Resonetics’ Post

🚀 Revolutionize Your Metal Analysis with the Niton Handheld XRF System from Thermo Fisher Scientific Inc🛠️ In today's fast-paced metal industries, precision, efficiency, and reliability are paramount. Every decision, from production to quality control, hinges on accurate elemental analysis. That's where Thermo Scientific's Niton Handheld XRF System steps in – a game-changer poised to transform your metal analysis processes. Here's why the Niton XRF System stands out: Precision and Accuracy ✨ Experience unparalleled accuracy in elemental analysis with the Niton XRF System. Trust the results to make critical decisions with confidence, knowing that precision is at the core of every analysis. Portability and Flexibility 🌍 Say goodbye to time-consuming lab processes. The Niton XRF System's handheld design allows for on-the-spot analysis, bringing the lab to the metal source. Real-time results empower your team to make swift decisions, saving valuable time and resources. Streamlined Workflow 🔄 Navigate through your metal analysis tasks seamlessly with the Niton XRF System's user-friendly interface. Rapid analysis capabilities ensure that your workflow remains efficient, enhancing productivity across the board. Comprehensive Elemental Analysis 🔍 Detect and quantify a wide range of elements with ease. From trace elements to major constituents, the Niton XRF System provides comprehensive analysis to ensure that your metal meets the required specifications and standards. Reliability and Durability 💪 Designed to thrive in industrial environments, the Niton Handheld XRF System is built tough. Its robust construction ensures consistent performance even in the most challenging conditions, offering reliability you can count on. Ready to experience the future of metal analysis? Discover how the Niton XL5plus can revolutionize your manufacturing processes. Schedule a demonstration today, and let us answer any questions you may have. Don't settle for outdated methods – embrace innovation with Thermo Scientific's Niton Handheld XRF System. Contact us now to elevate your metal analysis to new heights. Your success is our priority. 🚀🔬 #thermofisherscientific #XL5plus #metallurgy #KRAHNChemie #KRAHNHellas #innovation #XRF #XRFSystem #NITON

Our work on how monolayers of 2D materials can modify the thermoelasticity of substates has been published! If you wish to take a look, follow the link 🙂

🌟 **Innovating with Spark Plasma Sintering (SPS) at California Nanotechnologies Inc (TSX.V: CNO.V, OTCMKTS: CANOF) ! 🌟 At California Nanotechnologies, we are pushing the boundaries of material science with Spark Plasma Sintering (SPS). One often understated quality of this advanced technology is that it is incredibly effective for diffusion bonding, enabling us to join a wide range of materials with unmatched precision and strength. Diffusion bonding is a solid-state process that joins materials by applying heat and pressure, allowing atomic diffusion across the surfaces to create a strong, seamless bond without melting the materials. At our new facility we will be able to bond parts that are 16+” OD! From aerospace to biomedical applications, SPS is revolutionizing how we think about material design and fabrication. Whether it's creating high-performance components for engines, bonding advanced heat exchanger components or developing new medical devices, the versatility of SPS is paving the way for next-generation innovations. 🔍 Curious about how SPS can benefit your projects? Learn more here at https://lnkd.in/gybQCanY #MaterialScience #Nanotechnology #SparkPlasmaSintering #DiffusionBonding #AdvancedManufacturing #Innovation #Aerospace #Biomedical #CaliforniaNanotechnologies #EngineeringExcellence

