Rechargeable batteries use combinations of materials that can easily and durably exchange electrons and positive ions. Internal combustion engine vehicles most often use lead-acid batteries, which contain a negative electrode made of lead, a positive electrode made of lead oxide, and an electrolyte consisting of sulfuric acid and water. Other materials used in batteries include nickel, cadmium, sodium and sulfur.
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Scientists became particularly keen on lithium for batteries, since it is a very lightweight metal (the third element in the periodic table, after and helium). Lithium atoms can readily release one of their three electrons, creating positively charged Li+ ions. Manufacturers initially used lithium metal for the negative electrode, which emits electrons. However, they noticed that the repeated use and recharging cycles altered the metal. To avoid this, the cathodes are now often made from cobalt oxide and a small proportion of lithium, with a graphite anode. The electrolyte is made of lithium salts in a solvent, meaning that it contains a great many lithium ions. That is where the name “lithium-ion battery” comes from.
The core component of a lithium-ion battery is a cell that looks a bit like puff pastry, with an aluminum plate to collect the current, followed by the cathode, electrolyte, anode, and finally a copper plate (see diagram).
When the battery is being charged up, Li+ lithium ions leave the positive electrode (cathode) and are stored in the negative electrode (anode). When it is discharged to produce an electric current, the Li+ ions move in the opposite direction.
These cells, each with a voltage of a few volts, can be grouped together in varying numbers, depending on the capacity required to power a cell or car battery.
Lithium-ion batteries have a high , meaning that they can store three to four times more energy per unit mass than batteries using other technology. They are quick to recharge and can be used over and over again, with at least 500 discharge/charge cycles at 100%.
However, they are at risk of suddenly catching fire and releasing toxic gases due to the electrolyte overheating to above 100°C, known as thermal runaway. This has led to thousands of cell phones and tablets being recalled by manufacturers in recent years. In , a battery in a Boeing 787 aircraft caught fire after landing.
Investigations have shown that overheating is most often caused by a short circuit brought on by incorrect assembly or impact. As a result, manufacturers are now required to follow rigorous processes and fit the lithium-ion batteries they make with an electronic battery management system (BMS), which turns the power off if it detects an anomaly.
In addition, manufacturers are looking into innovative technology that could help prevent overheating, such as solid electrolytes made of ultrathin polymer films.
The decision to ban the sale of internal combustion engines after means that Europe must catch up in battery production. Several countries, in conjunction with vehicle manufacturers and startups, have launched projects to design new (lithium) battery models, with the challenge of them for future production.
"Gigafactories" dedicated to the production of batteries with a capacity of several gigawatt-hours (GWh) are being developed, with the long-term aim of taking over part of the market currently held by Asia (China, South Korea and Japan). In addition to the creation of these sites, the products themselves are the subject of innovations to equip the vehicles of tomorrow with more efficient batteries... and at lower cost.
by Chris Woodford. Last updated: September 11, .
Power to go—that's the promise batteries deliver. They give us all the convenience of electricity in a handy, portable form. The only trouble is, most batteries run flat very quickly and, unless you use a specialized charger, you then have to throw them away. It's hard on your pocket and bad for the environment as well: worldwide, we throw away billions of disposable batteries every single year. Rechargeable batteries help to solve this problem and the best kind use a technology called lithium ion. Your cellphone, laptop computer, and MP3 player probably all use lithium-ion batteries. They've been in widespread use since about , but the basic chemistry was first discovered by American chemist Gilbert Lewis (–) way back in . Let's take a closer look at how they work!
Photo: Lithium-ion batteries power all kinds of "mobile" technology, from electric toothbrushes and tablet computers to electric cars and trucks. Photo by Dennis Schroeder courtesy of NREL (photo id#).
If you've read our main article on batteries, you'll know a battery is essentially a chemical experiment happening in a small metal canister. Connect the two ends of a battery to something like a flashlight and chemical reactions begin: chemicals inside the battery slowly but systematically break apart and join themselves together to make other chemicals, producing a stream of positively charged particles called ions and negatively charged electrons. The ions move through the battery; the electrons go through the circuit to which the battery's connected, providing electrical energy that drives the flashlight. The only trouble is, this chemical reaction can happen only once and in only one direction: that's why ordinary batteries usually can't be recharged.
Artwork: Ordinary batteries, such as zinc-carbon and alkaline ones, cannot be recharged because the chemical reactions that generate the power are not reversible. Once they're empty of electrical energy, there's no easy way to refill them.
Different chemicals are used in rechargeable batteries and they split apart through entirely different reactions. The big difference is that the chemical reactions in a rechargeable battery are reversible: when the battery is discharging the reactions go one way and the battery gives out power; when the battery is charging, the reactions go in the opposite direction and the battery absorbs power. These chemical reactions can happen hundreds of times in both directions, so a rechargeable battery will typically give you anything from two or three to as much as 10 years of useful life (depending on how often you use it and how well you look after it).
