Bright Idea: Glow-in-the-Dark Dye Could Power Cars

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If the world one day sees a boom in electric cars and renewable energy, people will need more efficient batteries than are currently available. Now, researchers say a glow-in-the-dark dye used to track chemicals in cells could offer a solution.

The chemical is boron-dipyrromethene, otherwise known as BODIPY, and it consists of a set of carbon rings linked to a boron atom and two fluorine atoms. BODIPY glows under “black” light. Chemistry researchers use it as a marker to see reactions or identify where biological systems take up other substances, such as cadmium.

In the new study, a team of chemists at the University at Buffalo tested BODIPY’s power-generating abilities with a special type of battery called a reduction-oxidation battery (or redox). The researchers found that small amounts of the dye added to a solution of acetonitrile could make a battery that can be charged and recharged 100 times without losing its ability to store energy efficiently.

In an ordinary rechargeable battery, like the lithium-ion ones used in computers and phones, the changes in the battery chemistry are in a solid state, and it’s harder for electrical charges to flow. Lithium-ion batteriesuse lithium as the charge carrier; lithium gives up electrons and moves from the negative to positive electrode.

Usually a battery has carbon and lithium oxide in it, and both are solids (hence the term “solid state”), so the substance of the battery has to be porous enough for the lithium ions to get through easily. Between the lithium and carbon layer is a liquid electrolyte to carry the charges (it typically isn’t water, and the chemical varies among different manufacturers). The problem is that after repeated charge cycles, the electrodes inside the battery can degrade, because they are reacting with the other chemicals in the battery.

Researchers show that BODIPY dye has interesting chemical properties that could make it an ideal material for use in large-scale rechargeable batteries.
Researchers show that BODIPY dye has interesting chemical properties that could make it an ideal material for use in large-scale rechargeable batteries.

Tim Cook, an assistant professor of chemistry at the University at Buffalo and lead author of the new study, told Live Science that his team combined two different approaches. The first one involved using a redox battery, (redox is short for reduction-oxidation) which consists of two chambers of liquid kept separate by a membrane. In this system, the liquids are the electrolytes surrounding the positive and negative terminals, and with that setup, it’s necessary only to find something that will dissolve in the liquid and release electrons.

“If the charge carrier is in solution, it doesn’t have the problem other batteries have when [the electrode] crystallizes,” which happens with some lithium-ion batteries, Cook said.

The second step was finding a substance that could dissolve in liquid and carry electrons. The researchers found that BODIPY was a very effective electron carrier; it both gives up and takes in electrons easily, Cook said. This means the glow-in-the-dark substance is more efficient at delivering energy.

This redox battery may be a safer option than lithium ion batteries, which sometimes catch fire. This happens because the lithium in them is ionized, meaning it has given up an electron. That makes the element very reactive with the oxygen in water, including the moisture in the air, forming lithium oxide and releasing hydrogen.

“What you’re left with is two ionized hydrogens that were attached to water, and we have two lithiums that gave up electrons to join with the water, and that reaction is kicking off a lot of heat too,” Cook said.

The hydrogen that can burn if a spark hits it, or the chemicals used for the electrolyte, can react with air. (Lithium itself is so reactive that a popular demonstration in chemistry classes is dropping lithium in water to watch it bubble and generate hydrogen.)

When lithium ion batteries catch fire it’s usually because the casing of the battery cracks, exposing the insides to the air, or because the membranes that separate the chemical species inside the battery get damaged, allowing reactions to occur inside the battery. Those reactions generate gases, heat, and sometimes fire. [9 Odd Ways Your Tech Device May Injure You]

“A [lithium]-based battery has a lot of energy, and if there are mechanical failures, like the membrane separator is ruptured,

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