There have been constant news articles coming out over the past few years claiming the next big thing in supercapacitor and battery technologies. Very few actually turn out to work practically.
The most exciting things to happen in the last few years (from an average citizen’s perspective) are the wider availability of sodium ion batteries (I believe some power tools ship with them now?), the continued testing of liquid flow batteries (endless trials starting with the claim that they might be more economic) and the reduction in costs of lithium-ion solid state batteries (probably due to the economics of electric car demand).
FWIW the distinction between capacitors and batteries gets blurred in the supercapacitor realm. Many of the items sold or researched are blends of chemical (“battery”) and electrostatic (“capacitor”) energy storage. The headline of this particular pushes the misconception that these concepts can’t mix.
My university login no longer works so I can’t get a copy of the paper itself :( But from the abstract it looks first stage, far from getting excited about:
This precise control over relaxation time holds promise for a wide array of applications and has the potential to accelerate the development of highly efficient energy storage systems.
“holds promise” and “has the potential” are not miscible with “May Be the Beginning of the End for Batteries”.
I’ve been seeing a lot about Sodium-ion just in the past week.
While they seem to have a huge advantage in being able to charge and discharge at some fairly eye-watering rates, the miserable energy density would seem to limit them to stationary applications, at least for now.
Perfect for backup power, load shifting, and other power-grid-tied applications though.
They’ve also got much better lifespans, being able to cycle many more times with less capacity loss. As they currently stand, they’re much better choices for stationary storage applications. However, I have seen them implemented in power tools and cars for their discharge rates, but it doesn’t hurt that they will stay healthy for longer.
I mean, I wouldn’t mind a car with “only” 200km range, but that can charge up to full in just 5 minutes. I use my car just for work 99% of the time anyway, the times I need to go somewhere further away I can easily stop midway to charge, get a coffee in the meantime and then be on my way.
Unfortunately what’s shipping today seems it would offer maybe half that.
For the batteries that were announced this past week, a larger-than-refrigerator-sized cabinet held a capacity of around 15kWh.
Around half the energy density by mass of Lithium batteries, and in the order of a sixth of the density by volume.
Now if only we could come up with a system where your car could be charged while stopped at traffic lights, we might be onto a winner (:
Considering however that the price of sodium is around 1-2% that of lithium, I expect we will see significant R&D and those numbers quickly start to improve.
Sadly Sci-Hub has not received updated articles in several years. Alexandra is waiting for the outcome of the trial in India. I don’t think it depends on what the outcome is, just that the trial needs to be over.
We have the internet man, just bug another human and wait a few days to hear back from them.
Like I know that’s what you are “supposed” to do. But public money public knowledge, I refuse to accept that this is somehow an acceptable state of things.
There have been constant news articles coming out over the past few years claiming the next big thing in supercapacitor and battery technologies. Very few actually turn out to work practically.
The most exciting things to happen in the last few years (from an average citizen’s perspective) are the wider availability of sodium ion batteries (I believe some power tools ship with them now?), the continued testing of liquid flow batteries (endless trials starting with the claim that they might be more economic) and the reduction in costs of lithium-ion solid state batteries (probably due to the economics of electric car demand).
FWIW the distinction between capacitors and batteries gets blurred in the supercapacitor realm. Many of the items sold or researched are blends of chemical (“battery”) and electrostatic (“capacitor”) energy storage. The headline of this particular pushes the misconception that these concepts can’t mix.
My university login no longer works so I can’t get a copy of the paper itself :( But from the abstract it looks first stage, far from getting excited about:
“holds promise” and “has the potential” are not miscible with “May Be the Beginning of the End for Batteries”.
I’ve been seeing a lot about Sodium-ion just in the past week.
While they seem to have a huge advantage in being able to charge and discharge at some fairly eye-watering rates, the miserable energy density would seem to limit them to stationary applications, at least for now.
Perfect for backup power, load shifting, and other power-grid-tied applications though.
There are already cars with this technology (one of the cheap Chinese ones)
They’ve also got much better lifespans, being able to cycle many more times with less capacity loss. As they currently stand, they’re much better choices for stationary storage applications. However, I have seen them implemented in power tools and cars for their discharge rates, but it doesn’t hurt that they will stay healthy for longer.
I thought one of the main advantages of sodium-ion batteries was price? Great for the applications you listed
Removed by mod
I’m doing research on high energy density Na-ion batteries. We’ll get there eventually
I mean, I wouldn’t mind a car with “only” 200km range, but that can charge up to full in just 5 minutes. I use my car just for work 99% of the time anyway, the times I need to go somewhere further away I can easily stop midway to charge, get a coffee in the meantime and then be on my way.
Unfortunately what’s shipping today seems it would offer maybe half that.
For the batteries that were announced this past week, a larger-than-refrigerator-sized cabinet held a capacity of around 15kWh.
Around half the energy density by mass of Lithium batteries, and in the order of a sixth of the density by volume.
Now if only we could come up with a system where your car could be charged while stopped at traffic lights, we might be onto a winner (:
Considering however that the price of sodium is around 1-2% that of lithium, I expect we will see significant R&D and those numbers quickly start to improve.
|My university login no longer works so I can’t get a copy of the paper itself :(
Scihub my brother 🙏
Sadly Sci-Hub has not received updated articles in several years. Alexandra is waiting for the outcome of the trial in India. I don’t think it depends on what the outcome is, just that the trial needs to be over.
Just email one of the researchers and ask them to send you a copy
We have the internet man, just bug another human and wait a few days to hear back from them.
Like I know that’s what you are “supposed” to do. But public money public knowledge, I refuse to accept that this is somehow an acceptable state of things.
I wouldn’t know, but it’s totally not on there, or so I’ve been told.
Are these papers not listed on arxiv?
More like decades. Anyone remembers buckyballs and buckytubes? What happened to that?
Nanotubes are still a thing, but most of the hype now seems to be around ‘buckysheets’ (graphene)
There’s an old saying: “Graphene is so versatile it can do anything except leave the laboratory”.
To paraphrase one of society’s less brilliant thinkers, “Who would have thought
heathcareadvanced materials science could be so hard?”I heard that nanotubes are being used in strengthening various materials. But yeah, not world-changing
Yup. How long have we been waiting for graphene batteries to revolutionize technology? About a decade now?
…and the same obstacle that faced graphene a decade ago is the same seemingly insurmountable obstacle facing it today.