why your phone battery lasts for days when it's new, but loses charge in a few hours after a year: latest research reveals how lithium-ion cells degrade and could pave the way for longer lasting batteries - lithium ion cell

Scientists have finally solved the mystery behind why smartphone batteries have such an evil battery life after using them for about a year.
According to the latest findings,
How do you believe in lithium-
The ion battery is not working correctly.
They are not charged particles that flow in a single, uniform direction inside the battery, but move back and forth in a random motion mode.
According to the researchers, this knowledge can be used to make batteries that last longer and keep charging without damaging the battery life.
There may be applications for rolling on a large scale.
In addition to electric cars, scientists say, there are billions of gadgets around the world.
This groundbreaking study came from researchers at Stanford University, the Massachusetts Institute of Technology, and the University of Bath who found our understanding of lithium
The ion battery that powers all of our favorite gadgets is not correct.
As we all know, charged particles flow through the material between the positive and negative poles (electrolyte)
This movement creates a charge.
However, it was previously thought that lithium was of the opposite sex, meaning that it flowed in one direction and that the particles were on a uniform route through the battery.
However, it has now been found that the reality is very different, and the particles called ions actually flow back and forth through the electrolyte.
This may produce randomly packaged ion bags inside the battery, resulting in a large amount of heat that damages the life of the battery.
As a result, the battery loses the ability to keep it charged and we often find ourselves relying more on portable chargers.
William Chueh, an assistant professor at Stanford University, said: "We have used very powerful X-
Light from the accelerator, we are using these X
These individual nanoparticles are observed by light.
Our initial expectation was that lithium would only move in some direction.
We actually see lithium moving in the direction it shouldn't move.
The study took advantage of the facility of the lac National Accelerator Laboratory at Stanford University, which enabled the team of scientists to study batteries on a nano scale.
Dr. Chueh elaborated on the phenomenon and explained that the previous theory did not explain how the liquid interacted with the solid.
Like in space, we think about the behavior of particles in vacuum, he said.
But the battery can't work in a vacuum.
It works in liquid.
The team believes they will be able to fix this bug by changing the shipping path and allowing more durable batteries in the future.