What if charging your phone took less time than brushing your teeth? A new study published in Proceedings of the National Academy of Sciences could very well hold the key to a next-gen charger capable of recharging your phone in just 60 seconds.
Researchers from the University of Colorado Boulder have discovered a new cutting-edge technique that could make it possible to charge devices almost instantaneously. This would make charging phones, laptops, and even electric cars much more efficient and convenient. The foundation of the new technique is based on new insights into how ions move through supercapacitors.
The key, one of the researchers explains in a press release, is to make the movement of the ions more efficient. By doing this we can make the charging and release of energy much faster, allowing for that next-gen charger that is capable of boosting your phone’s charge from 0 to 100 in just a minute, or maybe even less.
To make this discovery, the researchers looked at the movement of ions through a complex network of interconnected pores running through the supercapacitor. Their findings have helped modify a scientific law that researchers have used to govern electrical currents for more than 175 years. This law, called the Kirchhoff circuit law, describes the flow of electrons in a simple loop of wiring in most classes.
However, when inspecting the ions and their movement, the researchers found that the ions move fundamentally differently at the intersections of tiny nanoscale pores when compared to how electrons move near the same locations. Further observations helped them determine that these movements are different from what Kirchhoff’s law describes. This doesn’t completely throw out the old laws, though, as they still provide valid explanations for how electronics flow within conventional electronic circuits.
However, to create a next-gen charger capable of taking full advantage of the movements of the ions, we have to look at things different. This, the researchers say, is “the missing link” that they have been looking for. Creating more efficient energy storage has been a long-term goal for many engineers.
We’ve seen water-based batteries capable of storing more than traditional lithium-ion batteries. Still, a method that lets us charge our batteries almost instantly would remove a lot of the hindrances surrounding the wider adoption of things like electric cars. Not to mention how much more convenient a next-gen character would make charging laptops, phones, and other electronic devices.
Yeah, no. This is not about chargers or batteries or phones or cars. This study is about improved charge/discharge rates for supercapacitors.
Supercaps have very high flow rate, but extremely low capacity. Put them in a phone or a car and it would run very fast for five minutes. Supercaps are useful, don’t get me wrong, but they’re not batteries.
Very cool research from UC Boulder, but the journalism leans way too far into clickbait.
The bigger issue I would see is the heat created from dumping all that energy in at once. And can a US outlet even provide that much power?
Solid point. A laptop battery is around 60Wh, and charging that in 1 minute would pull 3.6kW from the outlet, or roughly double what a US residential outlet can deliver.
Supercaps stay pretty cool under high current charging/discharging, but your laptop would have to be the size of a mini fridge.
The research paper itself was only talking about using the tech for wearable electronics, which tend to be tiny. The article probably made the cars-and-phones connection for SEO. Good tech, bad journalism.
I remember when you could fully charge your battery in under 30 seconds.
REMOVABLE BATTERIES BITCH
So what are we looking at, the next 5 years?
No, never. Current charging rates already get close to thermal constraints. Hitting those charging rates either requires accepting much lower power density or using way more metal per cell. This research might inform design changes to improve charging rates, but we’ll never see high capacity batteries charging in a minute.
The researchers know this and only mention wearables and iot devices applications. The article author erroneously makes the leap to high energy density devices.
If you don’t care about energy density at all, ceramic capacitors can already charge and discharge in microseconds.
…and explode them in the next 60
No, most phones are allready safe to leave on your charger all night.
Been charging my phone overnight for years. Battery health is 100% and I never have to worry about charging.
Impossible for battery health to be at 100% after years. May still be working great, but not 100%.
Battery degradation is ridiculously unpredictable. I’ve seen 100 cycle batteries at 75% and 2500 cycle batteries over 90%. I only dealt with like 5 MacBook models
Agreed, but not a “charge overnight for years” but no degradation at all.
Depending on what battery protection modes are in play, many have smart charging or other features designed to prolong life. Also a fair few batteries come out with greater than design capacity from the factory. It’s called a design capacity and not an absolute capacity for a reason. A phone battery that left the factory at 110% could conceivably still be at or above 100%.
Fyi it’s not overnight charging that’s the issue either, it’s charging to 100%. What one device consider 100% varies and devices will essentially lie to you about it. 4.2V is normally considered 100% full for Lithium Cobalt Oxide batteries yet some devices push higher than this while others skirt under to pad capacity and cycle life respectively. It’s about tradeoffs.
One hour is fast enough
Can we focus on other things, like making devices cheaper or idk, NOT spy bricks
clears throat one hour is not fast enough.
Well, yea. Tho it would be cool to be able to slow charging down in software, I wanna sleep while charging without overcharge
That is another matter altogether. Apple has that feature that limits the charge to 80%. Easily done. In fact, as we move to AI, we can create much more intelligent charging schemes that can be tailored to the user.
But when it comes to actual charge times, obviously less is better. Not sure why anyone in their right mind would get upset over lower times and claim that things are fine now. It’s like fighting against electricity because you love your typewriter.
Android already does that, no AI required. Some fairly simple math is enough.
The device first charges to 80% and holds there. It also calculates how long it will need to charge from there to full and when it will need to resume charging so that it will hit 100% just before the next alarm goes off. Then it does that.
