Development and optical characterization of an atmospheric pressure non-thermal plasma jet for superhydrophobic surface fabrication

IF 1.3 Q3 ORTHOPEDICS

Plasma Research Express Pub Date : 2020-10-28 DOI:10.1088/2516-1067/abbe9b

Rakesh Ruchel Khanikar, P. J. Boruah, H. Bailung

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引用次数: 9

Abstract

Atmospheric pressure non-thermal plasma jets are becoming subject of great attention in various fields such as plasma processing and biomedical applications due to their ability to produce highly reactive species and good reaction chemistry at low gas temperatures. In the present study, a non-thermal plasma jet operating on argon gas at atmospheric pressure aimed mainly towards surface modification and thin film deposition applications has been developed. Optical emission spectroscopy is used to evaluate the plasma parameters. The gas temperature (800 ± 50 K) is estimated from OH(A-X) rotational band. The excitation temperature is measured using intensity ratio of two argon lines and is found to be 0.241–0.273 eV and the corresponding electron temperatures have been measured. Electron density of the order of 1014 cm−3 has been obtained from the Stark broadening of Balmer H β line. The plasma jet has been successfully employed to deposit a superhydrophobic thin film of SiwCxHyOz using hexamethyldisiloxane (HMDSO) precursor monomer. The deposited film has been analyzed using XRD, FTIR, SEM, AFM, and contact angle analyzer. All the treated surfaces have shown superhydrophobic property with a contact angle greater than 150° showing numerous potential in various applications. This method is a relatively easy and environmental friendly way of fabricating superhydrophobic surfaces.

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用于超疏水表面制造的常压非热等离子体射流的研制和光学特性

大气压非热等离子体射流由于其在低气体温度下产生高反应性物种和良好反应化学性质的能力，在等离子体处理和生物医学应用等各个领域正成为备受关注的主题。在本研究中，开发了一种在大气压氩气下工作的非热等离子体射流，主要用于表面改性和薄膜沉积应用。光学发射光谱用于评估等离子体参数。气体温度（800±50 K）由OH（A-X）旋转带估算。使用两条氩线的强度比测量激发温度，发现激发温度为0.241–0.273 eV，并测量了相应的电子温度。β线的斯塔克增宽得到了1014 cm-3量级的电子密度。等离子体射流已成功地用于使用六甲基二硅氧烷（HMDSO）前体单体沉积SiwCxHyOz的超疏水薄膜。利用XRD、FTIR、SEM、AFM和接触角分析仪对沉积的薄膜进行了分析。所有处理过的表面都显示出超疏水性，接触角大于150°，在各种应用中显示出许多潜力。这种方法是一种相对简单且环保的制造超疏水表面的方法。

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来源期刊

Plasma Research Express Energy-Nuclear Energy and Engineering

CiteScore

2.60

自引率

0.00%

发文量