Green energy is in its heyday. 

Renewable energy sources now account for 22% of the nation’s electricity, and solar has skyrocketed eight times over in the last decade. This spring in California, wind, water, and solar power energy sources exceeded expectations, accounting for an average of 61.5 percent of the state's electricity demand across 52 days. 

But green energy has a lithium problem. Lithium batteries control more than 90% of the global grid battery storage market. 

That’s not just cell phones, laptops, electric toothbrushes, and tools. Scooters, e-bikes, hybrids, and electric vehicles all rely on rechargeable lithium batteries to get going. 

Fortunately, this past week, Natron Energy launched its first-ever commercial-scale production of sodium-ion batteries in the U.S. 

“Sodium-ion batteries offer a unique alternative to lithium-ion, with higher power, faster recharge, longer lifecycle and a completely safe and stable chemistry,” said Colin Wessells — Natron Founder and Co-CEO — at the kick-off event in Michigan. 

The new sodium-ion batteries charge and discharge at rates 10 times faster than lithium-ion, with an estimated lifespan of 50,000 cycles.

Wessells said that using sodium as a primary mineral alternative eliminates industry-wide issues of worker negligence, geopolitical disruption, and the “questionable environmental impacts” inextricably linked to lithium mining. 

“The electrification of our economy is dependent on the development and production of new, innovative energy storage solutions,” Wessells said. 

Why are sodium batteries a better alternative to lithium?

The birth and death cycle of lithium is shadowed in environmental destruction. The process of extracting lithium pollutes the water, air, and soil, and when it’s eventually discarded, the flammable batteries are prone to bursting into flames and burning out in landfills. 

There’s also a human cost. Lithium-ion materials like cobalt and nickel are not only harder to source and procure, but their supply chains are also overwhelmingly attributed to hazardous working conditions and child labor law violations. 

Sodium, on the other hand, is estimated to be 1,000 times more abundant in the earth’s crust than lithium. 

“Unlike lithium, sodium can be produced from an abundant material: salt,” engineer Casey Crownhart wrote ​​in the MIT Technology Review. “Because the raw ingredients are cheap and widely available, there’s potential for sodium-ion batteries to be significantly less expensive than their lithium-ion counterparts if more companies start making more of them.”

What will these batteries be used for?

Right now, Natron has its focus set on AI models and data storage centers, which consume hefty amounts of energy. In 2023, the MIT Technology Review reported that one AI model can emit more than 626,00 pounds of carbon dioxide equivalent. 

“We expect our battery solutions will be used to power the explosive growth in data centers used for Artificial Intelligence,” said Wendell Brooks, co-CEO of Natron. 

“With the start of commercial-scale production here in Michigan, we are well-positioned to capitalize on the growing demand for efficient, safe, and reliable battery energy storage.”

The fast-charging energy alternative also has limitless potential on a consumer level, and Natron is eying telecommunications and EV fast-charging once it begins servicing AI data storage centers in June. 

On a larger scale, sodium-ion batteries could radically change the manufacturing and production sectors — from housing energy to lower electricity costs in warehouses, to charging backup stations and powering electric vehicles, trucks, forklifts, and so on. 

“I founded Natron because we saw climate change as the defining problem of our time,” Wessells said. “We believe batteries have a role to play.”

-via GoodGoodGood, May 3, 2024

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Note: I wanted to make sure this was legit (scientifically and in general), and I'm happy to report that it really is! x, x, x, x

The world is rapidly transitioning to renewable power, but there are shortcomings. Solar power falls at night, and wind power recedes and ascends irregularly. New technologies need to be developed that can store energy from the electrical grid when there's a surplus and deploy it when there's not enough. Rechargeable lithium-ion batteries play a crucial role in everyday life, powering devices from smartphones to electric vehicles. However, they rely on limited resources like lithium, nickel, and cobalt, raising concerns about sustainability and cost. Xiaowei Teng, the James H. Manning Professor in Chemical Engineering at WPI, is leading a team to explore new battery technologies for grid energy storage. The team's recent results, published in the European scientific journal ChemSusChem, suggest that iron, when treated with the electrolyte additive silicate, could create a high-performance alkaline battery anode. The second most abundant metal in the Earth's crust after aluminum, iron is far more sustainable than nickel and cobalt. The United States alone recycles approximately over 40 million metric tons of iron and steel from scrap each year.

