Polymer etching by atmospheric‐pressure plasma jet and surface micro‐discharge sources: Activation energy analysis and etching directionality

Self Cite

We report (a) the deep modification of polymers by long-lived reactive species generated in atmospheric pressure plasma and (b) the dependence of plasma-polymer interaction on the macromolecular structure. Styrene-based polymers show significant thickness expansion whereas polymers with methyl, alcohol, and ether side groups show low-rate etching. The characterization of polystyrene (PS) by X-ray photoelectron spectroscopy and attenuated total reflectance-Fourier transform infrared shows that plasma treatment destroys aromatic rings and produces ether, ester, and surface organic nitrate groups.These modifications can happen at tens of nanometers below the surface, which we attribute to the reaction-diffusion of plasma species. Comparing three styrene-based polymers namely PS, poly(4methyl styrene), and poly(αmethyl styrene), we find that long-lived species primarily attack the C-H bond on the carbon site where the aromatic ring connects.

k_{ER}

can be expressed as:

k_{ER} = A_{ER} \cdot ex normalp true(\frac{- E_{a}}{k_{b} T} true),

where

A_{ER}

is the pre‐exponential factor,

k_{b}

is the Boltzmann constant and T is the substrate temperature. The apparent activation energy

E_{a}

is an empirically fitted parameter that represents the energy required for the etching reaction to take place.…”

Section: Discussionmentioning

confidence: 74%

Interaction of long‐lived reactive species from cold atmospheric pressure plasma with polymers: Role of macromolecular structure and deep modification of aromatic polymers

Luan

Oehrlein

2019

Self Cite

“…Atmospheric pressure plasma jets have been widely used in many healthcare and materials processing applications, ranging from etching and deposition to microbial decontamination and cancer therapy. [1][2][3][4][5] Perhaps the most widely used plasma jet configuration is based on the dielectric barrier discharge employing a noble gas such as helium or argon; typically, the gas is flushed through a dielectric capillary and subjected to an applied voltage using one or more electrodes placed inside and/or outside of the capillary. On the application of a time-varying voltage of sufficient magnitude to cause a breakdown, a discharge forms within the capillary and propagates as a fast-moving ionization wave along the noble gas channel, ultimately exiting the capillary and extending into the surrounding quiescent air.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Turbulence and entrainment in an atmospheric pressure dielectric barrier plasma jet

Morabit

Whalley

Robert

et al. 2019

Particle image velocimetry, laser-induced fluorescence, and computational modeling are used to quantify the impact of plasma generation on air entrainment into a helium plasma jet. It is demonstrated that discharge generation yields a minor increase in the exit velocity of the gas. In contrast, the laminar to turbulent transition point is strongly affected, attributed to an increase in plasma-induced perturbations within the jet shear layer. The temporal decay of laser-induced fluorescence from OH is used as an indicator of humid air within the plasma. The results show that plasma-induced perturbations increase the quenching rate of the OH-fluorescent state;indicating that shear-layer instabilities play a major role in determining the physicochemical characteristics of the plasma.

“…Low temperature plasma surface modification technology has broad application prospects because of its remarkable advantages such as high efficiency, low energy consumption, environmental protection, and it only acts on the surface of fibers without affecting the properties of the main stems of fibers . Furthermore, low temperature plasma generated by glow discharge is considered to be the best choice for material surface modification because of its good discharge uniformity, abundant active particles, and appropriate power density …”

Section: Introductionmentioning

confidence: 99%

Study on atmospheric air glow discharge plasma generation based on multiple potentials and aramid fabric surface modification

Zhao

Liu

et al. 2019

A method of forming large‐area glow discharge plasmas with good diffusivity in atmospheric air based on the composite network‐surface laminated electrode structure with multiple potentials is proposed. This method can enhance the intensity of the space electric field and generate glow discharge plasma under the condition that the voltage is lower than 1 kV. Through the alternating electric field, the charged particles diffuse from the surface of the electrode to the space to enhance the treatment of aramid fabric. According to the changes of surface morphology, contact angle and surface energy of aramid fabric, it can be seen that the surface roughness and surface energy of the material treated by plasma are significantly improved. After 30 s of treatment, the contact angle decreases by 83.85° and the surface energy increases 3.4 times. This method has the advantages of low discharge voltage, good discharge uniformity, good material treatment effect, and so forth. It has good application prospects for the industrialization of aramid fabric surface modification with high efficiency.