Fluidnatek & Spinbox by Bioinicia’s Post

https://lnkd.in/gefP79ac Lithium-sulfur batteries are inevitable. This conference is very timely for battery industry professionals to understand exactly how and why these high theoretical energy density cells are showing significant promise as a next-generation energy storage system. #Sustainability #EVBatteries #Lyten #LithiumSulfur This conference track will showcase the latest R&D advances and discuss the key challenges facing the commercialization of lithium-sulfur batteries. The international faculty of experts will present the most recent results, new materials, processes and applications in the field. Don’t miss your opportunity to get the latest developments from the major global players developing lithium-sulfur technologies. For maximum savings, register by July 19. 

Stationary Energy Storage: Innovations in Li-ion Battery Technologies: Li-ion batteries remain the dominant electrochemical energy storage technology in the global market. Other battery storage technologies, such as redox flow batteries, Na-ion batteries, and metal-air batteries, have continued to remain as emerging technologies with a limited volume of deployments in the last few years. http://dlvr.it/TDZPXS

🔬🌟 Last week, we unveiled our exciting plan to spotlight the cutting-edge equipment of the MG2lab every week! This week, we present the 6 Nm3/h PEM electrolyzer that is able to operate between 30% and 100% of its nominal load! 🧪⚡️ While we've conducted steady-state tests so far, future experiments will focus on the system capacity respond to load variation, which is crucial for coupling it with PV systems so it can be used for green hydrogen production. Our ultimate goal? Optimal operation of the electrolyzer within the microgrid, transforming it into an additional storage system capable of medium-term period, that can provide hydrogen both for electricity production inside of fuel cells, and its use instead of natural gas. 🌐🔋💡 We're passionate about sharing insights into our lab's capabilities and the tools that drive our success. Join us on this journey of exploration and discovery! 🌐🔍✨ #EnergyInnovation #MicroGrids #RenewableEnergy #LabEquipment #ScienceAndTechnology #Electrolyzer #ResearchAndDevelopment #StayTuned #MG2lab

Sodium Today-Technology July 29. 2021, CATL,the world's third largest battery provider,unveiled the company’s first-generation sodium-ion battery with the energy density up to 160Wh/kg, and the next generation of sodium-ion batteries’ energy density development target is to exceed 200Wh/kg.   sodium-ion batteries has the advantages of high-energy density, fast-charging capability, excellent thermal stability, great low-temperature performance and high-integration efficiency, among others.Sodium-ion batteries can be used in various transportation electrification scenarios, especially in regions with extremely low temperatures, where its outstanding advantages become obvious. Also, it can be flexibly adapted to the application needs of all scenarios in the energy storage field. #new energy # sodium ion battery #CATL #Technology #inovation

Solid Oxide Electrolysis is not anymore something for the future but for the present and luckily we are having more and more proofs of this. Let me show you. 😊 A few months ago, we had a very nice report by Gniewomir Flis and Ghassan Wakim showing us the actual state of the SOEC industry. We could see how they are not so far as many people believe. https://lnkd.in/gYPJCnVs This report shows that some companies like Bloom Energy, Topsoe, Elcogen, FuelCell Energy or Ceres are already getting ready for the challenge of delivering MW-scale systems with GW factories and so on. The main challenge of Solid Oxide Electrolysis is to have a good module in the hundreds of kWs to scale-up and use it as a repetitive unit to build larger systems. Now, Topsoe has reached a new milestone in their developments and show us a successful test of their so-called "350 kW core SOEC" with lots of data to everyone to analyse. https://lnkd.in/g3cy9gkC In the picture below, you can see how it is possible to run efficiently a SOEC system while taking advantage of their properties to operate at nearly 100 % efficient, i.e. operating slightly below to the thermoneutral point of the steam reaction (1.29 V) as my images has showed you before. A big congratulation to all the team at Topose and to all the great Solid Oxide scientists believing in this technology during the last decades when very people did it, establishing the grounds for the Solid Oxide industry to flourish now. Finally, I encourage to all the water electrolysis industry to embrace "Science-based behaviors" and show good data, even if it is few thousand hours of test, to continue overcoming the fears and skepticism of investors around these technologies. Let's show them that we are ready for the challenge as solar, wind and batteries were few years ago. #greenhydrogen #solidoxide #test #gooddata

