NOVONIX’s Post

Switching from gas-powered cars to electric vehicles is one way to reduce carbon emissions, but building the lithium-ion batteries that power those EVs can be an energy-intensive and polluting process itself. Now researchers at Dalhousie University have developed a manufacturing process that is cheaper and greener. “Making lithium-ion cathode material takes a lot of energy and water, and produces waste. It has the biggest impact on the environment, especially the CO2 footprint of the battery,” says Dr. Mark Obrovac, a professor in Dalhousie's Departments of Chemistry and Physics & Atmospheric Science. “We wanted to see if there were more environmentally friendly and sustainable – and less expensive – ways to make these materials.” Most electric vehicle batteries use lithium nickel manganese cobalt oxide (NMC), with the elements mixed in the crystal structure of the cathode. They are typically made by dissolving the elements in water then using the crystals that form when the elements come together as a solid. That process takes a lot of water – which then has to be treated to clean it – and energy, which is the main source of the cost and carbon footprint of the batteries. Using the CLS, Obrovac and his team investigated whether they could use an all-dry process to get the same results while saving energy, water, and money. “We wanted to see, can you get the same quality if you take dry materials and combine them using simple processes that you’d find in any large-scale factory and heat them up,” he says. “And under what conditions can you do that to get commercial-grade material while cutting out the water and the waste?” Cathodes made from dry materials are sometimes not as homogeneous as those made in water, so the team tried a variety of methods using different oxides and heating regimes under different temperatures and pressures to determine what worked best. The highest quality cathodes available now are made from single crystals with particles about 5 microns in diameter. By carefully adjusting their starting materials and furnace conditions, Obrovac’s team was able to reproduce those qualities using an all-dry process, making cathode materials comparable to the best ones on the market today. Obrovac has partnered with the Nova Scotia-based battery company NOVONIX, which is using all-dry processes to produce cathode materials at the company’s pilot-scale facility in Dartmouth. That facility is capable of producing 10 tonnes per annum of cathode material, with methods that offer an estimated 30% lower capital costs than the conventional (wet) methods, 50% lower operating costs, and uses 25% less energy, while requiring no process water, and generating zero waste. “These are big numbers, it’s very much a step-change in the production of these battery materials,” says Obrovac. “It should result in lower-cost batteries overall with a substantially lower global warming footprint.” https://bit.ly/3VOr7RP #batteries #environment

🔋🚗 The Future of Affordable Electric Cars: A Game-Changer in Battery Technology 🌿🌍 Exciting advancements are on the horizon for electric vehicles (EVs) as researchers unveil a breakthrough that could significantly lower costs and enhance performance. The key? A cheap, widely available element: iron. In the quest for more affordable and sustainable EVs, iron-based batteries are emerging as a promising alternative to traditional lithium-ion batteries. Iron is abundant, cost-effective, and less environmentally damaging to extract compared to lithium and cobalt. This development could revolutionize the EV market, making electric cars more accessible to a broader audience and accelerating the transition to green transportation. The implications of this innovation are profound. By leveraging iron in battery technology, manufacturers can reduce production costs, leading to more affordable electric cars. This not only benefits consumers but also aligns with global sustainability goals by promoting cleaner energy solutions. Moreover, the adoption of iron-based batteries could alleviate some of the supply chain issues and geopolitical tensions associated with lithium and cobalt mining. As these materials are sourced from regions with complex political landscapes, a shift to iron can enhance energy security and reduce reliance on conflict-prone areas. The journey towards sustainable and cost-effective electric transportation is gaining momentum. With ongoing research and development, iron-based batteries hold the potential to drive significant advancements in the EV industry, fostering innovation, and economic growth while mitigating environmental impacts. Stay tuned as this transformative technology continues to evolve, promising a greener and more affordable future for electric mobility. Read more about this groundbreaking development here:https://lnkd.in/dWzsFHgV 🌿🔋🚗 #ElectricVehicles #SustainableTechnology #Innovation #GreenEnergy #AffordableEVs

