The piezoelectric effect in liquids

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Last Updated01/04/2023

For the first time, scientists have reported evidence of the piezoelectric effect in liquids.
The effect has been known for 143 years and in this time has been observed only in solids.
The new finding challenges the theory that describes this effect as well as opens the door to previously unanticipated applications in electronic and mechanical systems.
The effect was found in pure 1-butyl-3-methyl imidazolium bis(trifluoromethyl-sulfonyl)imide and 1-hexyl-3-methyl imidazolium bis(trifluoromethylsulfonyl)imide — both ionic liquids (liquids which are made of ions instead of molecules) at room temperature.
The study paper was published in the Journal of Physical Chemistry Letters.

In the piezoelectric effect, a body develops an electric current when it is squeezed.
Quartz is the most famous piezoelectric crystal; it is used in analog wristwatches and clocks.
Such crystals are also used in other instruments where converting mechanical stress to a current is useful.

Quartz is silicon dioxide (SiO2).
The quartz crystal consists of silicon and oxygen atoms at the four vertices of a three-sided pyramid; each oxygen atom is shared by two pyramids.
These pyramids repeat themselves to form the crystal.
The effective charge of each pyramid is located slightly away from the centre.
When a mechanical stress is applied, that is when the crystal is squeezed, the position of the charge is pushed further from the centre, giving rise to a small voltage. This is the source of the effect.

The reason the piezoelectric effect has only been expected in solids thus far is that the body being squeezed needs to have an organised structure, like the pyramids of quartz.
Liquids don’t have such structure as they take the shape of the container.
Physicists explain the effect using a combination of Hooke’s law and the properties of dielectric materials.
These are materials that don’t conduct electricity but whose electrons are still mildly affected by an electric field. Hooke’s law is not clear when the body isn’t very compressible.

The discovery opens the door to applications that have previously not been accessible with solid-state materials, and are more readily recyclable and in many instances pose fewer environmental issues than many currently used piezoelectric materials.
The liquids also displayed the inverse piezoelectric effect: they became distorted when an electric charge was applied.
This could be used to control how the liquids bent light passing through them by passing different currents through them.
That is, using this simple control mechanism, vials of these liquids could be lenses with dynamic focusing abilities.
Having a theory to explain the liquids’ behaviour could reveal why these liquids behave the way they do, which in turn could reveal better ways to develop newer applications.