Experimental Investigation and Molecular Dynamics Simulation on the Anti-Adhesion Behavior of Alkanethiols on Nickel Insert in Micro Injection Molding

Weng, Can; Chen, Jiachen; Yang, Jin; Zhou, Mingyong; Jiang, Bingyan

doi:10.3390/nano11071834

Cited by 2 publications

(2 citation statements)

References 37 publications

(41 reference statements)

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“…Adhesion is the result of molecular or atomic forces between objects, causing them to bond closely [79]. This phenomenon involves various mechanisms of adhesion, among which van der Waals forces generate short-range attractions between molecules, including London dispersion forces and Debye polarization forces, creating temporary charge distributions and resulting in attraction [48,80,81]. Electrostatic forces, also known as Coulomb forces, arise from interactions between charges and can lead to attractions or repulsions between positively and negatively charged entities [82].…”

Section: Mechanism and Failure Modementioning

confidence: 99%

Nanostructure-Based Oil–Water Separation: Mechanism and Status

Wang,

Feng,

Wang

et al. 2023

Separations

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Flexible and effective methods for oil–water separation are crucial for reducing pollutant emissions and safeguarding water and fuel resources. In recent years, there has been growing interest in fundamental research and engineering applications related to water and fuel purification, especially oil–water separation. To date, filter materials with special wetting characteristics have been widely used in oil–water separation. Nanostructured materials are one of the most attractive candidates for next-generation oil–water separation. This review systematically summarizes the mechanisms and current status of oil–water separation using nanostructured materials. Basically, this can be achieved by using nanostructured materials with specific wettability and nanostructures. Here, we provide a detailed discussion of two general approaches and their filtration mechanisms: (1) the selective filtration technique, based on specific surface wettability, which allows only oil or water to penetrate while blocking impurities; (2) the absorption technique, employing porous sponges, fibers, or aerogels, which selectively absorbs impure oil or water droplets. Furthermore, the main failure modes are discussed in this review. The purposes of this article are: (1) to summarize the methods of oil–water separation by nanotechnology; (2) to raise the level of environmental protection consciousness of water pollution by using nanotechnology; (3) to tease out the features of different approaches and provide a pivotal theoretical basis to optimize the performance of filtering materials. Several approaches for oil and water separation are compared. Furthermore, the principle and application scope of each method are introduced.

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Section: Mechanism and Failure Modementioning

confidence: 99%

Nanostructure-Based Oil–Water Separation: Mechanism and Status

Wang,

Feng,

Wang

et al. 2023

Separations

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“…Lucchetta et al 22 developed a multiscale model of submicron scale polymer flow and analyzed the sensitivity of the model to polymer material type, mold surface properties, and mold temperature, with a maximum error of 8% in the accuracy of the multiscale model. In our previous exploration, 23 we adopted a molecular dynamics approach to scrutinize the nano‐injection molding demolding process, identifying that minimizing the interfacial interaction between the mold insert and polymer molecular chains is essential for reducing demolding force. Xhou and Qiu 24 found that the surface morphology of the mold cavity determined the contact mode between the mold insert and the part, which affected the adhesion and friction during the demolding process.…”

Section: Introductionmentioning

confidence: 99%

Enhancing structural replication of microfluidic chips: Parameter optimization and mold insert modification

Wang,

Weng,

Fei

et al. 2024

Polymer Engineering & Sci

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The demolding process in micro‐injection molding constitutes a critical phase, exerting a decisive influence on the quality of polymer microstructures. In this study, the demolding forces of PMMA microfluidic chips were measured under different demolding temperatures, packing pressures, and demolding speeds by using pure nickel (Ni) mold insert. The dimensional deviations of the microchannels with different aspect ratios were analyzed. In addition, the effect of mold insert modification on the demolding force was further analyzed. The results showed that the effect of demolding temperature on the demolding force was the most significant, and the peak demolding force decreased with the decrease in temperature. The width of the microchannels increased and the depth decreased after demolding, while the opposite results were observed for the micro‐mixing structures. However, the dimensional deviation of the micro‐mixing structures was larger than that of the microchannels. Using the optimal molding parameters, the peak demolding force could be reduced from 114.0 N at 110°C to 47.0 N, a decrease of 58.8%. It is noteworthy that, when the microchannel was narrower than 100 μm, achieving precise replication of microchannel dimensions became progressively more challenging as the microchannel width decreased. Using the Ni‐WS2 mold insert with low surface energy and low friction coefficient, the demolding force could be further reduced by 38.3%. The effect of the molding quality of microfluidic chip microstructures on the mixing performance of heavy metals was demonstrated by micro‐mixing experiments.Highlights Demolding temperature crucially affects microstructure dimensions. Optimal parameters and modified mold insert reduce demolding force by 38.3%. Dimensional deviation increases with the increase of microchannel aspect ratio. Optimized microfluidic chip enhances Co2+ chemiluminescence by 6.42%.

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Experimental Investigation and Molecular Dynamics Simulation on the Anti-Adhesion Behavior of Alkanethiols on Nickel Insert in Micro Injection Molding

Cited by 2 publications

References 37 publications

Nanostructure-Based Oil–Water Separation: Mechanism and Status

Nanostructure-Based Oil–Water Separation: Mechanism and Status

Enhancing structural replication of microfluidic chips: Parameter optimization and mold insert modification

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