Nanotech Tales’ Post

How is nanotechnology shaping the future of innovation?🚀 This comprehensive resource covers the fascinating world of nanomaterials and their vast applications. From smart devices and renewable energy ⚡ to environmental sustainability 🌱, these materials are revolutionizing industries and advancing cutting-edge solutions. This guide offers a concise yet detailed overview; whether you’re a student, researcher, or engineer, it provides insights into the profound impact of nanotechnology on our modern world. 🌟 Explore the dynamic realm of nanotechnology and see how it's shaping the future! 🔗Read Now: https://bit.ly/4gnqZQA Editors: Divya Bajpai Tripathy, Anjali Gupta, Arvind Kumar Jain, Anuradha Mishra and Tokeer Ahmad Title: Nanotechnology: A Quick Guide to Materials and Technologies #Nanotechnology #TechAdvancements #BenthamScience

Open 🔑 Access #Nanotechnology and #Nanostructures in #Food #Science: #Advancements & #Applications 📜Research Article : ✍🏻Abhishek Kulkarni #Introduction Nanotechnology is the science and engineering of manipulating materials at the nanoscale, typically between 1 and 100 nanometers (one nanometer is one-billionth of a meter).... #Novel #Packaging #Materials Nano-enabled solutions also allowed the integration of various bioactive molecules and nanoparticles to prevent oxidation and food degradation. Selenium and cellulose NPs can be integrated into food packaging to retard or inhibit the ROS that can degrade food quality... #Conclusion Nanotechnology research for commercial food applications has rapidly progressed, but the development of nanostructures has been slower. Public concern over the safety of nanotechnologybased goods for human consumption and use has increased.... 📰 Get full-length article here: https://lnkd.in/gYgFaZGK We do accept #PPTs and #Video Articles to be publish within our Journal. You can send us your article to given email #Email: onlinescientificresearch@gmail.com

Exciting News in Nanotechnology! I'm thrilled to share that our publication in the Royal Society of Chemistry's journal has reached 244 citations. Our work focuses on innovative approaches in nanoscience, and we've made some breakthrough findings that could potentially reshape how we understand material science applied to the bio world. 🔗 Read the full article here > https://lnkd.in/dtwcx_tW In this study, we explore the complexities and applications of nanomaterials in various industries. The findings underscore the importance of collaboration and continuous research in pushing the boundaries of science and technology. 💡 Key Highlights: Innovative methodologies in nanomaterial synthesis. Detailed analysis of nanomaterial properties. Implications for technology and industry. I would love to hear your thoughts on our research and discuss potential impacts and applications in your fields! #Nanotechnology #ScienceResearch #MaterialScience #Innovation #RoyalSocietyOfChemistry

I am thrilled to share that I have completed a wonderful online course in the field of nanotechnology.🤩 During this course, I learned the principles and fundamentals of nanoscience and the impact of material size on properties. I explored techniques for synthesizing nanomaterials, both top-down and bottom-up, and got to know how to characterize these materials using advanced instruments such as SEM, TEM, XRD, ICP, and Mass Spectroscopy. We also discussed how to utilize these nanomaterials in suitable applications based on their properties, as well as the possibilities for enhancing their characteristics through various modifications. Nanotechnology is a game-changer, impacting every sector imaginable, and i am eager to apply what I have learned in future projects.✨ Let’s push the boundaries of what’s possible! 💡 #NanoTechnology #Research #MaterialsScience #Innovation

I’m excited to announce the release of my latest research publication: "Fabrication of Supported and Unsupported Gold Nanorods for Nonenzymatic Glucose Sensing and Study of Their Growth Kinetics." 🧪✨ In this work, we explored the innovative fabrication of gold nanorods and their application in nonenzymatic glucose sensing. Our study delves into both supported and unsupported nanorods, providing valuable insights into their growth kinetics and how these factors impact their efficiency in glucose detection. This research offers significant potential for advancing glucose sensing technologies, particularly in creating more stable and efficient sensors without the need for enzymes. The findings could pave the way for new developments in the field of biosensors and nanotechnology. I’m incredibly grateful to my collaborators and mentors for their support throughout this project. Their contributions were essential in bringing this work to fruition. If you’re interested in nanotechnology, biosensors, or glucose sensing, I’d love to hear your thoughts or discuss potential collaborations! You can access the full publication here: https://lnkd.in/dgFfYeR4 #Research #Nanotechnology #Biosensors #GlucoseSensing #Innovation #AcademicAchievement

