Determination of Surface Temperature in ICP RF Plasma Treatments of Organic Materials

Farias, Carlos Eduardo; Bernardelli, Euclides Alexandre; Borges, Paulo César; Mafra, Márcio

doi:10.1590/1980-5373-mr-2017-0238

Cited by 2 publications

(3 citation statements)

References 35 publications

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“…The higher degradation of the samples with the increase of the power is related to the greater density of the species chemically active in the plasma, ions and electrons. The temperature of the sample is another factor that should contribute significantly to a greater degradation with power increase [2,5,21,22,37]. Because of that, in the present work, a water circulation system was used to keep the temperature constant at about 0°C.…”

Section: Resultsmentioning

confidence: 99%

“…However, due to the complexity of the plasma environment, it is necessary to obtain more information about the influence of the different species on the degradation of organic functions [19]. In addition, it is also important to study the structural changes of the treated material generated by the physical parameters of the discharge, both in organic [20][21][22] and in metallic materials [23].…”

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Influence of applied plasma power on degradation of L-proline in an inductively coupled RF plasma reactor

et al. 2022

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Surface treatments such as heat treatments, paints, plasma treatments and galvanizing are important in metal working industry. In those treatments, the required adhesion characteristics can be limited if contaminants are present, so there is a need to clean these surfaces. Conventional processes can be costly, some generated waste may be environmentally hazardous and, in some cases, due to part geometry, they are not effective. Alternatively, plasma treatments which are considered to be environmentally clean, more efficient and with lower operating costs can overcome those difficulties. Due to the reactional complexity of these treatments, there are many fields to be researched, such as which reactions are due to impacts of (neutral) chemical species and which are due to excited species and radiation. The present work aims to verify the interactions between Ar-10%O 2 plasma using amino acid L-proline in an inductively coupled radiofrequency plasma. This study showed that oxidative plasma promotes high degradation of the sample. A gas analyzer (quadrupole mass spectrometer) coupled to the gas outlet was used and many gaseous products are detected during treatment, such: H 2 , H 2 O, CO, NO (Nitric Oxide) and CO 2 while L-proline undergoes intense degradation. The conclusions allow to state that the interaction between the Ar/O 2 plasma and L-proline promotes intense degradation through the breakdown of the heterocyclic ring of the molecule.

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Influence of applied plasma power on degradation of L-proline in an inductively coupled RF plasma reactor

et al. 2022

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“…Molecules widely used as models for surface contaminants are stearic acid and hexatriacontane. Works carried out with these compounds [12][13][14][17][18][19][20][21][22] evaluated the influence of the types of discharge and process parameters such as gas composition, pressure, power, and frequency of the electrical source.…”

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confidence: 99%

Influence of the pressure on the interaction between stearic acid and Ar-O2 in inductively coupled radio frequency plasma

Bernardelli,

Splett,

Farias

et al. 2023

Matéria (Rio J.)

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This work aimed to analyze the influence of treatment pressure on the interaction between stearic acid and an Argon-Oxygen plasma. The fixed variables were the applied RF plasma power (50 W), treatment time (30 min), and treatment starting temperature (273 K). The pressure was varied as follows: 0.2, 0.6, and 1.0 Torr. For all treatment conditions, the etching of the samples was observed, as evidenced by the mass loss of the specimens and by following the gaseous by-products of reactions employing a mass spectrometer coupled to the reaction chamber. Optical emission spectroscopy followed the emission lines of oxygen active species. Functionalization of the specimens was also observed, as shown by the results obtained by Fourier-transform infrared spectroscopy (FTIR) and through XRD analysis. A liquid phase was formed for samples treated at 0.6 and 1.0 Torr, which favored the functionalization process and broadened the band present in the region from 1750 to 1700 cm -1 , resulting in amorphous phases. An increase in the intensity of the characteristic peaks of esters was also observed. It can be concluded that the higher pressure favors the formation of a liquid phase and reaction kinetics, resulting in higher functionalization and lower etching.

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Determination of Surface Temperature in ICP RF Plasma Treatments of Organic Materials

Cited by 2 publications

References 35 publications

Influence of applied plasma power on degradation of L-proline in an inductively coupled RF plasma reactor

Influence of applied plasma power on degradation of L-proline in an inductively coupled RF plasma reactor

Influence of the pressure on the interaction between stearic acid and Ar-O2 in inductively coupled radio frequency plasma

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