🔋 Exploring the innovation of Reversible Fuel Cells (RFCs) - a pioneering technology bridging fuel cell and electrolyzer modes for efficient energy storage and generation. 🔍 *Fuel Cell Mode:* - Anode reaction: 2H2 → 4H 4e- - Cathode reaction: O2 4H 4e- → 2H2O - Overall reaction: 2H2 O2 → 2H2O electricity heat 🔄 *Electrolyzer Mode:* - Anode reaction: 2H2O → O2 4H 4e- - Cathode reaction: 4H 4e- → 2H2 - Overall reaction: 2H2O electricity → 2H2 O2 🔧 *Technical Details:* - Electrolyte: Proton exchange membranes (PEMs) or solid oxide electrolytes - Electrode materials: Platinum, iridium, and nickel-based catalysts - Efficiency: 40-60% round-trip efficiency 💡 *Applications:* - Energy storage - Backup power systems - Space missions 📚 Dive deeper into the operation, materials, efficiency, and applications of RFCs with references by Wang et al. (2011), Liso et al. (2018), and Ebbesen et al. (2014) in Applied Energy, Renewable and Sustainable Energy Reviews, and International Journal of Hydrogen Energy respectively. #EnergyStorage #FuelCells #RenewableEnergy #Innovation

We are pleased to invite you to read selected papers on the topic of Supercapacitors Selected Papers from 2022–2023 on the Topic of Supercapacitors https://brnw.ch/21wK4WB Part of them are: 1. “An Experimental Study of Power Smoothing Methods to Reduce Renewable Sources Fluctuations Using Supercapacitors and Lithium-Ion Batteries” 2. “Use of Water-In-Salt Concentrated Liquid Electrolytes in Electrochemical Energy Storage: State of the Art and Perspectives” 3. “From Triboelectric Nanogenerator to Uninterrupted Power Supply System: 4. “Carbon-Based Materials for Supercapacitors: Recent Progress, Challenges and Barriers”

In the literature on zinc-based batteries, it is often highlighted that zinc offers significant advantages over lithium due to its abundance, affordability, and accessibility. Additionally, aqueous rechargeable zinc batteries are promoted as a sustainable and cost-effective alternative to lithium-ion batteries, especially for renewable energy storage. The aim of this Comment on #Nature Communications, developed in a collaborative effort of #HIU, #Sapienza and #UULM, is to provide a perspective on these statements, elucidating their foundations and implications and giving a quick but comprehensive background to authors and readers that deal with this topic, focusing specifically on batteries with zinc ions shuttling reversibly between the metallic negative electrode and the insertion-type positive electrode. https://rdcu.be/dHT6U

https://lnkd.in/gm4xHGMx Intercalation pseudocapacitance is a relatively new electrochemical mechanism that enhances both the energy-density and power-density of a pseudocapacitor with high rate-capability to bridge the gap between supercapacitors and batteries and pave the way for next-generation energy storage systems.

Sodium-Ion Batteries: A Leap Forward in Energy Storage with Layered Oxide Cathodes In the realm of energy storage, sodium-ion batteries with layered oxide cathodes are emerging as a formidable contender, especially for applications demanding high power output and rate capability. At their core, these batteries benefit from a structure that facilitates the smooth migration of sodium ions, a critical aspect during charge and discharge cycles. Key Highlights: Layered Structure Advantage: The cathodic materials' layered composition optimizes the movement of sodium ions, ensuring efficient ion diffusion and contributing to the battery's high power output and excellent rate performance. Material Composition: These cathodes are typically made from layered transition metal oxides, providing a stable and conductive platform for the insertion and extraction of sodium ions, crucial for long-term battery stability and efficiency. Feasibility and Sustainability: Advancements in layered oxide cathodes are not just enhancing the performance of sodium-ion batteries but are also a stride toward sustainable energy storage solutions. Given the relative abundance and lower cost of sodium compared to lithium, these developments mark a significant step in reducing reliance on rarer resources. Diversifying Energy Storage Options: The evolution of sodium-ion battery technology, particularly with layered oxide cathodes, is adding a vital dimension to our energy storage choices, catering to a range of applications from large-scale energy storage to electric vehicles. As we continue to innovate in battery technology, sodium-ion batteries with layered oxide cathodes represent a pivotal development, promising to reshape the landscape of energy storage with their unique blend of efficiency, sustainability, and economic viability. #EnergyStorage #BatteryTechnology #SodiumIonBatteries #SustainableEnergy #Innovation