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Plastic bags recycled into nanotubes

Waste polyethylene from shopping bags and other sources can easily be converted into carbon nanotubes suitable for use in batteries
Giving plastic bags a second life
Giving plastic bags a second life
(Image: Jeff J Mitchell/Getty)

Waste plastic from 鈥渢hrowaway鈥 carrier bags can be readily converted into carbon nanotubes. The chemist who developed the technique has even used the nanotubes to make lithium-ion batteries.

This is called 鈥渦pcycling鈥 鈥 converting a waste product into something more valuable. Finding ways to upcycle waste could encourage more recycling: for instance, bacteria can convert plastic drinks bottles into a more expensive plastic.

The carrier-bag-to-nanotube technique was developed by Vilas Ganpat Pol at the in Illinois and converts high or low-density polyethylene (HDPE and LDPE) into valuable multiwalled carbon nanotubes.

Bag baker

Pol made the nanotubes by cooking 1-gram pieces of HDPE or LDPE at 700聽掳C for 2聽hours in the presence of a cobalt acetate catalyst and then letting the mixture cool gradually. Above 600聽掳C the chemical bonds within the plastic completely break down and multiwalled carbon nanotubes grow on the surface of the catalytic particles.

A lot of catalyst is needed to get good results 鈥 about a fifth of the weight of the plastic being converted 鈥 and it cannot easily be recovered afterwards. But Pol says this is still one of the cheapest and environmentally friendly ways yet found to grow nanotubes.

鈥淥ther methods generally require a vacuum to avoid oxygen interaction with the catalyst as well as with the system,鈥 he says. 鈥淚n my new reaction there is no vacuum 鈥 the formation of oxide is inhibited due to the presence of a continuous reducing hydrocarbon atmosphere at 700聽掳C.鈥

Nanotube nuggets

Individual pieces of the catalyst become trapped inside forests of newly grown nanotubes. But Pol has shown the nanotubes can be used as is without further processing to cut them free.

鈥淚 have used the as-prepared cobalt-encapsulated nanotubes as an anode material for lithium-ion batteries and they work fantastically,鈥 he says. 鈥淭he specific capacity of my carbon nanotubes is higher than commercial nanotubes.鈥 He thinks that might be down to slight imperfections in the usually-regular structure of the nanotubes, created by the reducing atmosphere during fabrication.

The cobalt impurities also make the nanotubes suitable for use in lithium-air batteries, because the cobalt is converted to cobalt oxides that perform as catalysts to help the reactions of ions in the battery that let current flow, says Pol. He has patented the use of the cobalt-containing nanotubes in both lithium-ion and lithium-air batteries: 鈥淭he cobalt is not an impurity, it is an asset,鈥 he says.

Recycling jigsaw

at the University of Reading in the UK is an expert in recycling plastic. He thinks the new technique is an 鈥渋nteresting part of the jigsaw鈥 of recycling plastic waste to make high-value electronic materials.

But he thinks the use of relatively expensive cobalt as a non-recoverable catalyst might be problematic if the system is ever to be scaled up. Pol agrees, but adds that the type of batteries he proposes using the nanotubes for are already recycled for their cobalt, so the metal would ultimately be recovered.

Leaving the catalyst out of the process altogether yields another carbon product of potential value, though: carbon spheres between 2聽and 10聽micrometres across that can be used in printer ink, says Pol.

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Topics: Energy and fuels