielectric-barrier discharge (DBD) using collisionally-assisted laser-induced fluorescence. Axial Hem distributions are compared to the emission of excited helium (He*) and nitrogen ion (N2+*) species in the plasma. A correlation is found between Hem densities and the performance of the ionization source in ADI-MS. Fluorescence images also show that Hem densities increase substantially when a glass slide is placed 10 mm from the discharge capillary in a geometry typical for desorption/ionization experiments. Advantage is taken of the time-varying nature of the plasma to produce axial profiles of temporally and spectrally resolved fluorescence images of Hem atoms and ground state nitrogen ions in the plasma jet. The axial distribution and similarities in the temporal behavior of the helium metastable and ground state nitrogen ion species give strong evidence that nitrogen ion species are created via Penning ionization by helium metastable atoms. Although axial distributions of He*,N2+*, and N2* emission support the fluorescence data, temporally-resolved emission measurements show that emission from key plasma species is almost entirely the result of excitation by a temporal energy wave. The effect that hydrogen (H2) has on the helium metastable atom densities is also presented. The addition of hydrogen to the discharge gas severely quenches the metastable state, leaving it virtually undetectable. The addition of 0.9% H2 to the helium in the source provides an order of magnitude increase in ADI-MS signal for target analytes despite the quenching of the Hem population.

Helium Dielectric-Barrier Discharge

Atmospheric Pressure Plasma Jet

Helium Metastable Imaging

Biochemistry

Chemistry

Storage Stability of an Antioxidant Active Packaging Coated with Citrus Extract Following a Plasma Jet Pretreatment

Contini, C., Katsikogianni, Maria G., O'Neill, F.T., O'Sullivan, M., Boland, F., Dowling, D.P., Monahan, F.J.

05 October 2013

yes / Antioxidant active packaging was prepared by coating a citrus extract on the surface of polyethylene terephthalate (PET) trays which had been either treated with an atmospheric pressure plasma jet or left untreated. The surface characteristics of the packaging were examined, as were its stability and antioxidant efficacy following storage for up to 24 weeks under the following three storage conditions: room temperature, 0 % relative humidity (RH) or 50 °C. Plasma pretreatment increased coating density, thickness and roughness, and oxygenated functional groups at the polymer surface, whereas water contact angle decreased. Trays stored at room temperature did not lose their antioxidant efficacy over 24 weeks and plasma pretreatment enhanced the efficacy from week 8 onwards. Gravimetric analysis of the coating revealed a loss of antioxidant compounds only after 16 weeks. Trays stored at 0 % RH lost coating from week 1 onwards, with lower loss in plasma pretreated trays, while loss of coating was highest at 50 °C, with lower loss in plasma pretreated trays only after 24 weeks. Overall, the surface characteristics of the antioxidant active packaging were modified by plasma pretreatment of the PET surface, with some improvement in antioxidant efficacy, and the efficacy of the packaging in delaying oxidative deterioration in cooked meats was retained during storage at ambient temperature.

Etude et optimisation d'une décharge "Plasma Gun" à pression atmosphérique, pour des applications biomédicales / Characterization of an atmospheric pressure pulsed plasma gun for biomedical applications

