📣Don't miss the chance to submit your abstract for #IBPC2024! The next International Battery Production Conference will take place from November 27 to 29, 2024 in #Braunschweig. This is your chance to showcase your innovative research, cutting-edge developments, and groundbreaking ideas to a global audience of industry leaders, researchers, and professionals. Abstract Submission Deadline: July 7, 2024 IBPC Braunschweig #conference #battery #callforabstracts https://lnkd.in/ezYUP9Dg
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[💡R&D] Lithium–sulfur batteries (LSBs) demonstrate superior energy density, thanks to TUBALL™ slurry, making them promising candidates for next-generation energy storage. Chinese researchers have developed a high-loading SPAN electrode with enhanced integrity and charge transport, achieved through cobweb-structured nanotube networks and interactions between PDA and PVP. The battery exhibits stable cycle performance even at high loading, as detailed in an article published in Nano Macro Small. Read the article in full here: https://lnkd.in/edbFCUyK Learn more on graphene nanotube applications and uses: https://lnkd.in/epQtWN_W #randd #LSB #electrode #battery
Mussel and Cobweb Inspired High Areal Capacity SPAN Electrode
onlinelibrary.wiley.com
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Materials scientist for Energy Conversion & Storage applications at Khalifa University, UAE ➡️Fuel Cells➡️Secondary Batteries➡️Electrocatalysts➡️Hydrogen Economy➡️ Renewable Energy
📚 Exciting Announcement: Journal Article on "Divalent Co-Dopant's Role as Structure Stabilizer in Scandia-Stabilized Zirconia Electrolyte for SOFC" 🚀 Thrilled to share my recent publication in the Journal of the Electrochemical Society, exploring the impact of divalent cations' atomic size on ionic conductivity and long-term aging in scandia-stabilized zirconia electrolytes for SOFCs. These findings open avenues for stable, highly conductive electrolytes, contributing to more sustainable and efficient energy solutions. 🌐💡 🙌 Special thanks to my outstanding team and collaborators for their dedication and expertise in achieving this milestone. 📖 If you're passionate about clean energy and solid oxide fuel cell technology, check out the full article at https://lnkd.in/dhkxkY9T via @ioppublishing Your valuable feedback is always welcome! #FuelCellTechnology #CleanEnergy #ResearchPublication #ElectrolyteInnovation #SOFC #EnergySustainability Let's advance the frontiers of science and technology together! 💼🔍
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Scientists from Fraunhofer UMSICHT and Ruhr-Universität Bochum explored the potential of electrochemical #hydrogenation reactions as a sustainable and efficient alternative to traditional thermocatalytic methods. They cover the basic principles, practical applications and recent advancements in this field, focusing on translating these reactions from the lab to industrial settings. They discuss the challenges of scaling up electrochemical hydrogenations, including mass transfer limitations and reactor design, and offer strategies to address them. They also present future prospects and research directions for achieving widespread industrial implementation of electrochemical hydrogenation reactions. ➡ Click here for the "Chemical Society Reviews" publication: https://s.fhg.de/5PP. Julian T. Kleinhaus | Jonas Wolf | Kevinjeorjios Pellumbi | Leon Wickert | Sangita C. Viswanathan | Dr. Kai junge Puring | Daniel Siegmund | Ulf-Peter Apfel
