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Nanomanufacturing, Volume 4, Issue 3 (September 2024) – 4 articles

Cover Story (view full-size image): Novel packaging films that were prepared with or without the incorporation of a natural-halloysite (HNT)/carvacrol (CV)-extract nanohybrid with LDPE and coated externally, directly, or via corona treatment with carvacrol essential oil are studied in this report. According to the results from FTIR spectroscopy and a carvacrol release kinetic analysis, this technique led to a higher number of carvacrol molecules nanocoated on the surface of all the tested films. All the corona-treated films also exhibited higher total antioxidant activity and higher EC50 values. The most promising kind of active film, the carvacrol-coated and corona-treated LDPE film incorporated with 10 %wt. halloysite nanotubes that were also impregnated with carvacrol, exhibited over 40% higher water and oxygen barrier performance than that of the pure LDPE film. View this paper
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14 pages, 17182 KiB  
Article
Assembly and Bilayer Liftoff of Periodic Nanostructures with Sub-20 nm Resolution Using Thermal Scanning Probe Lithography
by Paloma E. S. Pellegrini, Silvia V. G. Nista and Stanislav Moshkalev
Nanomanufacturing 2024, 4(3), 173-186; https://doi.org/10.3390/nanomanufacturing4030012 - 11 Sep 2024
Viewed by 901
Abstract
The demands for high resolution fabrication processes are ever-increasing, with new and optimized methodologies being highly relevant across several scientific fields. We systematically investigated thermal scanning probe lithography process and detailed how tuning temperature and probe contact time on the sample can optimize [...] Read more.
The demands for high resolution fabrication processes are ever-increasing, with new and optimized methodologies being highly relevant across several scientific fields. We systematically investigated thermal scanning probe lithography process and detailed how tuning temperature and probe contact time on the sample can optimize patterning and achieve 10 nm resolution. Additionally, we propose a novel fabrication methodology that integrates thermal scanning probe lithography and bilayer liftoff, achieving sub-20 nm resolution of the final metallized structures. Each step of the process, from sample preparation to the final liftoff, is described in detail. We also present a quantitative analysis comparing the accuracy of the lithography process to that of the bilayer liftoff. Finally, we show the feasibility of using thermal scanning probe lithography for the fabrication of photonic devices by validating our work with promising dipole geometries for this field. Full article
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14 pages, 3672 KiB  
Perspective
Fabrication of Surface Acoustic Wave Biosensors Using Nanomaterials for Biological Monitoring
by Hongze Zhang, Pu Chen, Liquan Yang, Huan Wang and Zhiyuan Zhu
Nanomanufacturing 2024, 4(3), 159-172; https://doi.org/10.3390/nanomanufacturing4030011 - 16 Aug 2024
Viewed by 1371
Abstract
Biosensors are a new type of sensor that utilize biologically sensitive materials and microbially active analytes to measure a variety of biological signals. The purpose of monitoring is achieved by combining these sensitive materials with analytes such as proteins, cells, viruses, and bacteria, [...] Read more.
Biosensors are a new type of sensor that utilize biologically sensitive materials and microbially active analytes to measure a variety of biological signals. The purpose of monitoring is achieved by combining these sensitive materials with analytes such as proteins, cells, viruses, and bacteria, inducing changes in their physical or chemical properties. The use of nanomaterials in fabricating surface acoustic wave (SAW) biosensors is particularly noteworthy for the label-free detection of organisms due to their compact size, portability, and high sensitivity. Recent advancements in the manufacturing techniques of SAW biosensors have significantly enhanced sensor performance and reliability. These techniques not only ensure precise control over sensor dimensions and material properties but also facilitate scalable and cost-effective production processes. As a result, SAW biosensors are poised to become powerful tools for various clinical and rapid detection applications. Full article
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22 pages, 5918 KiB  
Article
Effect of Corona Treatment Method to Carvacrol Nanocoating Process for Carvacrol/Halloysite-Nanotube/Low-Density-Polyethylene Active Packaging Films Development
by Aris E. Giannakas, Vassilios K. Karabagias, Amarildo Ndreka, Aikaterini Dimitrakou, Areti A. Leontiou, Katerina Katerinopoulou, Michael A. Karakassides, Charalampos Proestos and Constantinos E. Salmas
Nanomanufacturing 2024, 4(3), 138-158; https://doi.org/10.3390/nanomanufacturing4030010 - 22 Jul 2024
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Abstract
Active food packaging incorporated with natural plant extracts as food preservatives, which will totally replace chemical preservatives gradually, are of major interest. Sequentially to our and other scientists’ previous work, in this paper we present the results of a study on the development [...] Read more.
Active food packaging incorporated with natural plant extracts as food preservatives, which will totally replace chemical preservatives gradually, are of major interest. Sequentially to our and other scientists’ previous work, in this paper we present the results of a study on the development of a novel active food packaging film based on the incorporation of a natural-halloysite/carvacrol-extract nanohybrid with the commercially used low-density polyethylene. The corona-treatment procedure was employed to incorporate a natural preservative on to the optimum final film. Packaging films are formatted with and without incorporation of natural-halloysite/carvacrol-extract nanohybrid and are coated externally, directly or via corona-treatment, with carvacrol essential oil. Mechanical, physicochemical, and preservation tests indicated that the low-density polyethylene incorporated perfectly with a natural-halloysite/carvacrol-extract nanohybrid. The extra external coating of the film with pure carvacrol extract using the corona-treatment technique led to approximately 100% higher Young Modulus values, slightly decreased ultimate strength by 20%, and exhibited almost stable elongation at break properties. The water vapor and oxygen properties were increased by 45 and 43%, correspondingly, compared to those of pure low-density polyethylene film. Finally, the antioxidant activity of the corona-treated film increased by 28% compared to the untreated film coated with carvacrol because of the controlled release rate of the carvacrol. Full article
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18 pages, 7591 KiB  
Article
3D Printing of High-Porosity Membranes with Submicron Pores for Microfluidics
by Julia K. Hoskins and Min Zou
Nanomanufacturing 2024, 4(3), 120-137; https://doi.org/10.3390/nanomanufacturing4030009 - 27 Jun 2024
Viewed by 1133
Abstract
In this study, we investigate the potential of two-photon lithography (2PL) as a solution to the challenges encountered in conventional membrane fabrication techniques, aiming to fabricate tailor-made membranes with high-resolution submicron pore structures suitable for advanced applications. This approach led to the development [...] Read more.
In this study, we investigate the potential of two-photon lithography (2PL) as a solution to the challenges encountered in conventional membrane fabrication techniques, aiming to fabricate tailor-made membranes with high-resolution submicron pore structures suitable for advanced applications. This approach led to the development of fabrication techniques and printed membranes that can be adapted to various lab-on-a-chip (LOC) devices. Membranes were fabricated with pore diameters as small as 0.57 µm and porosities of 4.5%, as well as with larger pores of approximately 3.73 µm in diameter and very high porosities that reached up to 60%. Direct 3D printing of membranes offers a pathway for fabricating structures tailored to specific applications in microfluidics, enabling more efficient separation processes at miniature scales. This research represents a significant step towards bridging the gap between membrane technology and microfluidics, promising enhanced capabilities for a wide array of applications in biotechnology, chemical analysis, and beyond. Full article
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