HOW IT WORK? - Li_ion batteries

Issuing time:2019-01-19 17:28

Li_ion batteries have revolutionised modern life, through their application in consumer electronics and by powering applications as diverse as medical implants, grid_scale storage and satellites. However, recent concerns regarding product safety have fuelled public concern about battery safety. So how do these cells work, and what can go wrong?

A lithium-ion (Li_ion) battery is assembled from three  basic components: an anode,cathode and electrolyte.During charging, Li+ ions are moved by an electro chemical driving force from the cathode to the anode through the medium of the ionically conducting electrolyte. During discharge, the reverse happens, and as the Li+ ions move, the coupled transport of an electron to ensure charge neutrality is able to perform useful work. The quantity of Li-ions transferred indicates the total amoun of energy available within the cell, and the rate of transfer indicates its power.

There are a variety of cathode materials available commercially that provide the ‘source’ of lithium within the cell. Nearly all commercially available Li-ion batteries use a graphite anode material, and  as the batter is charged, lithium is removed from the cathode material, conducted through the electrolyte and ‘intercalated’ (inserted) between the graphene galleries in the characteristically layered graphite structure. This process is remarkably reversible, and the Columbic efficiency for state-of-the-art Li-ion cells can  be around 0.9999. This high efficiency guarantees the long cycle life of Li-ion cells compared  to alternative battery chemistries.

However, these cells are not without fault: ‘capacity fade’ is a common and frustrating experience, as overextended cycle-life battery capacity drops and batteries need increasingly frequent charging. While these  durability issues remain a concern, it is the more rapid and dangerous failures that have recently made headlines.

The constituent materials in a cell work best within a safe operating window that defines the safe temperature and voltage range, as well as the maximum current that the cell can accept during charging (and deliver during discharge).

Trying to charge a cell too quickly can lead to the precipitation of metallic lithium within the cell, whereas voltages outside the safe operating window can lead to degradation of the electrolyte with the possibility of gas generation. External effects can also influence how the cell behaves, and extremes of temperature and pressure are known to have safety implications.

If something does go wrong, there is also hardware inside cells to mitigate against failure. This includes separator materials that prevent short circuiting, positive temperature co-efficient devices that limit  cell  voltage at elevated temperatures, and pressure relief events that trigger in the event of excess gas generation to prevent cell rupture.Increasingly sophisticated battery management systems are designed to protect the batteries from these extremes; when you plug your mobile phone in to charge, control systems monitor the current and voltage ‘seen’ by the cell and keep it within its comfort zone.

Catastrophic failures include thermal runaway events, which can occur when heat generated within a cell triggers an exothermic reaction, releasing more heat and driving further exothermic reactions. When the rate of heat generation exceeds the rate of rejection, the thermal runaway proceeds, which can lead to fires and explosions.

In very rare occurrences, manufacturing defects have also been known to cause cell failure. Li-ion cell electrodes are manufactured in extremely high volumes,and the  electrodes are assembled  in tightly  packed configurations to maximise volumetric energy density. While the quality control processes are robust, contaminants in the process can cause problems; for example, any metallic contaminants can puncture the separator and cause short circuiting between the electrodes. Similarly welding, assembly and electrochemical ‘formation’ are subject to highly stringent quality controls, as they can also jeopardise cell safety if left unchecked.

The drive to maximise volumetric energy density and miniaturise cells must be tempered with safety guarantees.

Thankfully, failure rates are estimated to be as low as one failure per 40 million cells; it is therefore highly unlikely that you will ever experience a cell failure firsthand. However, with the increasing presence of these products, and their requirement to operate in a range of environments, scientists and engineers are tackling the challenge of designing safer and more durable batteries, both for Li-ion cells and next-generation energy storage technologies.


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