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🔍 Welcome to the fourth episode of IBTR's popular science series, "Vanadium Flow Battery 23 Questions." Today, we delve into a fundamental query: What is the role of electrolyte in a vanadium flow battery? 🔋Vanadium flow batteries rely on electrolytes as their energy storage medium, emphasizing the critical role electrolyte stability plays in VFB performance and cycle life. To elevate VFB performance, enhancing electrolytes is crucial, with a focus on solubility and stability enhancements. 🔬 Current research endeavors to optimize electrolyte production processes, integrating additives and stabilizers to achieve heightened stability, concentration, wide temperature adaptability, and cost-effectiveness. 💡 Yet, electrolyte costs represent a significant portion of VFB expenses, igniting efforts to curb raw material consumption and promote electrolyte leasing business models. This pursuit involves lowering production costs by boosting electrolyte utilization. 💼 Innovative financial and commercial models, like electrolyte leasing, offer potential cost-effective solutions. By embracing electrolyte leasing, companies can slash initial investment costs, potentially halving expenses compared to traditional purchasing models. 🌐 Join us in unlocking the potential of vanadium flow batteries, shaping a sustainable energy future with efficient, cost-effective energy storage solutions. #VanadiumFlowBatteries #EnergyStorage #Electrolytes #Innovation #Sustainability #RenewableEnergy #IBTR #ScienceSeries #23Qs
【Vol.4】Vanadium Flow Battery 23 Questions--IBTR's popular science series
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🔬 New Publication! 📢 Glad to share our recent paper titled "System-level feasibility analysis of a novel chemical looping combustion integrated with electrochemical CO2 reduction" published in RSC's Sustainable Energy & Fuels. Given that the CO2 capture has been one of the challenges in developing a viable CCUS process, this research explores the integration of the upstream CLC for power generation with a downstream electrochemical reduction of CO2, and demonstrates the techno-economic feasibility of the proposed process via simulations based on the developed grey-box model for electrolysis. This work has been done in collaboration with the research group of Prof. Meenesh Singh at University of Illinois Chicago. A huge thank you to Prof. Meenesh Singh and Rohan Sartape for the detailed insights and experimental data on electroreduction of CO2 to ethylene. Special thanks to my PhD advisor Prof. Ravindra Gudi for his guidance and facilitating this collaboration, and my mentors Prof. Pratim Biswas and Prof. Suresh Bhargava for their support and critical suggestions. Check out the full paper here: https://lnkd.in/dpNzvetE #Research #SustainableEnergy #CO2Reduction #Electrochemistry #TechInnovation #CCUS #ChemicalEngineering #CarbonCapture #EnergyTransition
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🌟🔋 We would like to share a high impact publication in the field of #Lithium-ion #batteries co-authored by our very own Scientific Director, Montse Casas Cabanas, and colleague, Dimitrios Chatzogiannakis, in collaboration with INSTITUT DE CIÈNCIA DE MATERIALS DE BARCELONA (ICMAB-CSIC), Umicore and ALBA Synchrotron on "Understanding charge transfer dynamics in blended positive electrodes for Li-ion batteries." 📚🔬 This study, published in Energy Storage Materials, sheds light on the intricate mechanisms of charge transfer within blended positive electrodes, marking a significant advance in #battery technology. The insights gained could lead to the development of more efficient and durable Li-ion batteries, which are crucial for #sustainable energy solutions. 🌍💡 https://lnkd.in/dKiZYk7q
Understanding charge transfer dynamics in blended positive electrodes for Li-ion batteries
sciencedirect.com
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🔋 ⚡ Blended electrodes can be custom-designed for specific applications if synergistic effects are well understood. In our latest study, Dimitrios Chatzogiannakis (Destiny PhD Programme MSCA COFUND PhD) looks into charge transfer dynamics in blended electrodes. We show how current distribution between blend components is influenced by their individual voltage profiles and varies across SoC. And we also captured the "buffer effect" (charge exchange between components during relaxation) in operando XRD experiments conducted at ALBA Synchrotron! In collaboration with M.Rosa Palacin (INSTITUT DE CIÈNCIA DE MATERIALS DE BARCELONA (ICMAB-CSIC)) and Umicore.
