When it’s your job to take devices apart and figure out how they work, you start to think about them differently. I like to think about the complex circuitry of a smartphone the same way I think about the ecosystem of a human body. That makes the battery in your smartphone the heart. (Bear with me here.)
Just like your heart supplies oxygen-rich blood to the rest of your body, your smartphone’s battery pumps nutritious electrical energy to every part of the device, keeping it healthy and functioning. Say you got a heart transplant at 60. It might not restore your body to that of your twenty-year-old self, but it would certainly improve its critical functions. Same goes for installing a new battery in your smartphone—it might not bring your phone back to pristine condition, but it can significantly boost its performance.
Behind the battery
Like most modern portable electronic devices, iPhones use lithium-ion (Li-ion) batteries. You can think of a Li-ion battery as a packet of extremely volatile chemicals and metals, separated by super-thin, non-conductive layers, which prevent the electrodes from touching and triggering a potentially explosive thermal reaction. It’s similar to the chemistry of glow sticks, where two solutions are separated to prevent them from reacting with each other. Except, when you crack a Li-ion battery, you get an explosion, not a cool accessory to bring to a rave. Needless to say, the battery has the potential to be the most… exciting part of your phone. But under normal use, it is perfectly safe.
You can read an exhaustive course on Li-ion batteries over here, but I’ve summarized some practical points of interest below:
1. Li-ion batteries experience very little memory effect
This means you can recharge your iPhone battery before it’s completely drained—with no consequences. Conversely, older nickel-centric batteries would “forget” what their capacity was, so it was advised to fully drain them before charging them back up again. That’s a huge pain, which makes Li-ion batteries a more convenient choice for electronics.
2. All batteries are consumables
That means you use them up and then they die. It’s the circle of life. Li-ion batteries primarily degrade over charge cycles—according to Apple, an iPhone retains up to 80 percent of its original capacity after 500 complete cycles (from 100 to zero percent charge). After that, the battery meter would still read 100% after a full charge—but it would only last 80 percent as long as it did when you first got it. So if you’re an Angry Birds champion or a Twitter power-user, you might want to replace your battery before the 500 cycle mark to enjoy optimal (untethered) play-time.
3. Modern day Li-ion batteries normally incorporate smart circuitry within the battery
Which helps prevent them from becoming damaged or dangerous. This built-in governor works in conjunction with other safety systems, so you can keep your already-charged iPhone plugged in overnight without damaging the battery. The Lightning cable is part of that safety system. MFi Lightning cables include a chip that protects the device from dangerous voltage spikes and thermal runaway. In order to cut costs, many inexpensive Lightning cables (like the ones you see at the gas station) don’t include the MFi chip. So if you’ve already shelled out the dough to buy an iPhone, spend the extra cash and get an MFi-certified Lightning cable—it’s cheaper than replacing a fried iPhone.
4. We’ve all seen those horrifying pictures of swollen batteries circulating the interwebs—but how exactly does that happen?
A Li-ion battery becomes swollen with gases due to physical damage or malfunctioning protection circuitry, resulting in overcharging. The battery pack itself acts as a safety system by containing the outgassing. So if you encounter a swollen battery, immediately dispose of it properly. If you live in North America, you can contact Call2recycle at 1-877-723-1297.
5. Fact: Batteries are incredibly picky about their climate
Temperature is a key factor in keeping your Li-ion batteries healthy and happy. Batteries exposed to high temperatures (over 100ºF) through multiple charge cycles will suffer reduced longevity. Like your pet chihuahua, your phone will appreciate not being left in a hot car.
6. The sleep of death
Do not keep a Li-ion battery fully discharged for long periods of time. The battery’s protection circuit will cut the battery off when it drains too low, but it can only do so much. The battery will continue to slowly self-discharge, damaging the battery’s capacity and ability to recharge.
TLDR: Like any muscle, batteries get tired—but that doesn’t mean it’s the end of the line for your smartphone. Even if manufacturers would rather sell you a new device, you can get past those esoteric screws and get your current device back on track. Or, better yet, fight for your right to easy-access batteries. Who wants a phone with an early expiration date anyway?
Correction: The first version of this article stated that iPhone batteries retain 8o percent of their capacity after a year and a half of use. That is incorrect—batteries retain 80 percent of their capacity after 500 complete cycles (from 100 to zero percent charge), which can take anytime from a year and a half to over three years, depending on how often you use your phone. We’ve updated the article to reflect this correction.
i love the articles that you guys put out. just one of many reasons that i love being a part of this group.
Enjoyed your article, or to continue with your comparison to the human body, it was very good basic “anatomy and physiology” article. Now I understand why the occasional cable gets the error message, “not an Apple approved” acessory; it missing the MFi chip! – ifixit customer.
PS. Waiting for someone to make components to do Apple phone upgrades; keep the case change the internals.
I’m pretty sure everything has an expiration date.
Great article, as always. Repair can set you free.
JC, right on with the phone upgrade concept, “…keep the case change the internals.” I’ve been a proponent of this for years.
In your item 2, there is a misconception. When you say that charging overnight is a charge cycle, that is only true if it was discharged to zero before you charge it. If the battery showed 50% before charging overnight, that would only be 1/2 of a charge cycle. If you did it for 2 nights that would be one full charge cycle. If you charged starting at 50% every night it should last 1,000 days to 80% capacity, or 3 years. Of course, in real life that does not happen. However, most users will get more than a year and a half out of a battery unless they are very heavy Angry Birds or Twitter users.
“Battery cycles” and “number of times charged to 100%” are not the same thing, so the calculation in #2 is incorrect unless the battery is discharged to 0% each day.
To our astute readers: thank you for catching and pointing out the “battery cycle” misconception! We will revise and correct the error.
Thx. A+
You mention how Lightning cables have the proprietary chip in them, but don’t explain why Android phones don’t need such a proprietary system to not get fried.
There is a similar problem with cheap uncertified USB-A to USB-C cables. It doesn’t matter what “camp” you’re in. You get what you pay for. Sometimes that means a fried device be it an iPhone or a Google Chromebook Pixel which happened to get fried when a google engineer tested some cheap USB-C cables. USB is a standard and just like there are certified or “MFi” lightning cables there are certified USB cables…. The point is don’t buy cheap uncertified cables for any device… The proper cables and the devices form a reliable system.
For William, Android devices do need such a chip, they just don’t have them. Which means that your Android phone might get fried if you don’t use a quality power source. Android devices use the same battery management chip that iOS devices use, which is the part that typically gets fried. Fortunately, there are 3rd party repairers who can replace the chip. But it will cost more than a quality power source and cable.
So man type of problems usually occurs in mobile batteries. Here, Author clearly explained the structure of Battery.
You mention 500 complete charges, but not partial charges, which is more common, especially with no memory effect. One app I use claims it knows how much of a full cycle gets used by a partial cycle*. If you want to make your article much more useful and you know something about this, it might be worth mentioning. Cheers
*That is, 15% to 85% uses e.g., 0.2 of a full charge life cycle. The numbers are not related arithmetically.