Sarron, Vanessa

16 December 2013

L’utilisation de plasmas, qu’ils soient thermiques ou basse pression, dans le domaine biomédical remonte aux années 1970. Au cours de ces dernières années, les développements concernant des jets de plasma froid à pression atmosphérique, ont permis un élargissement des domaines d’applications biomédicales des plasmas. Au sein du GREMI, un type de jet de plasma a été développé : le Plasma Gun. Le plasma généré par le Plasma Gun se propage sur de longues distances à l’intérieur de capillaires. L’optimisation des traitements visés nécessite une étude approfondie des décharges créées par le Plasma Gun. La caractérisation du Plasma Gun a mis en évidence la génération de Pulsed Atmospheric pressure Plasma Streams ou PAPS, ces derniers se propageant du réacteur jusque dans l’air ambiant où ils génèrent une plume plasma. Ces PAPS présentent deux modes de propagation, au cours desquels une connexion entre le front d’ionisation et le réacteur est présente en permanence. Ces deux modes nommés respectivement Wall-hugging et Homogène, diffèrent principalement par la morphologie et la vitesse de propagation des PAPS qui leur sont associés. Chacun de ces modes présentent donc des caractéristiques qui leur sont propres mais certaines propriétés de propagation leur sont communes, telles que la possibilité de division ou de réunion de PAPS, ainsi que du transfert de PAPS à travers une barrière diélectrique ou via un capillaire métallique creux. L’étude de la plume plasma, propagation des PAPS dans l’air ambiant, a souligné l’importance de la longueur des capillaires sur la longueur du jet plasma. De plus, la génération du plasma a une très forte influence sur l’écoulement du gaz et la structuration du jet lors de son expansion dans l’air. / The use of plasmas, thermic or low pressure, in biomedical goes back up to 1970s. During these last years, atmospheric pressure cold plasma jets have been developed, allowed an increase of biomedical applications of plasmas. In GREMI, a plasma jet was developed : the Plasma Gun (PG). The plasma generated by the PG propagates on long distances inside capillaries. The optimization of the aimed treatments requires a detailed study of the discharges created by the PG. The characterization of the PG highlights the generation of Pulsed Atmospheric pressure Plasma Streams or PAPS, these last ones propagating from the reactor to the capillary outlet (ambient air) where they generate a plasma plume. These PAPS present two propagation modes, during which a connection between the ionization front and the reactor is present permanently. These two modes named respectively Wall-hugging and Homogeneous, differ mainly by the morphology and their propagation velocity. These modes have common characteristics, such as the possibility of division or meeting of PAPS, as well as the transfer of PAPS through a dielectric barrier or via a hollow metal capillary. The study of the plasma plume underlined the importance of the length of capillaries on the length of the plasma jet. Furthermore, the generation of the plasma has a very strong influence on the gas flow and the jet structuration during air expansion.

Applications biomédicales

Jets de plasma froid

Pression atmosphérique

Décharge à barrière diélectrique

Onde d’ionisation

Streamer

Biomedical applications

Cold atmospheric pressure plasma jet

Dielectric barrier discharge

Ionization wave

Streamer

621

Investigation of Plasma Surface Interactions using Mueller Polarimetry / L'Étude des Interactions Plasma-Surface en utilisant la Polarimètrie de Mueller / Onderzoek naar Plasma-Oppervlakte Interacties met behulp van Mueller Polarimetrie

