Oil is out, batteries are out.
We need smarter solutions that work with the environment, not exploit it.
Watch the video and tell me you didn’t say ‘… holy fuck.’
Oil is out, batteries are out.
We need smarter solutions that work with the environment, not exploit it.
Watch the video and tell me you didn’t say ‘… holy fuck.’
Batteries have a very important role in transitioning off fossil fuels.
They do not inherently lead to disaster, but to make the transition, lithium batteries in their current form are insufficient. Fortunately most people aren’t intending to do stationary energy storage for the electric grid with lithium. For that, sulfur-aluminum or lead-antimony (liquid metal) batteries are better, alongside pumped hydro, thermal storage, liquefied air, power-to-gas, etc, etc.
As the number of battery-powered vehicles grows, recycling of lithium becomes important, and sodium ion batteries (already manufactured, but not en masse) will be needed because sodium is much more abundant.
The electric grid will have to adapt. On some days, vehicles might not draw power from the grid, but return it - to balance out a power plant that dropped offline, or help during peak demand.
Traveling less will help and optimizing life to be convenient with less travel will help - but I think one can safely discard the possibility that everything can be altered. Unless economic shortage prevents them, people will travel, but the environmental impact of this can be very different depending on how they do it. :)
So - it’s a puzzle with many bottlenecks and many ways to circumvent them.
I’ve recently become interested in metal-air batteries, e.g. iron-air batteries, which use only a very plentiful metal (iron) and are thereby suitable for storing energy on a power grid (not much use in consumer electronics, of course - it’s not for that!). Also it’s conceptually hilarious to me that it’s basically rust-powered
It also feels like some of the transportation needs that were included in this video’s lithium battery calculations could be handled with capacitors instead of batteries. I believe we should be targeting capacitors for all of our public transportation infrastructure that travels set routs and routinely stops for 10-30s. Busses, light rail, etc can have quick charging stations along the route and you can not only drastically reduce the electric storage (and therefore remove lithium entirely), you can reduce the weight of these vehicles.
Yep, forgot about iron, and about flow batteries.
The nice thing about flow batteries is that storage capacity and reactive cell size can be scaled independently. :)