🌟 Exciting Breakthrough in Nanotechnology! 🌟 Scientists at Lund University and Hokkaido University have created 2D gold monolayers, a new type of super-thin material with groundbreaking potential. Here’s what makes it special: New Method: They used a clever process to grow the gold layers on a special base, adding boron atoms to keep the structure stable. Better Properties: This method makes the gold more stable and durable, solving problems scientists faced before. Wide Applications: The unique features of this gold could be used in catalysis, electronics, and energy innovations. This discovery could pave the way for amazing advancements in future technologies! 🔗 Read more: Full Article At RAIB, we love sharing exciting research like this. Let’s work together to explore the future of science! 📧 Contact us at rainstitute.bd@gmail.com. #Nanotechnology #Innovation #MaterialsScience #RAIB

As published in the prestigious Advanced Materials journal, Prof. Malachi Noked and his team have made a significant leap in sodium-ion battery technology. Their innovative research presents a cobalt-free cathode with impressive capacity, achieved through a high-entropy method that blends multiple elements into a single phase. This is a challenging task due to the complex interactions between the elements. Choosing oxyfluoride materials to reduce oxygen loss and adding lithium to the equation enhanced the crystal structure’s stability and improved the kinetics of the battery’s charge and discharge processes. The result? In early testing, a robust cathode with a reversible capacity of 109 mAh g−1 at 2–4 V and 144 mAh g−1 at 2–4.3 V shows great potential for long-term stability. This approach has successfully minimized phase transitions during battery operation, as evidenced by in-depth diffraction studies. Prof. Noked’s promising findings guide future research toward efficient, high-entropy cathodes for sodium-ion batteries. Dive into the full study for a deeper understanding: https://lnkd.in/dzT8w_DB Malachi Noked Bar Ilan Institute for Nanotechnology and Advanced materials (BINA), Bar Ilan University

Hey all, I'm Kiran Raghav J, a Mechanical Engineering undergrad passionate about Material Science and Nanotechnology. I’m thrilled to share that my very first blog on nanotechnology is now live! This blog explores the intriguing world of nanomaterials, covering their types, applications, challenges, and future potential. A heartfelt thank you to Professor Dr. Samuel Ratna Kumar P S for their exceptional mentorship and support. 🌐 Check out the blog here: https://lnkd.in/g9cxsXtC I’m eager to hear your thoughts and connect with fellow professionals and enthusiasts. Please feel free to leave your comments or questions below! #Nanotechnology #Nanomaterials #ResearchBlog

🌿 Green Nanotechnology Meets Antibacterial Innovation 🌟 Sustainability is the future, and researchers are turning to nature for inspiration. A recent study published in AIP Advances showcases how the humble goji berry, a well-known superfood, is being used to create antibacterial silver nanoparticles (Ag-NPs). 🧪 What’s the innovation? Researchers from Sapienza University of Rome, NED University of Engineering and Technology, and King Saud University have developed a simple, eco-friendly method to synthesize Ag-NPs using store-bought goji berries. These berries, rich in bioactive compounds, act as natural reducing and stabilizing agents, eliminating the need for harmful chemicals. 🔍 How it works: 1️⃣ Goji berries are dried, ground, and filtered to create an extract. 2️⃣ This extract is combined with silver nitrate (AgNO₃) to produce silver nanoparticles. 3️⃣ Techniques like X-ray diffraction, UV-Vis spectroscopy, and FT-IR spectroscopy confirm the nanoparticle formation. 🦠 Impact: The Ag-NPs exhibit strong antimicrobial activity, effectively inhibiting Staphylococcus aureus, a bacterium responsible for staph infections. 🌱 Why it matters: The method is simple, scalable, and non-toxic. No additional chemicals or complex equipment are required, making it energy-efficient. It aligns perfectly with sustainable practices in material synthesis. 💡 What’s next? The researchers aim to study the biocompatibility and cellular toxicity of these nanoparticles, paving the way for their use in biomedical applications. 📢 This breakthrough is a testament to how interdisciplinary research can merge sustainability and innovation, offering green solutions to global challenges. Let’s embrace nature-inspired science for a sustainable future! 🌍 #GreenNanotechnology #Sustainability #AntimicrobialResistance #Innovation #Nanotechnology