Slikboer, Elmar

26 November 2018

Cette thèse examine une nouvelle méthode de diagnostic, appelée Polarimètrie de Mueller, pour l’étude des interactions plasma-surface. Cette technique d’imagerie permet la caractérisation optique résolue en temps des cibles exposées au plasma. Les matrices de Mueller mesurées sont analysées en utilisant la décomposition logarithmique donnant des informations polarimétriques sur la diattenuation, la dépolarisation et la biréfringence. Cette dernière est exploitée en examinant des matériaux optiquement actifs afin d’identifier des aspects spécifiques de l’interaction avec le plasma, tels que les champs électriques ou la température de surface.Ce travail se concentre sur les cibles électro-optiques, qui permettent principalement la détection de champs électriques induits par la charge de surface déposée lors de l’interaction. La biréfringence est couplée analytiquement au champ électrique, en rapportant le retard de phase du faisceau sonde de lumière polarisée, à l’ellipsoïde d’index perturbé suivant l’effet Pockels. Grâce à cette approche analytique, les matériaux ayant des propriétés électrooptiques spécifiques peuvent être choisis de telle manière que toutes les composantes individuelles de champ électrique (axiales et radiales) induites à l’intérieur de l’échantillon soient imagées séparément. Pour la première fois les composantes du champ électriques peuvent être découplées permettant de mieux comprendre la dynamique du plasma proche d’une surface diélectrique.Cette technique est utilisée pour étudier l’impact d’ondes d’ionisation sur des surfaces. Ces décharges, générées par un jet de plasma à pression atmosphérique dans la gamme kHz, sont des plasmas froids filamentaires généralement utilisés pour des applications diverses telles que la fonctionnalisation de surface de polymères ou des traitements biomédicaux, mais les méthodes de diagnostic disponibles pour étudier les effets induits sur les surfaces sont limités. L’imagerie de polarimètrie Mueller appliquée aux cibles électro-optiques permet d’examiner les champs axiaux et radiaux en termes d’amplitude (3-6 kV/cm), d’échelles spatiales (<1mm axiales and <1cm radiales) et d’échelles temporelles (< 1μs pulsée and < 10μs CA) pour divers paramètres de fonctionnement du jet, e.g. amplitude de tension et gaz environnant.Simultanément à la biréfringence transitoire induite par le champ électrique, un signal de fond constant est également observé. Il est induit par la contrainte résultante du gradient de température induit à l’intérieur du matériau ciblé. Une relation analytique est obtenue en utilisant l’effet photo-élastique, permettant de développer une procédure de fitting pour retrouver la distribution de température. Cette procédure est utilisée, après calibration, pour montrer que la température de l’échantillon peut varier jusqu’`a 25 degrés par rapport aux conditions ambiantes – tandis que les changements dans le champ électrique sont également mesurés – et dépend de la fréquence de la tension d’alimentation AC du jet de plasma. La détermination précise de la température induite dans les cibles est importante car la plupart des applications visent des échantillons thermosensibles.Enfin, ce travail montre comment des échantillons complexes (aussi bien en terme d’état de surface que de composition chimique) peuvent être examinés lors d’une interaction plasma-surface, en les combinant avec une cible électrooptique. En raison de l’ajout d’un échantillon complexe, une composante de dépolarisation est ajoutée due à la diffusion du faisceau lumineux polarisé. Les changements de dépolarisation sont liés à l’évolution de l’échantillon complexe au cours du traitement par plasma. Ceux-ci, couplés aux champs électriques mesurés simultanément, fournissent un outil de diagnostic unique pour examiner les interactions plasma-surface. Cela a été appliqué à un cas test où une seule couche de cellules d’oignon est exposée aux ondes d’ionisation générées par le jet de plasma froid. / In this thesis, a new diagnostic method called Mueller Polarimetry is examined for the investigation of plasma-surface interactions. This imaging technique allows the time-resolved optical characterization of targets under plasma exposure. The measured Mueller matrices are analyzed by using the logarithmic decomposition providing polarimetric data on diattenuation, depolarization, and birefringence. The latter is used by examining materials that possess optically active behavior to identify specific aspects of the plasma interaction, e.g. electric fields or temperature.This work focusses on electro-optic targets, which primarily enables the detection of electric fields induced by surface charge deposited during the interaction. The birefringence is coupled to the externally induced electric field by analytically relating the phase retardance for the probing polarized light beam to the perturbed index ellipsoid, according to the Pockels effect. Through this analytical approach, materials with specific electro-optic properties can be chosen in such a way – together with the orientation of the Mueller polarimeter itself – that all the individual electric field components (axial and radial) induced inside the sample are imaged separately. This has never been done before and allows to better understand the plasma dynamics in the vicinity of a dielectric surface.It is used to investigate the surface impact by guided ionization waves generated by a kHz-driven atmospheric pressure plasma jet. These non-thermal filamentary discharges are generally applied to various samples for e.g. surface functionalization of polymers or biomedical treatment of organic tissues. However, available diagnostic tools are limited to study these interactions. Imaging Mueller polarimetry applied to electro-optic targets examines the axial and radial field patterns in terms of amplitude (3-6 kV/cm), spatial scales (< 1mm axial and <1cm radial), and timescales (<1μs pulsed and <10μs AC) for various operating parameters of the jet, for example voltage amplitude and surrounding gas.Simultaneous with the transient birefringence induced by the electric field, a constant background pattern is also observed. This results from strain induced by temperature gradients inside the targeted material. An analytical relation is obtained following the photo-elastic effect, which allowed a fitting procedure to be designed to retrieve the temperature pattern. This procedure is used after calibration to show that the temperature of the sample can vary up to 25 degrees relative to room conditions – while changes in the electric field are seen as well – depending on the operating frequency of the AC driven plasma jet. The accurate determination of the temperature is important since most applications involve temperature sensitive samples.Lastly, this work shows how complex samples (in terms of surface geometry and/or chemical composition) can be examined during a plasma-surface interaction. This is done by combining them with the electro-optic targets. Due to the addition of a (thin) complex sample, depolarization is added to the system through scattering of the polarized light beam. In-situ observed changes of depolarization relate to the evolution of the complex sample during the plasma treatment. This, coupled with the simultaneously monitored electric field patterns, provides a unique diagnostic tool to examine the plasma-surface interactions. This has been applied for a test case where a single layer of onion cells is exposed to the ionization waves generated by the non-thermal plasma jet.

