Spingenix’s Post

Gorgeous work on pre-prototyping of Molecular FCN including clock delivery based on #SCERPA simulator. Thanks to Federico Ravera for dedicating effort and a lot of accurate analyses and deep insights that pave the way to the demonstration of the Molecular Field Coupling Nanocomputing principle. #nanocomputing #nanotechnology #FCN #nanoelectronics #molecularelectronics #molecules #nanofabrication #clock #latency #pipelining #ICT #digital #PolitecnicodiTorino #polito #futurecomputing #quantumcomputing #quantumphenomena #DFT #finitelelementsimulation

Shuailong Zhang and Mohamed Elsayed from the Prof. Aaron Wheeler's lab at the University of Toronto have utilized Mightex’s #Polygon1000 to examine how light pattern thickness affects the control of dielectric microparticles through optoelectronic tweezers (OET). Their study found that by adjusting the thickness of light patterns, the movement of microparticles can be significantly influenced. Thicker light patterns were shown to increase the force on particles, although beyond a certain point, this effect tapers off. This research underscores the adaptability of OET technology for various applications, including bio-analyte manipulation and microrobotics. The Mightex #Polygon1000 remains an essential tool for advancing these studies. 👉 Explore the full study here: https://lnkd.in/djEqeeHD 📅 Join us at #MicroTAS 2024 in Montreal from October 13-17. Visit us at Booth # 10 to discuss recent developments—we’re looking forward to connecting with you!

Nanotechnology is revolutionising the way we approach engine lubrication. This webinar will explore how this advanced technology is pushing the boundaries of lubrication engineering, Save the Date: 📆 28th November 2024 (Thursday) 🕚 11.00 am Click https://bit.ly/3OhKs9s or catch the live broadcast on MBOT Facebook page. No pre-registration needed, fill in the attendance sheet during the QnA session. #MBOT #webinar #MBOTThursweb #CPD #technology #nanotechnology

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Delighted to share our latest research on #4Dprinting of #PLA-#PBAT-#Fe₃O₄ #nanocomposites! By blending #biodegradable PLA with flexible PBAT, we’ve created a composite that overcomes the brittleness of pure PLA, offering enhanced toughness and flexibility while maintaining #biodegradability. This blend, combined with 10 wt% Fe₃O₄, leads to mechanical improvements, achieving a 16% increase in ultimate tensile strength (UTS) to 35.89 MPa. Our nanocomposites also exhibit rapid #shapememory recovery (up to 100%) under both thermal and #magnetic stimuli, with #recovery times as fast as 3 seconds. The addition of Fe₃O₄ nanoparticles provides #multifunctionality, allowing for remote, contactless activation! This work opens the door to exciting applications in biomedical and aerospace devices with remotely controlled actuation features. Full details can be found in the open access paper <https://lnkd.in/eTR3Q9hS> published by Wiley in Macromolecular Rapid Communications Journal. Research Team: Mohammad Amin Yousefi, Davood Rahmatabadi, Majid Baniassadi, Mostafa Baghani, Mahdi Bodaghi

Efficiency meets innovation: our electrospinning equipment empowers groundbreaking research! exploring the endless possibilities of nanofibers fabrication!⚡ #NSLAB #Nanomaterials #FutureOfFabrication #nanofabrication #Nanotechnology #Elmarco #Electrospinning #ResearchRevolution #InnovationInAction

Yesterday, at the Innovation Day for SMEs hosted by the Bundesministerium für Wirtschaft und Klimaschutz (BMWK), Fraunhofer IWS scientist Lukas Nitschke had the opportunity to showcase our DLIPµcube. This state-of-the-art equipment is designed for #SurfaceFunctionalization using Direct Laser Interference Patterning (#DLIP). It features the most compact scanner-based direct #Laser interference system currently available for creating periodic surface structures ⚡️.   💡 This cutting-edge technology is particularly impactful in producing multifunctional films through laser-based micro- and nanostructuring of tools for lab-on-chip systems, as impressively demonstrated in the ReMultiMi project (Replicative Manufacturing of Multifunctional Microfluidic Foils).   The project aimed to achieve film multifunctionality independently of their chemical composition by laser-based micro- and nanostructuring of replication tool surfaces, enabling efficient adjustments to hydrophilic and hydrophobic properties. To this end, one-step processes using direct laser writing (DLW) and direct laser interference patterning (DLIP) have been developed.   👉🏼 Learn more about the ReMultiMi project: https://lnkd.in/e-Ur3Wwd   #LightAtWork #Biomimicry Coypright image: © Fraunhofer IWS

Dive into the realm of advanced nanotechnology and material science with Zurich Instruments Lock-in Amplifiers! 🌟 Uncover the subtle properties of novel materials at near-atomic scales with unparalleled precision. Whether you're in noisy or quiet environments, these instruments provide ultra-low-noise electronics for adaptable, optimized experiments. Effortlessly measure current, voltage, phase, and impedance at both DC and AC levels while directly assessing noise – all with a single device! 🚀🚀 Learn more: https://lnkd.in/d8tEmUaX #zurichinstruments #materialscience #nanotechnology

I'm very pleased to share a new Editor's Choice article for Nano Trends: This article investigates a cyclic synthesis method for ultrathin 2D nanomaterials based on the ionic layer epitaxy (ILE) method, a solution-based self-assembly process for growing 2D nanomaterials over a large area. This work advances the ILE method by repeatedly refreshing the surfactant templates and recycling the reactant solution, enabling repeated synthesis of Co(OH)2 2D nanosheets in over 84 cycles. This continuous approach may shed light on the design of autonomous and sustainable synthesis of 2D nanomaterials for advanced electrocatalysis development. Nano Trends is a fully open access journal. Read the article: https://lnkd.in/ghHqZBya

Gain insight into how nanotech is able to use your body’s own energy supply to fuel the process of building polymer structures within your blood.