Sodium-ion batteries have started to appear in cars and home storage

They also don't need some "critical" minerals such as graphite, cobalt and nickel.

It seems that $15 per kWh of storage should be achievable with them. At this price, it's trivial to install enough grid-scale storage to completely move off fossil fuels in more southern areas.

To wit, in his review he-

-dismisses environmental concerns with Li

-dismisses safety concerns with Li

-dismissed geopolitical concerns with Li availability. Something something "environmentalists!" (shakes fist at clouds) like with the environmental concerns.

-dismisses economic advances of Na

And then the overwhelming focus of his review is that if you deep freeze the battery, it charges slowly. This becomes the foundation of his criticism. Only firstly it's a self solving issue -- the battery warms as it charges -- but in most situations the battery will be in a heated (or will be self-heating) scenario and at an ideal temperature.

I'm no Na booster, and it seems like an incremental improvement in various dimensions for certain scenarios, but that video adds extraordinarily little value to the space.

Phones and laptops are weight/volume sensitive, and sodium ions are a lot larger than lithium ions, thus the battery energy density is lower.

Sodium batteries, if the technology works, would replace EV batteries and provide support to the electrical grid, and would be purchased at thousands of times the volume of iphone ad laptop batteries

But more on that point, it always struck me as bizarre that lithium was dominant in so many areas despite vastly different requirements. For home and grid storage, battery weight is almost immaterial, while it's a paramount concern in portable devices. I think it would be very surprising indeed if one chemistry performed best in all scenarios. Lithium became dominant primarily because it had so much research and supply chain maturity behind it, even if it was suboptimal for areas like grid storage. Glad to see other battery chemistries are getting more investment.

For instance startup Channing Street Copper's battery powered induction stove. Their battery is large enough to also power your refrigerator for 3 days (IIRC).

In effect, a combination Powerwall and stove. Without requiring a panel upgrade. Apartment dwellers can cost effectively electrify All The Things. It greatly improves resiliency. Unlocks distributed grid power generation and storage (IIRC something like "VPP" for "virtual power plant").

"Induction stoves with batteries built in, and why they matter" [2022]

https://www.volts.wtf/p/induction-stoves-with-batteries-buil...

CATL is launching volume production of their second generation sodium ion battery in December 2025. That's in about 2 months. I'm sure they'll use most of next year to ramp up production but they are targeting multiple gwh of production capacity with this first factory. More will likely follow. Apparently converting existing LFP production to this is relatively easy. This is not some experimental thing but a completely validated and ready for mass production chemistry.

Some basic stats of their cell: 175 wh/kg, ~10K charge cycles, -40 to +70 degrees celsius operating range, 5C charge rate (very fast basically). That's basically very competitive with LFP for both storage and low end EVs (up to 500km/300miles is a number they've cited).

That is all straight from CATL's recent press release on this. They are either playing some really amazing poker game here or they really are about to massively change things in the market.

That temperature range means these batteries can operate pretty much anywhere on this planet.

Peak Energy is actually starting to produce low volume production for their unique chemistry for grid storage. Their pitch is basically that they can deploy these in the desert with passive cooling only. No fans or moving parts. No cooling liquids. Nothing. Apparently this should work fine in a desert where it's freezing cold at night and blisteringly hot during the day. No fire risk. No mechanical parts that can break. Basically plonk them down and forget about them. Of course highly uncertain if they can scale all the way but it sounds promising.

There are other companies with production plans (or actual production happening) on this front as well.

Sodium ion has definitely left the labs now and it's now a matter of time before either these batteries are mass produced and widely used or something even better comes along to displace this. My guess is sodium ion will eat significantly into LFP market share for both storage and automotive in the next five years or so. After that, I would be very disappointed if nothing better comes along. Five years is about the same time it took for LFP to make a big dent into NMC market share. It might be some time before these things start showing up in the US though because of the tariff situation and the lack of local production capacity for this new chemistry. But if it is successful elsewhere, it will eventually happen there as well.

The biggest feature of this chemistry is actually the low cost of the materials. There are no exotic metals that you need. Everything needed can be sourced cheaply and locally in abbundance in pretty much every country. There have been some persistent rumors that CATL is targeting a long term cost of this chemistry of around 10$/kwh starting at maybe between 30 and 50$. 10$ is almost 10x lower than what is common today. Most EVs only have about 500-700$ worth of battery at those prices. As opposed to 5-7K right now. And many manufacturers don't produce their own cells so they would be paying more.

The cost is basically why people are a bit bullish on this technology. The low cost is a really big deal. It changes everything.

If you put LFP batteries packed into a cargo container next to a solar farm in California or Nevada, a significant portion of that container will be piping (to every cell) and compressors for a beefy AC system. LFP cells don't like to work hot.