Read more.

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Harveypower Lifepo4 Battery Charge and Discharge Test

Welcome to our latest video showcasing the charge and discharge test of Harveypower's LiFePO4 battery.

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How much is 400 MWh of energy storage? One way of thinking about it is that it’s enough electricity for 300 homes … for an entire year. Of course, that’s not how it works, but that helps to conceptualize how much electricity is stored in this giant battery(..)

More details here:

And the paper in Nature here:

While the market for solar and wind energy sources is growing, transitioning to renewables at home isn’t easy. What happens when the sun goes in or when there’s no wind?

Solar panels and other kinds of green energy are usually backed up by other sources. These are needed to safeguard our power when the weather isn’t cutting it. We all want to be able to shower - even when it’s cloudy.

Usually, lithium-ion batteries provide this backup but these are pricey, meaning that most people can’t afford to switch entirely to renewables.

Scientists from MIT have created a new kind of battery that could provide a solution for storing energy at home. 

continue reading

Battery Thermal Management: The Crucial Role of Temperature Control

In modern electric vehicles (EVs), the lithium-ion battery module pack takes center stage, influencing an EV's performance, range, and safety. However, these crucial power sources are sensitive to temperature extremes. Like people, batteries have their comfort zone, typically operating optimally between 15°C and 40°C. Yet, the reality of automotive environments exposes batteries to temperatures ranging from a frigid -20°C to a sweltering 55°C. What's the solution? Give the battery an air conditioner, and you get battery thermal management, which accomplishes three essential functions: heat dissipation, heating, and temperature consistency.

Heat Dissipation

When temperatures soar, batteries can experience a dramatic loss of life (resulting in capacity degradation) and an elevated risk of thermal runaway. Thus, effective heat dissipation is vital when the battery becomes excessively hot.

Heating

Conversely, when temperatures plummet, the battery's capacity may be reduced and performance weakened. Charging the battery in this frigid state can even pose a risk of thermal runaway due to potential internal short circuits. So, it's crucial to warm up or insulate the battery when it gets too cold.

Temperature Consistency

Think back to the old air conditioner in your childhood home. It would blast cold air upon startup and then take a break. Most modern air conditioners now use frequency conversion and even airflow distribution to maintain temperature consistency. Similarly, power batteries strive to minimize spatial temperature differences, ensuring minimal variance in cell temperature. Temperature consistency is paramount to battery performance and safety.

Effects of Low Temperatures on EVs and Batteries

As the heart of an EV, the power battery has a profound impact on its performance, affecting aspects such as range, acceleration, and service life. Safety is also a top priority. Battery performance is deeply intertwined with temperature, and cold climates can significantly hinder an EV's operation.

For instance, electric vehicle owners in colder regions often notice a significant drop in mileage during winter. In some cases, the range can plummet to as low as 70% of its usual capacity. Many drivers resist using cabin heaters to conserve mileage.

Low temperatures not only reduce an EV's battery capacity but also inhibit its discharge capabilities. At extremely low temperatures, the electrolyte inside the battery may freeze, leading to a severe reduction in power output.

Lithium-ion batteries are particularly susceptible to temperature extremes. At lower temperatures, the chemical reactions within the battery slow down, resulting in decreased performance and range. Charging in freezing conditions can also lead to the formation of lithium deposits on the battery's negative electrode, potentially puncturing the battery diaphragm and causing a short circuit. The safety implications of charging batteries at low temperatures are significant.