As we can read in this interesting article from Oxford University, the popularization of the electric vehicle is closer. To better understand this statement, the battery of an electric vehicle has a series of two electrodes (called cathode and anode) distributed in cells containing a filler electrolyte. The electrolyte is basically a solution that soaks each of the electrodes and holds within it a high concentration of dissolved ions. When the battery is in the process of recharging, these dissolved ions move towards the anode and are stored inside until energy is requested. On the other hand, when the vehicle is started, the ions move towards the cathode in the opposite direction, generating an electric current through the external circuit that drives the motors that move the car forward. Lithium, because of its lightness and electropositive properties, is widely used, but sodium, with chemical properties similar to those of lithium but more abundant, appears on the scene. Sodium has the ability to move just as quickly through battery materials. But it benefits from being about 1,000 times more abundant on Earth than lithium. This opens up a great possibility for building cheaper batteries. The electric revolution and its popularization are closer. Thanks to Oxford for such an interesting article that has such a direct application to the automotive industry.

In the realm of electric vehicles, powered by stored electric energy, the key lies in rechargeable batteries capable of enduring multiple charge cycles.

🌍 Redefining electric mobility with cobalt-free batteries! 🚗 🔋The surge in demand for #electric #vehicles is driving #innovation, but it's also raising questions about the #environmental and #ethical #impact of #cobalt use in Li-ion #battery cathodes. 💡 Prof. Michael De Volder, Head of the IfM’s Nanomanufacturing Group, shares insights into groundbreaking efforts to eliminate cobalt from EV batteries, offering a glimpse into a more #sustainable era for electric mobility👇 https://lnkd.in/eKHEPGXe #electricvehicles #sustainability #innovation #cleanenergy #futureofmobility #nanomanufacturing #batteries Department of Engineering at the University of Cambridge University of Cambridge

In the realm of electric vehicles, powered by stored electric energy, the key lies in rechargeable batteries capable of enduring multiple charge cycles.

In the realm of electric vehicles, powered by stored electric energy, the key lies in rechargeable batteries capable of enduring multiple charge cycles.

Stanford's breakthrough in lithium metal battery technology promises to revolutionize electric vehicles, potentially doubling their range to 500-700 miles per charge. By implementing a simple resting protocol, battery life and performance are significantly enhanced, making electric vehicles more commercially viable. This advancement could alleviate range anxiety for drivers and accelerate the adoption of EVs. Additionally, the research sheds light on practical methods to adapt lithium metal technology to real-world driving conditions. #LithiumMetalBatteries #ElectricVehicles #BatteryTechnology

.. wait what? Batteries made of rocks? 🪨 Was that really what it said? To quote Mohamad Khoshkalam "Yes, you read right." 😉 He and his research team have patented a new material extracted from earth abundant rocks, that has the potential to replace lithium in batteries. Imagine the impact this could have on climate! 👀 Mohamed and the research project has been incubated with us at DTU Earthbound as a part of our venture building programme, Nurture, for early stage projects. We are rooting for you and your team Mohamad! DTU Energy DTU - Technical University of Denmark #deeptech #deeptechstartup #climateimpact #impact #greenenergy #greentransition #batteries #venturebuilding

It is worth reminding ourselves that we are just getting started with all the #EV advancements made over the past decade. The iterative process of innovate, deploy, analyze, innovate, deploy, analyze again is doing its thing. Part of what makes the #bipartisaninfrastructurelaw and #inflationreductionact valuable is the power of public investment to accelerate deployment and spur private-sector innovation. The innovation starts with research that is happening at universities and labs around the world. Take, for example, the research at Stanford University that has stumbled on a simple technique that could unlock a shift to longer-range, lower-weight battery compositions: "Next-generation electric vehicles could run on lithium metal batteries that go 500 to 700 miles on a single charge, twice the range of conventional lithium-ion batteries in EVs today. But lithium metal technology has serious drawbacks: The battery rapidly loses its capacity to store energy after relatively few cycles of charging and discharging – highly impractical for drivers who expect rechargeable electric cars to operate for years. Scientists have been testing a variety of new materials and techniques to improve the battery’s cycle life. Now, Stanford University researchers have discovered a low-cost solution: simply drain the battery and let it rest for several hours. This straightforward approach, described in a study published February 7 in the journal Nature, restored battery capacity and boosted overall performance." #electricvehicles #battery #innovation #research #cleanenergygeneration #climateaction