Like any other battery, a rechargeable lithium-ion battery is made of one or more power-generating compartments called cells. Each cell has essentially three components: a positive electrode (connected to the battery's positive or + terminal), a negative electrode (connected to the negative or − terminal), and a chemical called an electrolyte in between them. The positive electrode is typically made from a chemical compound called lithium-cobalt oxide (LiCoO2—often pronounced "lyco O2") or, in newer batteries, from lithium iron phosphate (LiFePO4). The negative electrode is generally made from carbon (graphite) and the electrolyte varies from one type of battery to another—but isn't too important in understanding the basic idea of how the battery works.
Photo: A lithium-ion battery, such as this one from a smartphone, is made from a number of power-producing units called cells. Each cell produces about 3–4 volts, so this battery (rated at 3.85 volts) has just one cell, whereas a laptop battery that produces 10–16 volts typically needs three to four cells.
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All lithium-ion batteries work in broadly the same way. When the battery is charging up, the lithium-cobalt oxide, positive electrode gives up some of its lithium ions, which move through the electrolyte to the negative, graphite electrode and remain there. The battery takes in and stores energy during this process. When the battery is discharging, the lithium ions move back across the electrolyte to the positive electrode, producing the energy that powers the battery. In both cases, electrons flow in the opposite direction to the ions around the outer circuit. Electrons do not flow through the electrolyte: it's effectively an insulating barrier, so far as electrons are concerned.
The movement of ions (through the electrolyte) and electrons (around the external circuit, in the opposite direction) are interconnected processes, and if either stops so does the other. If ions stop moving through the electrolyte because the battery completely discharges, electrons can't move through the outer circuit either—so you lose your power. Similarly, if you switch off whatever the battery is powering, the flow of electrons stops and so does the flow of ions. The battery essentially stops discharging at a high rate (but it does keep on discharging, at a very slow rate, even with the appliance disconnected).
Unlike simpler batteries, lithium-ion ones have built in electronic controllers that regulate how they charge and discharge. They prevent the overcharging and overheating that can cause lithium-ion batteries to explode in some circumstances.
Photo: Lithium-ion batteries are less toxic than batteries containing heavy metals such as lead, cadmium, and mercury, but recycling them is still far preferable to incinerating them or sending them to landfill. This photo shows a chemical reclamation process called relithiation, which restores spent battery chemicals to a form good enough to reuse with minimal investment of energy. Photo by Werner Slocum courtesy of NREL (US National Renewable Energy Laboratory). NREL photo id#.
Generally, lithium ion batteries are more reliable than older technologies such as nickel-cadmium (NiCd, pronounced "nicad") and don't suffer from a problem known as the "memory effect" (where nicad batteries appear to become harder to charge unless they're discharged fully first). Since lithium-ion batteries don't contain cadmium (a toxic, heavy metal), they are also (in theory, at least) better for the environment—although dumping any batteries (full of metals, plastics, and other assorted chemicals) into landfills is never a good thing. Compared to heavy-duty rechargeable batteries (such as the lead-acid ones used to start cars), lithium-ion batteries are relatively light for the amount of energy they store.
Lithium-ion batteries are getting better all the time, as electric cars clearly demonstrate. Lightweight lithium-ion batteries were first properly used in electric cars in the pioneering Tesla Roadster, manufactured from to . It took roughly 3.5 hours to charge its lithium-ion cells, which together weighed a whopping one half a tonne ( lb) and held 53kWh of energy. [1] Fully charged, they gave the car a range of over 350km (220 miles). Newer Teslas have far better cells and much greater range. A typical Tesla Model 3 has a 75kWh battery (half as much energy again as a Roadster) with just 4,416 cells—so they clearly have much higher energy density—and a range of 602km (374 miles). [2]
Photo: The lithium-ion batteries used in a plugin hybrid car. Photo by Andrew Hudgins courtesy of US Department of Energy National Renewable Energy Laboratory (NREL), image id # .
If we're interested in the drawbacks of lithium-ion batteries, it's important to bear in mind what we're comparing them with. As a power source for automobiles, we really need to compare them not with other types of batteries but with gasoline. Despite considerable advances over the years, kilo for kilo, rechargeable batteries still store only a fraction as much energy as ordinary gas; in more scientific words, they have a much lower energy density (they store less energy per unit of weight). That also explains why you can fully "recharge" (refuel) a gas-powered automobile in a couple of minutes, whereas it'll generally take you hours to recharge the batteries in an electric car. Then again, you have to bear in mind that these disadvantages are balanced by other advantages, such as the greater fuel economy of electric cars and their relative lack of air pollution (zero tailpipe/exhaust emissions from the vehicle itself).
Leaving aside vehicles and considering lithium-ion batteries more generally, what are the problems? The biggest issue is safety: Li-ion batteries will catch fire if they're overcharged or if an internal malfunction causes a short circuit; in both cases, the batteries heat up in what's called a "thermal runaway," eventually catching fire or exploding. That problem is solved with a built-in circuit breaker, known as a current interrupt device or CID, which kills the charging current when the voltage reaches a maximum, if the batteries get too hot, or their internal pressure rises too high.