Battery Thermal Management: A Technological Solution

Battery thermal management is the solution to many of these challenges. This technology aims to maintain battery temperature within the ideal range. The approach includes both heating and cooling, to optimize battery performance.

There are several methods used in battery heating:

Battery Natural Heating: The heat generated during battery operation, discharging, or charging can increase the battery's temperature. However, this method can be slow and is rarely used in modern electric vehicles.

Blower Heating: Blowing hot or cold air into the battery pack through an external air conditioner is another method. This approach demands a carefully designed air duct and can result in uneven temperature distribution within the battery pack.

Heating Elements in the Battery Pack: These are composed of heating elements and circuits. Two common heating elements are the Positive Temperature Coefficient (PTC) and Heating Film. PTC offers advantages like safety, high thermal conversion efficiency, and rapid heating.

Circulating Liquid Heating: Liquid-cooled battery packs have become the mainstream option. This method offers uniform heat distribution, safety, and reliability. It usually features a system to facilitate heat dissipation, ensuring even temperature rises throughout the battery pack.

Conclusion

Battery thermal management is not just a luxury; it's a necessity for modern electric vehicles. In a world of varying climates, maintaining optimal battery temperature is a key factor in enhancing performance, ensuring safety, and prolonging battery life. As technology continues to evolve, battery thermal management will continue to play a crucial role in advancing the electric vehicle industry, offering the promise of efficient and reliable clean energy transportation for the future.

General Motors Secures $625M Investment in Lithium Mining Joint Venture

General Motors (GM) is committing $625 million to expand its lithium production capacity through a joint venture with Lithium Americas Corp., aiming to secure domestic lithium supplies critical to electric vehicle (EV) battery production. https://twitter.com/KitcoNewsNOW/status/1851683383035990094 The investment focuses on the Thacker Pass project in Nevada, which holds North America’s largest…

Lithium-ion Batteries: Market Dynamics and the Road Ahead for Energy Storage

According to a new report published by Allied Market Research, The lithium-ion battery market size was valued at $46.2 billion in 2022, and lithium-ion battery industry is estimated to reach $189.4 billion by 2032, growing at a CAGR of 15.2% from 2023 to 2032.

A lithium-ion (Li-ion) battery is a type of rechargeable battery that uses lithium ions to store and release electrical energy. Li-ion batteries have become the dominant technology for portable electronics, electric vehicles (EVs), and many other applications due to their high energy density, relatively low self-discharge rates, and ability to be recharged multiple times. They are used in a wide range of devices, from smartphones and laptops to power grids and renewable energy storage systems.

Asia-Pacific is the major consumer of lithium-ion batteries among other regions. It accounted for more than two-fifths of the global market share in 2022.

The major companies profiled in this report include BYD Co., Ltd., A123 Systems, LLC, Hitachi, Ltd., CATL, LG Chem, Panasonic Corp., Saft, Samsung SDI Co., Ltd., Toshiba Corp., and GS Yuasa corporation.

Li-ion battery technology continues to evolve, with ongoing research focused on increasing energy density, cycle life, safety, and sustainability. The adoption of Li-ion batteries has had a profound impact on the way we use and store energy in modern society.

Lithium-ion batteries are rechargeable power storage devices that consist of a couple of components, together with cathodes, anodes, electrolytes, separators, and different materials.

The international focus on creating sustainable energy resources via renewable energy technology has led to increase in investments through governments and private institutions. This surge in demand for energy storage devices has pushed the growth of the lithium-ion battery market.

The rise in border disputes and terrorist activities worldwide has spurred the development of unmanned weapons and smart missiles, which closely rely on excessive electricity density batteries as power sources.

Lithium-ion batteries showcase a theoretical electricity density of about 2,600 Wh/kg, making them incredibly promising for high-energy-density battery applications. One excellent subject where they find use is in large-scale car vehicles, enabling efficient electric transportation.