This cooling system will take up a significant portion of space, power, and worst of all, of the total maintenance cost of the entire battery system.

An identical system made of Na batteries will take 2 containers, but need no cooling power and basically no maintenance - no moving parts, unlike the compressors and fans of the LFP pack.

It's not insurmountable for 'the West' to claw back some of that manufacturing, including high-tech items like batteries. It will take a large, long-time and very expensive effort, however. But talk is cheap, and largely 'the West' has drunken the neoliberalism kool-aid and is staring at quarterly shareholder value so little gets done.

Heck, some Western government are even in bed with the fossil fuel industry, desperately trying to hold back progress in order to claw a bit more profit out of the industry before the full force of the electric revolution hits.

I have heard that the USA has abandoned that strategy recently, but I think it is too early to see any impact.

All the research is in finding ever better combinations of anode/cathode.

Lithium mining and processing is dominated by Western countries, which is why China is incentivised to develop and manufacture sodium ion batteries. They know the game and haven't ignored it, unlike the West who ignored the geopolitical risk of China dominating rare earth processing for 20+ years.

The West should have a similar incentive despite having most of the lithium, namely supply risks for graphite, cobalt and nickel. There is a lot of research going on but mostly in Europe.

So American companies would develop sodium instead and break this market wide open.

But the Chinese appear to have beat them to it.

At some point when Americans were still denying climate change the CCP looked at the massive environmental destruction around them and decided to do something about it.

For heavy users and given a standard range of 250+ miles, we are talking about a longevity of 1 000 000 miles. I never had a car with more than 200.000km (120 000 miles).

The allure is cheaper input materials, potentially very long lifespans and creating a hedge against the boom and bust cycle of the lithium market.

But this is currently small batches backyard production, so I expect the prices to go down. Also, the materials are available practically everywhere, so even 3rd world countries should be able to make them.

I could see quite a rapid takeoff if they prove successful next year after being mass produced because they look like maybe the best solution for grid storage.

I think a lot of households will choose Sodium just because of how cheap it will be but not until there is the basic inverter equipment to make use of it from the usual manufacturers.

Sounds price competitive already?

  O($/Wh) D(Wh/kg) D(Wh/L) P($)  E(Wh) M(kg) Vol(L) V(V) C    S     URL(Lithium-ion)
  0.31    236.17   671.08  3.4   11.1  0.047 0.017  3.7  1000 18650 https://www.alibaba.com/product-detail/Wholesale-18650-Lithium-Battery-INR18650-3_1601503766893.html
  0.36    222.00   671.08  3.99  11.1  0.05  0.017  3.7  800  18650 https://www.alibaba.com/product-detail/Hot-Selling-Factory-Price-INR18650-30Q_1601159662361.html
  0.83    160.00   290.20  4     4.8   0.03  0.017  3.2  2000 18650 https://www.batteryspace.com/LiFePO4-18650-Rechargeable-Cell-3.2V-1500-mAh-4.8Wh-7.5A-Rate.aspx
  0.36    227.85   1088.24 6.4   18    0.079 0.017  3.2  3000 18650 https://www.goldencellpower.com/product-item/18650-1100mah-3-2v-lifepo4-cells/
  0.36    222.78   1064.06 6.4   17.6  0.079 0.017  3.2  3000 18650 https://www.batteryspace.com/LiFePO4-18650-Rechargeable-Cell-3.2V-2000-mAh-6.4Wh-6A-Rate.aspx
  0.80    134.74   365.71  10.18 12.8  0.095 0.035  3.2  4000 26650 https://www.batteryspace.com/LiFePO4-26650-Rechargeable-Cell-3.2V-4000-mAh-12.8Wh-12A-Rate.aspx
  0.24    184.00   396.07  3.5   14.72 0.08  0.037  3.2  3000 26700 https://www.alibaba.com/product-detail/lithium-ion-battery-cell-26700-3_1601277009356.html
  0.31    240.00   413.29  4.8   15.36 0.064 0.037  3.2  4000 26700 https://www.sunpowernewenergy.com/product/26700-high-rate-lifepo4-battery-45e/
  0.31    160.00   128.28  4.8   15.36 0.096 0.120  3.2  4000 33140 https://www.alibaba.com/product-detail/High-Quality-LMFP-5AH-Cell-Lithium_1601161018743.html
  0.28    256.41   167.03  5.6   20    0.078 0.120  3.2  5000 33140 https://www.evlithium.com/LiFePO4-Battery/33140-20ah-lifepo4-battery-cell.html

  Edit: dangit, I made a mistake in my previous post. A($/Wh) and C($/Wh) were supposed to be O($/Wh) for outlay. I fixed this one to provide context.