Do you happen to work with products that use AEMs? Someone I know has a patented AEM and want to get him more companies that want samples for testing My good deed of the day - I have no financial investment in this company - you can reach out to them yourself if you’re an investor or want a sample Tuffbrane.com Things AEMs can be used for: ⚡ ENERGY & POWER SYSTEMS Hydrogen Technologies • AEM Water Electrolyzers (AEMWE): Produce hydrogen via water splitting. • AEM Fuel Cells (AEMFCs): Generate electricity from hydrogen. • Hydrogen purification and compression: Utilize electrochemical methods. Electrochemical Energy Conversion • Electrochemical CO₂ reduction (CO₂RR): Convert CO₂ into fuels like methane. • Electrochemical nitrogen reduction (N₂RR): Produce ammonia. • Electrochemical ammonia synthesis: Generate ammonia from nitrogen. Energy Storage • Redox Flow Batteries (RFBs): Store energy with AEM-based systems. • Metal-air batteries (e.g., Zn-air, Fe-air): Use AEMs for improved performance. • Hybrid capacitors: Explore AEMs for enhanced energy storage. Methane Production & Power-to-Gas • Sabatier Reaction: Convert CO₂ and H₂ into methane for synthetic natural gas. • Electromethanogenesis: Biologically produce methane using AEMs. • Power-to-Gas Systems: Store renewable energy as methane. 🧪 INDUSTRIAL & CHEMICAL PROCESSES Electrosynthesis & Chemical Production • Chlor-alkali processes: Produce NaOH, Cl₂, and H₂. • Hydrogen peroxide (H₂O₂) synthesis: Generate H₂O₂ electrochemically. • Organic compound synthesis: Facilitate oxidation/reduction reactions. Ion Separation & Recovery • Anion exchange chromatography: Separate ions in analytical chemistry. • Selective ion recovery: Extract valuable ions like phosphate. • Precious metal recovery: Recover metals like Au, Pt, Pd.() Water & Wastewater Treatment • Electrodialysis (ED): Desalinate and purify water. • Reverse Electrodialysis (RED): Generate energy from salinity gradients. • Removal of anionic contaminants: Eliminate nitrates, sulfates, phosphates. 🌍 ENVIRONMENTAL & SUSTAINABILITY Carbon Capture & Utilization • CO₂ electroreduction: Convert CO₂ into useful chemicals. • Alkaline CO₂ absorption loops: Capture CO₂ in industrial processes. Biogas Upgrading • Methane enrichment: Enhance biogas quality by removing CO₂. • Integration with electrolyzers: Use AEMs to improve biogas systems. Air Purification • Electrochemical air purification: Remove pollutants using AEMs. • Alkaline gas scrubbers: Clean industrial emissions.() 🚀 SPACE & AEROSPACE APPLICATIONS Life Support Systems • Sabatier Reactors: Recycle CO₂ and H₂ into water and methane on the ISS. • Water recovery systems: Utilize AEMs for efficient water reclamation. In-Situ Resource Utilization (ISRU) • Methane and oxygen production on Mars: Generate fuel and life support resources using Martian CO₂ and water. • Electrolyzers for space missions: Produce essential gases for long-duration missions. 🧬 BIOTECHNOLOGY & MEDICAL Bioelectrochemical Systems • Microbial Fuel Cells (MFCs): Generate electricity from organic matter. • Microbial Electrolysis Cells (MECs): Produce hydrogen or methane biologically. • Bioelectrosynthesis: Synthesize chemicals using microbial processes. Medical Applications • Hemodialysis membranes: Explore AEMs for blood purification. • Diagnostic biosensors: Develop sensors for medical diagnostics. 🏭 INDUSTRIAL & MANUFACTURING Mining & Metallurgy • Acid mine drainage remediation: Treat contaminated water from mining. • Metal ion separation: Extract valuable metals from ores. Textile Industry • Dye separation and recovery: Remove and recycle dyes from wastewater. • Effluent decolorization: Clean textile industry wastewater. Food & Beverage • Deacidification of juices and wine: Improve taste and stability. • Electrodialysis of dairy products: Process whey and other products. Electroplating • Metal ion recycling: Recover metals from plating processes. • pH regulation: Maintain optimal conditions in electroplating baths. 🧱 MATERIALS SCIENCE & RESEARCH Membrane Electrode Assembly (MEA) • Fuel cell MEAs: Develop efficient AEM-based assemblies. • Integration in composite membranes: Combine AEMs with other materials for enhanced performance. Catalyst Support • Functionalized AEMs: Incorporate catalytic groups for improved reactions. • Embedded nanoparticles: Enhance electrocatalysis within AEMs. Research & Education • Electrochemical cell development: Prototype new energy systems. • Battery chemistry testing: Explore AEMs in various battery configurations. • Membrane material comparisons: Study performance differences between AEMs and other membranes. 🤞🏾🫶🏽😶‍🌫️💨🚀🌙👽 https://Linktr.ee/x52x @mphinance - here are 2 of the closest ones - Good luck stitching that shit on a hat 🤣🫶🏽 🐦‍🔥