Speedy innovation and utility of smart weapons, unmanned drones, and automobiles in the military enterprise contribute to the growth in demand for lithium-ion batteries. Lithium-ion batteries are a kind of rechargeable battery recognised for their excessive precise energy. The use of light-weight lithium and other substances in their development makes lithium-ion batteries rather light.

The application of lithium-ion batteries in a variety of industries has proven exceptional promise, such as in the aerospace sector, where Airbus Defense and Space has efficaciously examined High Altitude Pseudo-Satellite Aircraft (HAPAS) prototypes powered by using photo voltaic power all through the day and lithium-ion batteries at some stage in the night.

As per lithium-ion battery market analysis, on the basis of component, the cathode segment emerged as the global leader by acquiring nearly half of the lithium-ion battery market share in 2022 and is anticipated to continue this trend during the forecast period.

On the basis of capacity, the 3,000- 10,000 mAh segment emerged as the largest market share in 2022, which accounts for more than two-fifths of the lithium-ion battery market share.

On the basis of application, the automotive segment emerged as the largest market share in 2022 which accounts for more than half of the lithium-ion battery market share, and is anticipated to continue this trend during the forecast period.

About Us

Allied Market Research (AMR) is a full-service market research and business-consulting wing of Allied Analytics LLP based in Portland, Oregon. Allied Market Research provides global enterprises as well as medium and small businesses with unmatched quality of "Market Research Reports" and "Business Intelligence Solutions." AMR has a targeted view to provide business insights and consulting to assist its clients to make strategic business decisions and achieve sustainable growth in their respective market domain.

Pawan Kumar, the CEO of Allied Market Research, is leading the organization toward providing high-quality data and insights. We are in professional corporate relations with various companies and this helps us in digging out market data that helps us generate accurate research data tables and confirms utmost accuracy in our market forecasting. Each and every data presented in the reports published by us is extracted through primary interviews with top officials from leading companies of domain concerned. Our secondary data procurement methodology includes deep online and offline research and discussion with knowledgeable professionals and analysts in the industry.

The demand for efficient energy storage systems is ever increasing, especially due to the recent emergence of intermittent renewable energy and the adoption of electric vehicles. In this regard, lithium-sulfur batteries (LSBs), which can store three to five times more energy than traditional lithium-ion batteries, have emerged as a promising solution. LSBs use lithium as the anode and sulfur as the cathode, but this combination poses challenges. One significant issue is the "shuttle effect," in which intermediate lithium polysulfide (LiPS) species formed during cycling migrate between the anode and cathode, resulting in capacity fading, low life cycle, and poor rate performance. Other problems include the expansion of the sulfur cathode during lithium-ion absorption and the formation of insulating lithium-sulfur species and lithium dendrites during battery operation. While various strategies, such as cathode composites, electrolyte additives, and solid-state electrolytes, have been employed to address these challenges, they involve trade-offs and considerations that limit further development of LSBs.

Read more.

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Exploring the graphene aluminum battery. Don’t miss out on the EcoFlow sale. Get an extra 8% off with the code: FERRELLBF8! Amazon link: https://amzn.to/3T3f5iP Ecoflow website: https://us.ecoflow.com/?aff=195. While there are already an assortment of energy storage options available today beyond lithium batteries for grid scale storage, like compressed air and pumped hydro, there’s still a search for the next big thing. One rising star is aluminum batteries, which don’t require rare-earth materials, can charge faster, and could be cheaper and easier to recycle. There are two exciting battery breakthroughs we have to examine … and some of the benefits of these are kind of astounding. How do they work and can they really compete with lithium ion batteries? Let’s take a closer look.

Watch Exploring Solar Panel Efficiency Breakthroughs in 2022 https://youtu.be/m8crjuL8FFs?list=PLn...

The Battery Recycling video I mentioned: https://youtu.be/6w78-aSTIDY

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