Jet plasma à pression atmosphérique

Polarimètrie de Mueller

Interactions Plasma-Surface

Champ électriques

Température

Dépolarisation

Atmospheric pressure plasma jet

Mueller polarimetry

Plasma surface interactions

Electric fields

Temperature

Depolarization

530.44

Επίδραση ψυχρού πλάσματος πάνω σε βιοϋλικά και βιοσυστήματα / Impact of cold plasma over biomaterials and biosystems

Γεωργοπούλου, Στυλιανή

19 October 2012

Οι πίδακες πλάσματος ατμοσφαιρικής πίεσης διαδραματίζουν ολοένα και σημαντικότερο ρόλο σε διάφορες διαδικασίες επεξεργασίας και εφαρμογής του ψυχρού πλάσματος. Αυτό συμβαίνει λόγω της ιδιαίτερης ιδιότητας τους να παράγουν ενεργά φορτισμένα σωματίδια διατηρώντας τη θερμοκρασία του αερίου σε χαμηλές τιμές. Πρόσφατα, αυτό το ελκυστικό χαρακτηριστικό οδήγησε στην εκτεταμένη χρήση τους σε εφαρμογές που απαιτούν χαμηλές θερμοκρασίες, όπως στην επεξεργασία υλικών και σε βιολογικές εφαρμογές. Η μελέτη δύο τέτοιων εφαρμογών καθώς και η ανάλυση των χαρακτηριστικών εκκένωσης που λαμβάνει χώρα στο εσωτερικό ενός αντιδραστήρα παραγωγής πίδακα πλάσματος αποτελούν τους δύο κεντρικούς άξονες αυτής της διπλωματικής εργασίας. Ένας από τους κύριους στόχους του παρόντος εκπονήματος είναι ο προσδιορισμός των βέλτιστων συνθηκών λειτουργίας ενός συστήματος παραγωγής πίδακα πλάσματος. Ως επόμενο αντικείμενο μελέτης είναι η εφαρμογή ενός δεύτερου παρόμοιου συστήματος παραγωγής πίδακα πλάσματος για τροποποίηση της επιφάνειας πολυμερούς (πολυανθρακικού) με σκοπό την αύξηση της υδροφιλίας του και βελτίωση της βιοσυμβατικότητάς του. Επιχειρείται ανάλυση των μηχανισμών που καθορίζουν την αλληλεπίδραση του πίδακα πλάσματος με το πολυμερές. Τέλος, πραγματοποιείται εφαρμογή του ίδιου συστήματος για επεξεργασία λιποσωμικών μεμβρανών ως μοντέλο βιοσυστήματος. Ειδικότερα: • Στο πρώτο κεφάλαιο αναφέρονται κάποιες βασικές έννοιες και χαρακτηριστικά που αφορούν στο ψυχρό πλάσμα με έμφαση στους πίδακες ψυχρού πλάσματος και παρατίθενται διάφορα παραδείγματα αυτών που έχουν καταγραφεί στη βιβλιογραφία μέχρι σήμερα επιλέγοντας ως κριτήριο κατάταξής τους την τάση τροφοδοσίας. • Στο δεύτερο κεφάλαιο περιγράφονται αναλυτικά οι δύο πειραματικές διατάξεις πίδακα πλάσματος ατμοσφαιρικής πίεσης όπου πραγματοποιήθηκε το σύνολο των μετρήσεων. Παρουσιάζονται τα επιμέρους όργανα που χρησιμοποιήθηκαν για τη μέτρηση συγκεκριμένων μεγεθών και ταυτόχρονα παρατίθενται φωτογραφικό υλικό. Tέλος περιγράφονται δύο εφαρμογές του δεύτερου συστήματος που αφορούν στην επεξεργασία του πολυμερούς και των λιποσωμάτων και αναλύονται οι διαγνωστικές τεχνικές που εφαρμόστηκαν. • Στο τρίτο κεφάλαιο παρουσιάζεται το σύνολο των πειραματικών αποτελεσμάτων. Για τους σκοπούς αυτής της εργασίας πραγματοποιήθηκαν ηλεκτρικές και οπτικές μετρήσεις, μετρήσεις γωνιών επαφής, XPS αναλύσεις και μετρήσεις έντασης φθορισμού. • Στο τέταρτο κεφάλαιο καταγράφονται τα συμπεράσματα που προέκυψαν από τις επιμέρους μελέτες. Σημειώνονται ενδεικτικές τιμές των παραμέτρων του πρώτου συστήματος πίδακα πλάσματος για βέλτιστη λειτουργία. Επιτυγχάνεται μείωση της γωνίας επαφής