Surface wetting processing on BNNT films by selective plasma modes

Li, Ling; Liu, Xiaowei; Dai, Xiujuan J.; Li, LuHua; Chen, Ying

doi:10.1007/s11434-013-5859-2

Cited by 10 publications

(3 citation statements)

References 51 publications

(51 reference statements)

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“…Compared to other nanomaterials, BNNTs exhibit unique wettability properties, which are tunable. BNNT films exhibit high hydrophobic properties with contact angles of greater than 170° [ 87 ]; however, they can be tuned to the desired wettability, even to superhydrophilicity (CA < 5°), by using N 2 /H 2 gas plasma of different energy inputs and modes [ 51 ] or using a combination of pulsed and continuous wave mode plasma [ 88 ].…”

Section: Bnnt Membranesmentioning

confidence: 99%

Boron Nitride Nanotube (BNNT) Membranes for Energy and Environmental Applications

et al. 2020

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Owing to their extraordinary thermal, mechanical, optical, and electrical properties, boron nitride nanotubes (BNNTs) have been attracting considerable attention in various scientific fields, making it more promising as a nanomaterial compared to other nanotubes. Recent studies reported that BNNTs exhibit better properties than carbon nanotubes, which have been extensively investigated for most environment-energy applications. Irrespective of its chirality, BNNT is a constant wide-bandgap insulator, exhibiting thermal oxidation resistance, piezoelectric properties, high hydrogen adsorption, ultraviolet luminescence, cytocompatibility, and stability. These unique properties of BNNT render it an exceptional material for separation applications, e.g., membranes. Recent studies reported that water filtration, gas separation, sensing, and battery separator membranes can considerably benefit from these properties. That is, flux, rejection, anti-fouling, sensing, structural, thermal, electrical, and optical properties of membranes can be enhanced by the contribution of BNNTs. Thus far, a majority of studies have focused on molecular simulation. Hence, the requirement of an extensive review has emerged. In this perspective article, advanced properties of BNNTs are analyzed, followed by a discussion on the advantages of these properties for membrane science with an overview of the current literature. We hope to provide insights into BNNT materials and accelerate research for environment-energy applications.

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Section: Bnnt Membranesmentioning

confidence: 99%

Boron Nitride Nanotube (BNNT) Membranes for Energy and Environmental Applications

et al. 2020

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“…Surface engineering holds the key to enhance surface properties. On account of this, research into surface engineering techniques [1][2][3], such as plasma surface treatment [4][5][6][7], micro/nano printing [8][9][10], and ion/electron beam processing [11][12][13][14], is becoming increasingly significant. Having said that, a number of these surface techniques can be costly and require considerable human interaction in the form of pre-and post-processing.…”

Section: Introductionmentioning

confidence: 99%

Micro-Machining of Diamond, Sapphire and Fused Silica Glass Using a Pulsed Nano-Second Nd:YVO4 Laser

Waugh

Walton

2021

Optics

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Optically transparent materials are being found in an ever-increasing array of technological applications within industries, such as automotive and communications. These industries are beginning to realize the importance of implementing surface engineering techniques to enhance the surface properties of materials. On account of the importance of surface engineering, this paper details the use of a relatively inexpensive diode-pumped solid state (DPSS) Nd:YVO4 laser to modify the surfaces of fused silica glass, diamond, and sapphire on a micrometre scale. Using threshold fluence analysis, it was identified that, for this particular laser system, the threshold fluence for diamond and sapphire ranged between 10 Jcm−2 and 35 Jcm−2 for a laser wavelength of 355 nm, dependent on the cumulative effects arising from the number of incident pulses. Through optical microscopy and scanning electron microscopy, it was found that the quality of processing resulting from the Nd:YVO4 laser varied with each of the materials. For fused silica glass, considerable cracking and deformation occurred. For sapphire, good quality features were produced, albeit with the formation of debris, indicating the requirement for post-processing to remove the observed debris. The diamond material gave rise to the best quality results, with extremely well defined micrometre features and minimal debris formation, comparative to alternative techniques such as femtosecond laser surface engineering.

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“…Surface roughness, which can be found in the form of micro or hierarchical structures in nature, has been widely investigated for its enhancement to hydrophobicity [1][2][3][4]. Through mimicking natural superhydrophobic surfaces including plant leaves and animals such as lotus leaves, rice leaves and water strider legs, manmade superhydrophobic surfaces via various of methodologies have been presented and applied in industrial applications, for instance, coating, self-cleaning surfaces, microfluidic devices with surfacetension-induced drop motion and so forth [5,6].…”

Section: Introductionmentioning

confidence: 99%

Wetting transition energy curves for a droplet on a square-post patterned surface

Gong

Chen

et al. 2017

Science Bulletin

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Surface wetting processing on BNNT films by selective plasma modes

Cited by 10 publications

References 51 publications

Boron Nitride Nanotube (BNNT) Membranes for Energy and Environmental Applications

Boron Nitride Nanotube (BNNT) Membranes for Energy and Environmental Applications

Micro-Machining of Diamond, Sapphire and Fused Silica Glass Using a Pulsed Nano-Second Nd:YVO4 Laser

Wetting transition energy curves for a droplet on a square-post patterned surface

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