Advances In Nanomaterials For Engineering Use

Mapping Gas Adsorption on Platinum-Gold Nanostructures Could Advance Catalysis and Gas Separation Researchers at Tokyo Metropolitan University have made significant advancements in understanding gas adsorption on platinum and gold nanostructures, revealing new insights into catalytic and gas separation technologies. Their study, focusing on the unique crystalline solid [PtAu8(PPh3)8]-H[PMo12O40] (PtAu8-PMo12), provides real-time data on how hydrogen and carbon monoxide interact with nanoscale metal clusters. Key Findings • High-Speed X-ray Absorption Spectroscopy: • Researchers used quick-scan X-ray absorption techniques to track gas adsorption events every 0.1 seconds. • This real-time analysis allowed them to observe how gases influence atomic arrangements within platinum and gold nanostructures. • Nanoscale Voids Impact Gas Transport: • The study reveals how nanotunnel structures within these materials affect the adsorption and movement of gases, crucial for developing high-efficiency catalysts and gas separation membranes. • Ligand-Protected Metal Clusters Enhance Catalytic Properties: • Ligand stabilization modifies the geometric arrangement of platinum and gold atoms, creating distinct electronic properties superior to bulk metals in catalytic reactions. Why This Matters • Advancing Sensor and Gas Separation Technologies: The insights from this study could improve the efficiency of gas sensors and filtration materials, impacting environmental and industrial applications. • Enhanced Catalyst Design for Hydrogen Reactions: Understanding gas-metal interactions at the atomic level will help optimize catalysts for fuel cells, hydrogen storage, and CO2 conversion. • Breakthroughs in Nanomaterial Engineering: By manipulating nanostructures, researchers can fine-tune the properties of metal clusters, leading to next-generation catalytic materials. What’s Next? • Exploring Other Metal Combinations: Future studies may investigate how different metal compositions affect gas adsorption and catalytic performance. • Application in Industrial Catalysis: The findings could be applied to hydrogen fuel production, CO2 reduction technologies, and energy-efficient chemical synthesis. • Further Development of Gas Storage Materials: The ability to control gas adsorption at the nanoscale could lead to new storage solutions for hydrogen energy applications. This research represents a major leap in nanotechnology and materials science, paving the way for more efficient and sustainable catalytic processes and gas separation technologies.

🦾 Materials Stronger Than Steel and lighter than foam Researchers have developed carbon nanolattices with an exceptional specific strength of 2.03 MPa m³/kg—setting a new benchmark in lightweight structural materials. 🤓 Geek Mode The magic lies in the synergy between Bayesian optimization, nanoscale manufacturing, and pyrolytic carbon. Using multi-objective Bayesian optimization, scientists designed lattice structures that significantly outperform traditional geometries. At the nanoscale, reducing strut diameters to 300 nm yields carbon with 94% sp² aromatic bonds, dramatically increasing strength and stiffness. These lattices combine the compressive strength of steel with densities as low as 125–215 kg/m³, achieved through high-precision 3D printing and pyrolysis techniques. 💼 Opportunity for VCs This innovation is a platform for lightweighting in industries where every gram matters. From fuel-efficient aerospace components to resilient energy systems and next-gen robotics, the potential applications are vast. Companies building on these nanolattices will redefine design limits for pretty much anything! The scalability demonstrated here—printing 18.75 million lattice cells within days—positions this tech for real-world adoption. 🌍 Humanity-Level Impact Lighter, stronger materials mean reduced fuel consumption, lower carbon emissions, and more sustainable engineering solutions. These lattices also pave the way for more efficient energy storage systems, ultra-durable medical implants, and safer infrastructure—all crucial for the next century of our civilization. 📄 Link to original study: https://lnkd.in/gZpGC5Qy #DeepTech #AdvancedMaterials #Sustainability #VCOpportunities Tom Vroemen

We are excited to announce the publication of our latest work on "Boron Nitride Nanotubes Induced Strengthening in Aluminum 7075 Composite" in Advanced Composites and Hybrid Materials journal Al7075 has long been a benchmark for lightweight, high-strength structural metals. In this study, we’ve taken Al7075 to the next level by reinforcing it with boron nitride nanotubes (BNNTs), achieving an exceptional ~637 MPa ultimate strength 2.9x stronger than cast Al7075 alloy while maintaining excellent ductility with >10% elongation to necking. To overcome the challenge of dispersing BNNTs effectively in Al7075 powder, we developed an innovative multi-step process, including ultrasonication and milling at cryogenic temperatures. The composite powder can also be cold sprayed to form high-strength Al7075-BNNT coatings. SPS of Al7075-BNNT powder enabled the creation of a homogeneously reinforced composite with ultra-fine grains and robust interfacial bonding. The work delves deep into the synergistic strengthening mechanisms, including Hall-Petch, Orowan, dislocation-induced strengthening, and load transfer effects, revealing how BNNT dispersion can improve strength without sacrificing ductility. These findings open exciting opportunities for applications in aerospace, next-generation vehicles, and racing/automotive industries, where ultra-lightweight, ultra-strong materials are essential for performance and fuel efficiency. Thanks to my Postdoc Sohail M.A.K. Mohammed for leading this effort with incredible co-authors Ambreen Nisar, PhD, Denny John, ABHIJITH K S,Yifei Fu,Tanaji Paul, Alexander Franco Hernandez, and Sudipta Seal Enjoy reading the article: https://lnkd.in/eu8eHGsM Cold Spray and Rapid Deposition (ColRAD), Cam C., BNNT (Boron Nitride Nanotubes) #MaterialsScience #BNNT #Aluminum #AerospaceEngineering #Innovation #SPS #Research #LockheedMartin #BlueOrigin

🚧 Can "Smart Nanotech Concrete" Tackle Both Frost Damage and Climate Change? ❄️🌍 Two recent studies from the University of Miami and Washington State University showcase a significant advance toward low-carbon, high-durability infrastructure, thanks to a patented clinker-free geopolymer concrete. 🧪 What’s New? Graphene Oxide + Geopolymer Paste ➤ Adding just 0.02% graphene oxide (GO by mass of ash) to fly ash-based geopolymer paste makes a notable difference. No cement is needed for this type of concrete! ➤ The result? Much better strength retention after 84 rapid freeze-thaw cycles and stronger resistance to post-damage carbonation. ➤ GO improves hydration chemistry and reduces moisture uptake—key for durability in cold, wet regions. CFRP-Confined Geopolymer Columns ➤ Researchers encased GO-modified geopolymer concrete in carbon fiber-reinforced polymer (CFRP) tubes, creating high-strength, ductile structural members. ➤ Life Cycle Assessment (LCA) over a 100-year lifespan shows: ✅ Up to 34% lower CO₂ emissions than traditional cement concrete columns ✅ Excellent resilience, even under extreme loading and environmental conditions 💡 Why It Matters These innovations pave the way for next-generation infrastructure—stronger, greener, and more resilient. 👷♀️ Civil engineers: Ready to rethink your materials? 🎓 This is where chemistry, mechanics, and sustainability converge. 📚 Learn more: • Li & Shi, Cement and Concrete Composites, 2025 – https://lnkd.in/g-5hRfHi • Li et al., Transportation Research Record, 2025 – https://lnkd.in/gpbWKkS3 #CivilEngineering #FlyAsh #Geopolymer #GrapheneOxide #FrostResistance #CFRP #SustainableConstruction #ConcreteInnovation #LifeCycleAssessment #InfrastructureResilience #STEM #FutureEngineers