𝐏𝐮𝐛𝐥𝐢𝐜𝐚𝐭𝐢𝐨𝐧 𝐚𝐥𝐞𝐫𝐭 🔔 🔄 Although #centrifugal #microfluidics, also known as #Lab_on_a_disk (LOD), offers a promising solution for liquid pumping and manipulation with minimal instrumentation, many researchers and engineers still favor the #Lab_on_a_chip (LOC) system. This preference is evident in conference presentations and the number of companies servicing researchers in this area. While there are several reasons for this preference, there are key limitations to centrifugal systems: 1️⃣ #Unidirectional flow control can be a significant limitation. The outward flow direction dictated by centrifugal force complicates microfluidic disk design, requiring expertise to create functional, cost-effective units that operate microfluidic functions (such as metering, mixing, and separation) within a reasonable time frame, preferably less than a minute. 2️⃣ #Disk fabrication is typically costly and time-consuming, requiring expertise in CNC machining to engrave microfluidic circuits on machinable materials like PMMA. #Resin #3Dprinting offers a more cost-effective and rapid prototyping solution, but finding a building plate to print a 10 cm disk for a required resolution significantly increases costs. 3️⃣ Despite being cost-effective compared to LOC benches, fabricating a centrifugal bench requires programming and instrumentation skills before conducting any #bioassays. 4️⃣ A robust and simple valving system is essentially required to #control the #fluid flow, but simultaneously achieving simplicity and #cost-efficiency is already a challenge. 📝 In our recent article titled "𝐅𝐥𝐢𝐩𝐩𝐢𝐧𝐠: 𝐀 𝐕𝐚𝐥𝐯𝐞-𝐅𝐫𝐞𝐞 𝐒𝐭𝐫𝐚𝐭𝐞𝐠𝐲 𝐭𝐨 𝐂𝐨𝐧𝐭𝐫𝐨𝐥 𝐅𝐥𝐮𝐢𝐝 𝐅𝐥𝐨𝐰 𝐢𝐧 𝐂𝐞𝐧𝐭𝐫𝐢𝐟𝐮𝐠𝐚𝐥 𝐌𝐢𝐜𝐫𝐨𝐟𝐥𝐮𝐢𝐝𝐢𝐜 𝐒𝐲𝐬𝐭𝐞𝐦𝐬", published in Sensors and Actuators B (Chemical 8.4), we addressed the aforementioned LOD drawbacks by introducing the "𝐜𝐡𝐢𝐩 𝑶𝑵/𝑶𝑭𝑭 𝐚 𝐝𝐢𝐬𝐤" strategy. The article is available online for free until June 11, 2024, via the link below. 🌐 https://lnkd.in/emxrX624 🎥🎬 The video below provides a summary of this work. Please don't hesitate to reach out with any questions, suggestions, or comments. 🙌🔚 Last but not least, I want to sincerely thank project coordinator Gabriel Mazzucchelli, and supervisor Tristan Gilet for their active contribution to this research study. ULiège Département Aérospatiale et Mécanique Service public de Wallonie #centrifuge #Lab_on_a_disk #Lab_on_a_chip #bidirectional #flow_control #eppendorf #chip_on_a_disk #proteomics

❓ Are you looking to enhance your nanoparticle manufacturing processes with real-time, precise monitoring? ❓ In the fast-evolving world of manufacturing and quality control, Process Analytical Technology (PAT) is a game-changer. It enables real-time monitoring and control of production processes, ensuring higher efficiency, better quality, and reduced waste. 🔍 Why PAT Matters: - Real-Time Monitoring: Gain immediate insights into your processes. - Enhanced Quality Control: Ensure consistent product quality. - Increased Efficiency: Optimize processes and reduce downtime. - Regulatory Compliance: Meet stringent industry standards with ease. 🌟 Why not check out the NanoFlowSizer (NFS) by InProcess-LSP, a cutting-edge, non-invasive PAT tool designed for continuous, real-time nanoparticle size characterization. Utilizing Spatially Resolved Dynamic Light Scattering (SR-DLS) technology, the NFS offers unparalleled accuracy and versatility. Key Benefits of NFS: - Non-Invasive Measurements: Perform measurements through glass, avoiding sample contamination. - High-Speed Analysis: Obtain results in seconds, perfect for in-process monitoring. - Versatile Applications: Ideal for colloidal systems, nanosuspensions, and more. - Handles Turbid Samples: Accurate measurements even in highly turbid environments. 🔗 Learn more about how the NanoFlowSizer can revolutionize your PAT strategy: https://lnkd.in/eyVUqMz7 Embrace the future of manufacturing with advanced PAT solutions. Let’s drive innovation and excellence together! 💡 #ProcessAnalyticalTechnology #PAT #NanoFlowSizer #InProcessLSP #ManufacturingInnovation #QualityControl #Nanotechnology

