Direct Lithium Extraction (DLE) is an innovative method for extracting lithium from brine. For this process to be effective, the brine must be purified, which is where LiqTech’s expertise comes in. Read more about it below.
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Very important step in the right direction
Direct Lithium Extraction (DLE) is an innovative method for extracting lithium from brine. For this process to be effective, the brine must be purified, which is where LiqTech’s expertise comes in. Read more about it below.
LiqTech Receives an Order from a Leading Technology Company for Lithium Brine Production in the U.S.
liqtech.com
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Revolutionizing #Oil Refining: #AI-Driven Polymer Membranes Set to Transform the #Industry In a groundbreaking leap forward, researchers at Georgia Tech have unveiled a transformative #digital system designed to revolutionize #membrane separation in oil refining processes. This high-performance digital system is poised to redefine how polymers are tailored for membrane applications, promising unparalleled #efficiency and #sustainability in the refining industry. Discover more at www.energyHQ.world
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Unlock the power of copper! New research reveals how copper-based catalysts turn CO2 into valuable chemicals like ethylene & ethanol. #Sustainability #Catalysis #GreenEnergy https://lnkd.in/eGDQQQ2N
Cracking the Copper Code
theanalyticalscientist.com
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#DICPResearchNews DICP researchers developed a highly active Cu-doped NiCo alloy (Cu-NiCo/NF) catalyst, and constructed an energy-saving nitrate reduction system coupled with glycerol oxidation, achieving high glycerol electrooxidation activity and selectivity to produce formate at room temperature. Study was published in Angewandte Chemie @angew_chem Learn it more: https://lnkd.in/g72qYdX3
Efficient Electrocatalytic Oxidation of Glycerol to Formate Coupled with Nitrate Reduction over Cu‐doped NiCo Alloy Supported on Nickel Foam
onlinelibrary.wiley.com
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🚀 New scientific paper on the HIGFLY website! 🚀 HIGFLY´s latest publication in ChemSusChem: 📰 "Intensifying Cyclopentanone Synthesis from Furfural Using Supported Copper Catalysts" by Adarsh Patil, Maurik Engelbert van Bevervoorde, and Dr. Fernanda Neira D’Angelo from Eindhoven University of Technology. Research Highlights: 🔬 Objective: Develop sustainable methods to synthesize cyclopentanone (CPO), a bio-based platform chemical and potential jet fuel precursor, from furfural. 🔬 Method: Utilise supported copper catalysts in a continuous flow reactor to optimize the hydrogenation process. 🔬 Key Findings: A two-step catalytic strategy significantly improves CPO yields. This modular approach addresses flexible market needs and enhances process efficiency. Sustainability Impact: 🌱 Promotes the use of renewable biomass feedstocks. 🌱 Reduces reliance on fossil-based intermediates, contributing to a lower carbon footprint. View and download the full paper via the link below ⬇ https://lnkd.in/enthkeAf #horizoneu #chemsuschem #zenodo #sustainableaviationfuel #biofuel #furanics #catalysis #greenchemistry CINEA - European Climate, Infrastructure and Environment Executive Agency
Intensifying cyclopentanone synthesis from furfural using supported copper catalysts
zenodo.org
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Unlock the power of copper! New research reveals how copper-based catalysts turn CO2 into valuable chemicals like ethylene & ethanol. #Sustainability #Catalysis #GreenEnergy https://lnkd.in/eGDQQQ2N
Cracking the Copper Code
theanalyticalscientist.com
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Pseudo-boehmite alumina is a game-changer in the world of catalysis, thanks to its remarkable properties. As a precursor to gamma alumina, it plays a critical role in enhancing the performance of heterogeneous catalysts. Here's why it's highly valued: 🔬 High Surface Area: Provides ample active sites for catalytic reactions, ensuring high efficiency. 🏗️ Porosity: Promotes excellent dispersion of active components, leading to better catalyst performance. 🔥 Thermal Stability: Withstands high temperatures, making it ideal for demanding catalytic processes. Pseudo-boehmite alumina is indispensable in various catalytic applications, including: · Hydroprocessing: Enhances the removal of impurities in petroleum refining. · Fluid Catalytic Cracking (FCC): Boosts the conversion of heavy hydrocarbons into lighter, more valuable products. · Hydrotreating: Improves the quality of diesel and other fuels by removing sulfur, nitrogen, and other contaminants. · Hydrodesulfurization (HDS): Reduces sulfur content in fuels, contributing to cleaner emissions. · Methanol Synthesis: Acts as a robust support in catalysts that convert syngas to methanol. · Automotive Catalysts: Enhances the performance of catalytic converters, reducing harmful emissions from vehicles. Embracing this exceptional material means pushing the boundaries of what's possible in catalytic technology. Let's innovate and transform the future of catalysis together! #Catalysis #Innovation #ChemicalEngineering #Hydroprocessing #FCC #Hydrotreating #HDS #MethanolSynthesis #AutomotiveCatalysts #MaterialsScience #PseudoBoehmite #Alumina #CatalystSupport #SustainableTechnology #MatrixGlobalSpeciality
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Interesting catalyst for CO2 conversion to methanol, based on copper nanoparticles supported on a perovskite (barium titanate). #catalysts #co2conversion
CO2-to-methanol conversion improved with catalyst-support ion swap - Chemical Engineering
chemengonline.com
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Methanol from real metallurgical gases works. #GeCatSInfoday on the topic of catalysis and sustainable energy sources and chemicals. Reliable catalysts are an important prerequisite to produce sustainable energy sources and chemicals such as methanol. It was a great pleasure for me today to present our work on sustainable methanol synthesis from metallurgical gases. Our ongoing research shows that long-term stable methanol synthesis with real metallurgical gases is possible. There were interesting discussions that broadened my perspective. Big thanks to the organizers of the event #circularcarbon #greenmethanol #greenhydrogen
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Direct Lithium Extraction (DLE) is a technology that allows for the fast and efficient isolation of lithium from brine, a process that traditionally takes months to years. This technique involves several chemical processes that enable the production of saleable forms of lithium. DLE has been proven in producing projects in China and South America and is considered a disruptive technology, reducing carbon footprint, operating time, and cash costs compared to traditional lithium extraction and refining methods. *Principal Processing Methods* Direct Lithium Extraction (DLE) technologies can be broadly grouped into three main categories: adsorption using porous materials that enable lithium bonding, ion exchange, and solvent extraction. Additionally, DLE innovations are using sorbents, electrochemical, membrane, and ion exchange technologies, each with its own positives and negatives. *Adsorption Method:* advantages include it enables lithium bonding and can achieve a high lithium recovery and selectivity, but has the disadvantages of high energy, large amount of fresh water, and produces waste residue. *Ion Exchange Method:* advantages include it can achieve a high lithium recovery and selectivity, and some technologies use zero chemicals, however its disadvantage is that it may involve brine pH changes or heating, and requires a large amount of energy and fresh water. *Solvent Extraction Method:* advantages include it can achieve high lithium recovery and selectivity, but has the disadvantages of high energy, large amount of fresh water, and produces waste residue. #lithiumionbatteries #batterytechnology #environmentalsustainability #futureiselectric
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