έως και 49ο και τονίζεται ο πρωταρχικός ρόλος των διεγερμένων ουδέτερων και μετασταθών σωματιδίων του πίδακα πλάσματος στην επεξεργασία. Τέλος, παρατηρείται ποσοστό διάσπασης-επεξεργασίας των λιποσωμάτων έως 15%. / Non-thermal atmospheric pressure plasma jets are playing an increasingly important role in various plasma processing applications. This is because of their practical capability to achieve enhanced gas phase chemistry without the need of elevated gas temperatures. This attractive characteristic recently led to their extensive use in applications that require low temperatures, such as material processing and biomedical applications. The studies of two applications as well as the analysis of discharge characteristics inside the atmospheric pressure plasma jet are the two principal issues of this thesis. More specifically, one of the main objects of the present thesis is the determination of the optimal operation conditions for an atmospheric plasma jet system. A second, similar atmospheric plasma jet system was applied for surface modification of a polymer (polycarbonate) by increasing its wettability Τhe analysis of mechanisms governing the interaction of plasma jet with the polymer is presented. Finally, the same system was also applied for liposomes treatment considered as biosystem model. Particularly: • In the first chapter a brief report on the general characteristics of plasma is mentioned and a review of the different atmospheric pressure plasma jets developed until today is presented. The plasma jets are classified according to their power sources. • In the second chapter the two different experimental set-ups used are described in details. The specific characteristics of each atmospheric pressure plasma jet are outlined and all the others apparatus used are presented and demonstrated by means of photography. At the end, two applications of the second plasma jet are referred concerning polymer and liposome treatment with their respective diagnostics techniques. • In the third chapter the total experimental measurements are presented. For the goals of this thesis were conducted a plenty of electrical and optical measurements, contact angles measurements, XPS analyses and fluorescence intensity measurements. • In the forth chapter all the conclusions exported of each part are recorded. Firstly, the optimal operational conditions, as excluded from the experimental procedure, are recorded. It is obtained a significant decrease of contact angle until 49ο, emphasizing on the dominant role of the reactive excited neutrals and metastables species. Also modification of the liposome membranes is observed at the percentage of 15%.

Γωνίες επαφής

Ικανότητα ύγρανσης

530.442

Atmospheric pressure plasma jet

Dielectric barrier discharge

Surface polymer treatment

Contact angles

Wettability

Liposome membrane treatment

Ultrashort Two-Photon-Absorption Laser-Induced Fluorescence in Nanosecond-Duration, Repetitively Pulsed Discharges

Schmidt, Jacob Brian

01 October 2015

No description available.