Photo: Lithium-ion batteries can inflate like little cushions if they don't have a means of venting any gases produced during charging (mainly carbon monoxide, carbon dioxide, and hydrogen, though smaller amounts of other organic gases may also be present). Here are two identical batteries from a cellphone, the top one of which has almost doubled in width due to the trapped gases inside.
But there remain concerns and, in , the International Civil Aviation Organization officially prohibited shipments of lithium-ion batteries on passenger planes because of the potential danger. Now the safety risks of lithium batteries have attracted lots of media attention—especially when they've caused fires to break out in electric cars or on airplanes—but it's worth bearing in mind how few incidents there have been given how common the technology is (you'll find lithium-ion batteries in every modern cellphone, laptop, tablet, and most other rechargeable gadgets). And, once again, it's important to bear in mind the risks of the alternatives: yes, lithium-ion batteries in electric cars can catch fire—but gasoline-powered automobiles catch fire much more often... and cause actual explosions! Other types of batteries can also catch fire and explode if they overheat, so fire isn't a problem that's unique to lithium-ion technology.
Photo: What happens when a lithium-ion battery fails completely. Top: An intact battery. Bottom: An identical battery that failed after being punctured in a lab safety test. Photo by Dennis Schroeder courtesy of NREL (US National Renewable Energy Laboratory). NREL photo id#.
What's the solution? One promising option, currently being pioneered by a company called Ionic Materials, is to use flame-resistant polymers (solid plastics) in place of the flammable liquid electrolytes that are normally used in lithium-ion batteries. Another option, favored by John Goodenough, the chemist behind lithium-ion batteries, is to use "doped" glass (treated to make it electrically conductive) for the electrolyte instead. Time will tell whether one of these options—or something else entirely—will topple lithium-ion batteries from their place as the world's favorite rechargeable technology.
Artwork: A lithium-ion battery has a current interrupt device (CID) inside to stop it overheating. Here's one example of how it can work. The two battery electrodes (green, 12 and 14) sit inside a case (light blue, 22) with a lid on top (dark blue, 24). One of the electrodes (14) is connected to its top terminal (42) through the CID (28), which is made of three parts. There are two metal conducting discs (red, 30 and 32) with an insulator (purple, 34) in between them. Normally the discs are touching and allow current to flow from the electrode to its terminal. But if the battery overheats and pressure builds up inside, the discs are pushed apart and stop any more current flowing. Any excess gas vents through small slits (yellow, 56) in the sides of the case. Artwork from US Patent 4,423,125: Integrated current-interrupt device for lithium-ion cells by Phillip Partin et al, Boston-Power, Inc., courtesy of US Patent and Trademark Office.
Handy, helpful lithium-ion power packs were pioneered at Oxford University in the s by chemist John Goodenough and his colleagues Phil Wiseman, Koichi Mizushima, and Phil Jones. Their research was published in and turned into a commercial technology by Sony, who produced the first lithium ion batteries in the early s. Since then, they've become commonplace: around 5 billion are manufactured every year (according to a Bloomberg news report from ), most of them in China. Three pioneers of lithium-ion battery technology—John Goodenough, M. Stanley Whittingham, and Akira Yoshino—shared the Nobel Prize in Chemistry for their groundbreaking work. Like all scientists, their research can trace back to earlier discoveries; in this case, it's worth mentioning American chemist Gilbert Lewis and his research into the electrochemistry of lithium, in the early 20th century.
: A typical lithium-ion cellphone battery. This one is rated 3Wh, so you'd need about 25,000 of these to store as much electrical energy as you'd pack into a 75kWh (75,000Wh) Tesla Model 3 car battery!
Today's lithium-ion rechargeables have many advantages over yesterday's "nicads," but they're far from the end of the story. As we've already seen, there are pesky problems like "thermal runaway" still seeking effective solutions. Meanwhile, the hurtling pace of climate change is accelerating the need for cheaper, safer, more energy-dense and environmentally friendly batteries that charge more quickly and pack ever more energy into ever smaller space. Lots of exciting research is going on as you read these words. Ultra-fast-charging graphene batteries, ones made from other cutting-edge nanomaterials such as carbon nanotubes, and even ones based on genetically engineered viruses and vitamins such as flavin could be powering your computer or smartphone in the very near future!
Photo: Lithium-ion batteries can also work at scale to store power produced by renewable sources like wind turbines and solar cells. Here's an experimental 1MWh battery storage unit under test at NREL. Photo by Dennis Schroeder courtesy of NREL (US National Renewable Energy Laboratory). NREL photo id#.
Chris Woodford is the author and editor of dozens of science and technology books for adults and children, including DK's worldwide bestselling Cool Stuff series and Atoms Under the Floorboards, which won the American Institute of Physics Science Writing award in . You can hire him to write books, articles, scripts, corporate copy, and more via his website chriswoodford.com.
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