How Thin Film Batteries Work
Batteries come in many forms. These can be through different classifications, such as primary or secondary, or through the internal structure of the battery itself. Because batteries are used in so many commercial products, there are many different types and research is always being undertaken to create smaller, more efficient and safer batteries. In this article we look at thin film batteries, how they work and the advantages they possess over other types of battery.
What are Thin Film Batteries
Thin film batteries are a type of solid state battery, i.e. a battery that uses both solid electrodes and a solid electrolyte. However, unlike many other batteries, they are of the order of a few hundred nanometres. As with all batteries, thin film batteries possess both an anode and a cathode, as well as an electrolyte and separator material between the two.
For many thin film batteries, the cathode is usually made of a lithium-oxide complex such as LiCoO2, LiMn2O4 and LiFePO4. The anode material is commonly made of a carbon-based material such as graphite, although lithium and other metals can be used.
The key characteristic of the materials used in both the electrodes is that they are layered materials; and this allows a small number of layers to be created during the construction of the battery, thus making the battery very thin. Additionally, layered materials are used so that the lithium ions in the cell can readily intercalate and de-intercalate, without causing any damage to the structure of the electrodes. To create the desired thickness, the materials are often deposited using physical vapour deposition (PVD) techniques such as sputtering and thermal evaporation.
As mentioned, the electrolyte in these batteries are traditionally made of solid inorganic-based materials. The most common solid electrolyte used is lithium phosphorus oxynitride (LiPON), although recent research has seen a surge in using ceramic electrolytes such as lithium lanthanum zinc oxide (LLZO) and lithium lanthanum titanium oxide (LLTO). Regardless of the structure, the electrolytes employed must be an efficient ion conductor and a good electrical insulator.
How Thin Film Batteries Work
The internal structure of thin film batteries resembles the structure of many rechargeable batteries, only much smaller, so the ion migration mechanisms are essentially the same. So, when the battery is being charged, the lithium ions migrate from the lithium rich cathode and move into the anode. When the battery is in this state, it will absorb energy that can then be stored. If the battery is turned on during charging, the lithium ions will move back to the cathode and electrons will move from the cathode to the anode (although not through the electrolyte) and a current between the two electrodes is created.
When the battery is not being charged, it is in a state known as discharging. The lithium ions move from the anode to the cathode (i.e. discharge) and electrons will travel from the cathode to the anode. The time it takes for the ions to completely discharge is the current life of the battery, and when all the lithium ions have returned to the cathode, the battery will run out of power because the electrons will not migrate if there is no lithium ion movement. Thus, the battery will need to be charged again. If the battery is in a product that can be switched off, it will still discharge while the device is switched off, but at a much slower rate.