Aerospace Engineering

Chemistry

Engineering

Mechanical Engineering

Optics

Physics

Plasma Physics

Plasma

fluorescence

femtosecond

atomic species

quencing

nanosecond

filament discharge

discharge

Etude de la production des espèces réactives de l’oxygène et de l’azote par décharge Plasma Gun à pression atmosphérique pour des applications biomédicales / Study of oxygen and nitrogen reactive species production in atmospheric pressure Plasma Gun discharge for biomedical applications

Darny, Thibault

27 June 2016

En l’espace d’une dizaine d’années, les jets de plasma froid à pression atmosphérique ont su s’imposer comme un outil pertinent pour les applications biomédicales. La simplicité de conception et d’utilisation de ces dispositifs, combinée à leurs facultés de produire des espèces réactives (NO, OH, O …), ont significativement contribué au développement rapide du domaine. Beaucoup d’efforts ont été entrepris dans le développement de diagnostics quantitatifs, pour mesurer la production des espèces réactives dans la plume plasma d’un jet donné. Toutefois, la diversité des géométries de décharge, des sources d’alimentations électriques ou des conditions d’utilisation, rendent les comparaisons d’un jet à l’autre, difficiles. Cette thèse a porté sur l’étude du jet de plasma froid à pression atmosphérique développé au GREMI, le Plasma Gun (hélium, impulsion de tension microseconde). Nous avons étudié les mécanismes de décharge susceptibles de considérablement affecter la production d’espèces réactives, dans des conditions approchantes d’applications biomédicales. La thèse s’articule en trois chapitres principaux : l’étude de la modification de l’écoulement de l’hélium par plasma (par strioscopie) ; l’étude de la propagation du plasma dans le capillaire diélectrique (étude expérimentale et numérique de la dynamique de propagation rapide du plasma et de l’évolution du champ électrique en mélange hélium-azote) ; l’étude de l’interaction du plasma avec une cible conductrice (mesures dans le capillaire et dans la plume de l’évolution spatiale et temporelle de la concentration des métastables de l’hélium, corrélées à des mesures du champ électrique). Ce dernier point est en particulier représentatif de tout jet plasma en condition traitement biomédical in vivo et tend à faire une distinction fondamentale avec les mécanismes de décharge du jet plasma dit « libre », sans obstacle entravant la plume plasma. / Over the past ten years, the cold atmospheric pressure plasma jets (CAPPJ) became useful devices for biomedical applications. Their relatively simple design and use, combine with their ability to produce reactive species (NO, OH, O, …), led to a rapid research growth in this field. A lot of studies have been devoted to quantitative diagnostics development for the reactive species production measurements in the plasma plume. However, it is difficult to compare one jet with another because of the huge variety of discharge geometries, electric power supplies or operating conditions. This thesis deals with the study of the CAPPJ developed in GREMI, the Plasma Gun (helium feeded, microsecond voltage pulse). We have studied discharge mechanisms which strongly impact the reactive species production in near target biomedical application conditions. This study is divided in three parts : the study of helium flow modifications induced by the plasma (strioscopy visualization); the study of plasma propagation inside dielectric capillary (experimental and numerical study of fast plasma propagation dynamic and electric field evolution for helium-nitrogen mixtures); the study of conductive target-plasma interaction (space and time resolved measurements inside the capillary and the plasma plume of helium metastable production, correlated with electric field evolution). The conductive target contact concerns any in vivo biomedical treatments. CAPPJ in front of such a conductive target leads to fundamentally different discharge mechanisms compare to the free jet case.

Onde d’ionisation

Modification d’écoulement

Champ électrique

Cinétique réactionnelle hélium-azote

Métastable de l’hélium atomique

Espèces réactives

Cold atmospheric pressure plasma jet

Ionization wave

Flow modification

Electric field

Helium-nitrogen reaction kinetic

Atomic helium metastable

Reactive species

530.44