🔬💊 Hybrid Models to Support Fluid Bed Granulation Process Development 🔄 🌪 The integration of mechanistic and data-driven models, known as hybrid modeling, offers a powerful strategy for advancing fluidized bed granulation processes. By combining empirical process knowledge with multivariate data from process analytical technology (PAT) sensors, hybrid models bridge the gap between theoretical models and real-world processes. 📊 This study by Maksym Dosta, Ragna Hoffmann, Peter Schneider and Martin Maus demonstrates the application of hybrid modeling to fluidized bed spray agglomeration and fluidized bed layering or coating processes. The proposed strategy has been shown to support process development across different scales, resulting in improved process understanding, the creation of regime maps, and the potential generation of digital twins. Key Insights: 🔍 Hybrid Modeling Strategy: Integrates mechanistic and data-driven models to enhance the accuracy and applicability of fluid bed granulation processes. 🔄 Process Development Support: Successfully applied to fluidized bed spray agglomeration and layering/coating processes, providing valuable insights across different scales. 📈 Improved Process Understanding: Facilitates the creation of regime maps and enhances overall process comprehension. 🌐 Quality-by-Design Integration: Ensures a smooth incorporation of QbD principles into the development of oral solid dosage forms. 💡 Digital Twin Potential: Paves the way for the generation of digital twins, further advancing process optimization and control. 📚 Link to Publication: https://lnkd.in/d8UgRaPF #HybridModeling #FluidBedGranulation #ProcessDevelopment #QualityByDesign #Biomanufacturing #DigitalTwin #PolyModelsHub

Pleased to share the release of our latest #scientificpublication introducing an #opensource modeling tool using a dynamic mesh technique, validated against analytical solutions, numerical, and experimental results in various conditions and kinetic controls 🔗 🔎Highlights of this paper include: - Open-source modeling tool based on dynamic mesh technique - Validated against analytical solutions, numerical, and experimental results - Incorporating pulse reverse plating in dynamic mesh method - Proposed modified Wagner number for predicting optimal conditions - Application in metal production, surface finishing and electronics 👏Congratulations to the authors Alejandro Nicolás Colli, Xochitl Dominguez Benetton, Jan Fransaer for this innovative approach with great potential to improve practical applications in #electrochemical deposition and dissolution processes. #electrodeposition #electrodissolution #manufacturing #surfacefinishing #electroforming #electroplating #electrowinning #anodization #electropolishing #electrorefining #corrosion #electrochemistry

Did a super-simple quick study on the re-entrant auxetic cell this morning, simulated under (meshless!!!) quasi-static compression with the BASF TPU-01 material in the Metafold 3D platform. What is visually apparent (and reflected in the numeric data too) is that while the fully symmetric version seems to distribute the stress most uniformly, there is an asymmetric selection that also performs extremely well. Asymmetric cells may have desirable properties to resist directional forces, which are useful for specific impact-mitigating applications. I think it took me longer to make the gif than to run the sims! 😂 Prepare to be hypnotized! #metamaterials #additivemanufacturing #simulation

🚀 New Blog Alert: Part 2 of our polymer identification series is here! 🚀   Imagine stumbling upon a box of material with no label or documentation. What do you do? Scrap it or try to identify it?   In part 2, Tim Spurrell dives into advanced methods for identifying unknown polymers. From spectroscopic and thermal to chromatographic, microscopic, mechanical, and rheological analysis, we've got you covered.   Unlock the secrets of polymer characterization and take your knowledge to the next level!   🔗 Read it now: https://lnkd.in/gvxyU8HH #Nexeoplastics #plastics #plasticsindustry

PCBA纳米真空镀膜，顶级的防水工艺！派瑞林纳米真空镀膜工艺，被镀物表面形成：几微米厚 高透明 抗高压绝缘层，PCBA泡不坏！ Micro and nano processing technology: chemical vapor deposition (CVD) Put the powdered nano-materials into the evaporation chamber of the vacuum nano-coating equipment, and evaporate into gaseous molecules at a temperature of 150℃-180℃. Under the action of vacuum (1.0*10-2torr), the gaseous nanomolecules below 10nm enter into the cracking In the cracking chamber, the high temperature at 680°C-700°C is cracked into reactive monomers, and the active monomers and monomers are re-polymerized to form a dense and pinhole-free nano-film layer. #cvd #nano processing #chemical vapor deposition#nano-materials#vacuum nano-coating #nano-film layer