It sure does. If only it could shift it’s collective mindset and believe in itself again it would be even more powerful! I see so much negative self talk from Europeans in tech and VC.
One of the secret weapons of Silicon Valley is that it believes it can do anything and therefore does.
Keep sharing these stories Sten Tamkivi !!!!
Nanoscale UV-sensitive resins have better curing performance, gloss, and brightness. 🤔But did you know that the actual dispersion state of nanoparticles in the UV-sensitive resin is not always at the nanoscale?
𝗜𝘁'𝘀 𝗮 𝗳𝗮𝗰𝘁: nanoparticles often aggregate due to their high surface energy and low wetting ability with resins. A reliable measurement tool for nanoparticle characterization is necessary to overcome this challenge of maintaining stable dispersion of nanoscale particles.
🔬 In this application note, we used the BeNano Series analyzer to measure the particle size distribution and zeta potential of UV-sensitive resins added with different nanoscale pigments, investigating their dispersibility and stability.
Curious about the findings? 📥Download our app note now to learn more: https://lnkd.in/gQ5Mit2S#BetteSrsize#BeNano#nanoparticleanalyzer#zetapotential#particlesize#3dprinting#resins#additivemanufacturing#DLS#ELS#dlsequipment#zetaanalyzer#nanotechnology
Huaixuan Cao, Micah Green, and colleagues developed a simple and generalized approach to create structured MXene-polymer composites in a water-free system with well-controlled filler distribution and varied composite morphology (e.g., capsules, armored particles, and porous foams). This research not only expands the possible compositions of MXene-polymer architectures but also provides insights into their structure-property relationships, paving the way for developing desired performance-related properties.
#Matterhttps://lnkd.in/eeTC3hxJ
#IJEM's Latest Animated Cover on "Embedding Aligned Nanofibrous Architectures within 3D-Printed Scaffolds -Directing Cellular Infiltration and Tissue Regeneration"!
The cover displays a hybrid scaffold that is a combination of a 3D-printed framework and aligned nanofibrous architectures. This #scaffold is ingeniously designed to facilitate guided cellular infiltration and soft tissue ingrowth.
The yellow 3D-printed framework, distinguished by its customized contour shape and flexible internal microfilaments, provides stable environments for #TissueRepair. Concurrently, the light blue nanofibers enable the formation of aligned #microchannels that effectively guide and promote rapid #CellInfiltration for enhanced soft #TissueRegeneration.
More details on 👉 https://lnkd.in/gkCSV-6N#3DPrinting, #Biofabrication, #AdditiveManufacturing, #Biomaterials, #HybridManufacturing
👉 Do you know our innovative Caladrix Technology?
Combining our experience in material science, biology and chemistry with our state-of-the-art electrospinning equipment, we provide our customers with the future of stent coverings. Through direct deposition of the fibres onto the stent or braid, we can achieve excellent encapsulation whilst our pre-spinning process ensures bonding of the metal to the electrospun textile.
The benefits are:
▪️ Sutureless coating with robust adhesion
▪️ Low profile
▪️ Uniform coating over a range of geometries
▪️ Reduced manufacturing costs
▪️ Wide range of biostable and degradable polymers
▪️ Custom microarchitecture to match biological function
▪️ Single-layer, full encapsulation or selective area coating options
▪️ Inclusion of bioactive molecules
▪️ Target material structure and performance to where it is needed
◾ To find out more about our Stent Cover Technology, click here: http://ow.ly/GIWv50K3bJ4
Today, Katrina Moisley and Matei Cirstea, in collaboration with Confluent Medical Technologies, are excited to participate in the upcoming Textile University Day. During the event, they will leverage their expertise to present innovative advancements in electrospinning.
#electrospinningmachine#equipment#medicaldevice
Here's another post that doesn't focus on our Delaware Flow NanoCytometer™ and #ExtracellularVesicles.
Kinetic River knows that cutting edge research may not be served by standard offerings. That's why we developed the #Shasta, our ultrastable fluidics control module for #FlowCytometry. Suitable for use in your everyday flow cytometry experiments, but also suitable for specialized applications that require the use of specific flow rates, custom delivery paths, or user-adjustable pressures.
Our Shasta technology goes into every one of Kinetic River's flow cytometers.
Put the performance of your flow cytometer in your hands.
Find out more at https://lnkd.in/exHSKt8
Some of the main challenges in atomic/molecular layer deposition (ALD/MLD) involve the combination of high precursor volatility and film stability. The organic precursor plays a crucial part here, especially in "aromatic ALD/MLD".
For instance, the widely employed terephthalic acid (TPA; benzene-1,4-dicarboxylic acid) provides air-stable films but suffers from poor volatility. On the other hand, another commonly employed precursor, hydroquinone (HQ; benzene-1.4-diol), provides reasonable volatility but (often) unstable films.
Here we demonstrate that the less-explored benzene-1,4-dithiol (BDT) precursor provides both excellent volatility (near room-temperature sublimation) and film stability in ambient conditions. Together with the emerging [Zn(DMP)2] metal precursor, a robust (and truly scalable) low-temperature ALD/MLD process for Zn-BDT was established.
Thrilled to announce our latest publication in #small.Our team has successfully developed a cutting-edge low-temperature ALD/MLD process for crafting highly conformal Zn-organic thin films using innovative precursors. 🎉
In the current study, we utilized non-pyrophoric bis-3-(N,N-dimethylamino)propyl zinc [Zn(DMP)2] from #RuhrUniversityBochum and 1,4-benzene dithiol (BDT) precursors to fabricate these remarkable thin films. What makes this achievement even more significant is our demonstration of how the conformality of these films can be easily identified using #PillarHall#LHAR test structures.
A huge shoutout to all our collaborators who contributed their expertise and dedication to make this project a success! 🙌 Special thanks to Chipmetrics,Aalto University, Maarit Karppinen,Anjana Devi,Topias Jussila,David Zanders, Florian Preischel, Jorit Obenlüneschloß, Jussi Kinnunen for their invaluable guidance and support throughout this incredible journey. 🌟
Stay tuned for more updates and exciting developments as we continue to push the boundaries of innovation in materials science! 🚀 #MaterialsScience#ALDMLD#ConformalThinFilmshttps://lnkd.in/dh5G-ef2
Ink Design Enables Slot-Die-Coated Perovskite Solar Cells with >22% Power Conversion Efficiency, Micro-Modules, and 1 Year of Outdoor Performance Evaluation. Devices manufactured with FOM Technologies#AlphaSC at Helmholtz-Zentrum Berlin. It never gets old.
Outstanding ink engineering for fixing ribbing, a common effect observed at the downstream meniscus when the viscous and capillary forces between ink, slot-die, and substrate are unbalanced.
https://lnkd.in/eXp75daf
Coach to Product Leaders | ex-Facebook, Instagram, Nokia, eBay, Skype, Microsoft
2moIt sure does. If only it could shift it’s collective mindset and believe in itself again it would be even more powerful! I see so much negative self talk from Europeans in tech and VC. One of the secret weapons of Silicon Valley is that it believes it can do anything and therefore does. Keep sharing these stories Sten Tamkivi !!!!