i-battery’s Post

In this video, Dr. Billy Wu delves into the scientific principles, potential advantages, and challenges of solid-state batteries. He compares solid-state batteries with traditional lithium-ion batteries and introduces various types of solid electrolytes and battery architectures. Solid-state batteries offer higher energy density (over 400 Wh/kg) and improved safety, enabling faster charging speeds and new applications, such as electric flight. However, solid-state batteries face practical challenges, including manufacturing difficulties, material integration, and battery degradation. Despite these challenges, ongoing technological advancements hold promise for the future role of solid-state batteries in low-carbon energy storage. #EnergyStorage #BatteryTech #Innovation #FutureTech #SustainableEnergy

In this video, Dr. Billy Wu delves into the scientific principles, potential advantages, and challenges of solid-state batteries. He compares solid-state batteries with traditional lithium-ion batteries and introduces various types of solid electrolytes and battery architectures. Solid-state batteries offer higher energy density (over 400 Wh/kg) and improved safety, enabling faster charging speeds and new applications, such as electric flight. However, solid-state batteries face practical challenges, including manufacturing difficulties, material integration, and battery degradation. Despite these challenges, ongoing technological advancements hold promise for the future role of solid-state batteries in low-carbon energy storage. #EnergyStorage #BatteryTech #Innovation #FutureTech #SustainableEnergy

🔠 In our series “Battery ABC,” we’ll explore everything about batteries. Today we are moving to L – for LFP—Lithium Iron Phosphate. ❔Did you know LFP is particularly popular in China's big cities? ⭐ It is a rising star in battery cell chemistry. Watch the full video from our colleagues PowerCo to understand its role! Stay tuned for upcoming episodes.🎬 #BatteryABC #PowerCo #Emobility

In this video, Dr. Billy Wu delves into the scientific principles, potential advantages, and challenges of solid-state batteries. He compares solid-state batteries with traditional lithium-ion batteries and introduces various types of solid electrolytes and battery architectures. Solid-state batteries offer higher energy density (over 400 Wh/kg) and improved safety, enabling faster charging speeds and new applications, such as electric flight. However, solid-state batteries face practical challenges, including manufacturing difficulties, material integration, and battery degradation. Despite these challenges, ongoing technological advancements hold promise for the future role of solid-state batteries in low-carbon energy storage. #EnergyStorage #BatteryTech #Innovation #FutureTech #SustainableEnergy

Happy to share our Collaborative Work !!! We propose a current pulse-induced ultrafast strategy for developing MOF-derived graphitic nano-leaves (GNL) and supported ultrafine ruthenium nanoclusters exhibiting selective crystallization states depending on the tunable graphitization level of GNL. Density functional theory reveals that the unique electronic structure of amorphous-Ru and the cooperative effect of cobalt embedded in the graphitic layer lower the occupancy of the antibonding orbital, resulting in an accelerated HER process. https://lnkd.in/g4zrhj4i

🔋 Unveiling the Harmony of Nyquist Plots in Electrochemical Cells ⚡️🔄 Dive into the dynamic world of electrochemical cells where Nyquist plots play a pivotal role! 🌐✨ In the quest for efficient energy storage and conversion, Nyquist plots become our guiding stars. 🚀🔋 Visualizing impedance spectra, they empower us to optimize electrochemical processes and enhance cell performance. 📊🔧 Embrace the synergy of control systems and electrochemistry - shaping the future of sustainable energy! 💡🌍 #Electrochemistry #NyquistPlots #EnergyStorage #RenewableEnergy #ControlSystems #Innovation #LinkedInPost ⚡️🔗

#QTNano: The operation of a lithium-ion (Li-ion) battery is highly intricate and often challenging to articulate for those not well-versed in the field. Fortunately, this video, one of my preferred resources on the topic, presents a dynamic visual representation of the Li-ion battery's operational journey—from the charging phase to the discharge process. https://lnkd.in/dimvAVxH

Quite informative on the charge-discharge process of Li batteries and the role of graphene inside them https://lnkd.in/dQsa-npp

High-energy Li-ion batteries can provide both high capacity and high voltage, both of which are important in electric vehicles for greater range and faster acceleration. Using the ALS, researchers untangled the contributions of nickel and cobalt in high-energy Li-rich battery cathodes, pointing the way to optimizing them via a compositional approach. https://lnkd.in/g3CKkpie

Researchers develop 70kW-level high power density vanadium flow battery stack