🌟🔋 We would like to share a high impact publication in the field of #Lithium-ion #batteries co-authored by our very own Scientific Director, Montse Casas Cabanas, and colleague, Dimitrios Chatzogiannakis, in collaboration with INSTITUT DE CIÈNCIA DE MATERIALS DE BARCELONA (ICMAB-CSIC), Umicore and ALBA Synchrotron on "Understanding charge transfer dynamics in blended positive electrodes for Li-ion batteries." 📚🔬 This study, published in Energy Storage Materials, sheds light on the intricate mechanisms of charge transfer within blended positive electrodes, marking a significant advance in #battery technology. The insights gained could lead to the development of more efficient and durable Li-ion batteries, which are crucial for #sustainable energy solutions. 🌍💡 https://lnkd.in/dKiZYk7q
Understanding charge transfer dynamics in blended positive electrodes for Li-ion batteries
sciencedirect.com
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Researchers at Fraunhofer UMSICHT and Ruhr University Bochum have discovered that #carbon-based #bipolar #plates can be a more cost-efficient and scalable alternative to the #titanium #bipolarplates typically used in #PEM #electrolysis. The focus of their investigation was a new carbon-based bipolar plate developed and patented by Fraunhofer UMSICHT. It consists of a thermoplastic polymer-bonded carbon matrix with conductive additives such as carbon black and is produced using a powder-to-roll process. This material and production method enable continuous manufacturing of an easily processed and welded bipolar plate, already commercially used in redox flow batteries. The researchers subjected this carbon-based bipolar plate and a titanium bipolar plate to comprehensive ex-situ and in-situ tests. The ex-situ tests included electrochemical corrosion studies, scanning electron microscope analysis, and weight loss measurement to assess real-world suitability and parameter choices. During in-situ tests, the plates underwent accelerated ageing tests with alternating current densities between 1 and 3 A cm⁻² for over 500 hours. The scientists have published their results under the title ‘Bipolar Plates in PEM Water Electrolysis: Bust or Must?’ in the journal ‘Advanced Energy Materials’. In essence, they have discovered that the carbon-based bipolar plate has an ageing rate in the low µV h⁻¹ range and thus shows promising performance. This means that it can certainly compete with titanium bipolar plates and represents a much more cost-effective alternative. Another advantage: due to its material properties such as weldability, it enables completely new designs for PEM #electrolysers. The potential to replace titanium bipolar plates in the PEM electrolysis #stack and make electrolysis scalable at the same time is therefore definitely there. The task now is to further investigate and, if necessary, optimize the new material in order to further reduce the costs of electrolysis and thus make the production of #greenhydrogen more #economical.
Carbon-based bipolar plates more cost-efficient and scalable than titanium, researchers find
https://hydrogentechworld.com
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Recent studies show that BNNT properties can significantly improve water filtration, gas separation, sensing, and battery separator membranes, enhancing various aspects such as flux, rejection, anti-fouling, sensing, structural, thermal, electrical, and optical characteristics. This perspective article analyzes BNNTs' advanced properties, discussing their advantages in membrane science by reviewing current literature to provide insights and expedite research for environmental and energy applications🔬 https://lnkd.in/g8mRx3f4 Visit www.epicbnnt.com🔎 Call us at (410) 967-0557📞 Email us at [email protected]✉️ Follow us on: LinkedIn @Epic Advanced Materials Instagram @epicnanotech #nano #bnnts #imaginenano #boronnitridenanotubes #nanotubes #machinelearning #nanotechnology #deeplearning #materialdesign #nanomaterials #EPIC #EpicNano #EpicNanoTech #EpicBnnt #EpicAdvancedMaterials #nanotech #nanotechbnnt #science #pharmaceuticals #technology #materialscience #AI #innovation #sustainability #advancedmanufacturing #futurism #creativity #scienceandtechnology
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I am delighted to my participation in the RSC poster competition, where I am presenting a poster titled "Unraveling the Pseudocapacitive Traits of Two-Dimensional Titanium Carbide as an Electrode Material." This research delves into the unique electrochemical characteristics of two-dimensional titanium carbide, shedding light on its potential as an innovative electrode material. Through meticulous investigation, my work aims to contribute valuable insights to the field of energy storage and advance our understanding of materials with pseudocapacitive behavior. I share our findings with the scientific community and engage in discussions that could shape the future of energy storage technologies. #RSCposter2024 #RSCMat #RSCEnergy
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