A typical recycling process involves the following – waste is collected, sorted, cleaned and processed, then the processed waste is used to manufacture more of the same product, and the cycle is closed when consumers buy these products. The recycling process depends on the fact that these collected waste are made of the same material. That makes it possible to manufacture new products. Yet, that is not the typical case for e-waste.
E-waste, or electronic products that are no longer working, unwanted, or close to the end of their useful lives, are usually made of heterogeneous materials which cannot be readily separated. Therefore, recycling them and putting them back into the cycle does not seem too commercially profitable for the average manufacturer. Yet, these wastes have to be recycled because if they are put back into the environment, which turns out to be usually the case, the toxic materials contained in them can poison our soil, water, air, or wildlife.
To solve this problem some researchers have developed a selective, small-scale microrecycling strategy which can be used to convert old printed electronic parts like circuit boards and monitors into a new type of strong metal coating. These researchers, Veena Sahajwalla and Rumana Hossain, based their research on the copper and silica that are usually the components of electronic devices. They realized that based on the properties of these compounds they could be extracted from e-waste, then combined at high temperatures, even up to 2,732 F, thereby in the process generating silicon carbide nanowires which can then be processed further to create a durable, new hybrid material that is ideal for protecting metal surfaces.
These technique is innovative and a game changer. This could reduce the number of e-waste that end up in landfills and make it profitable for recycling plants to go into recycling larger amounts of e-waste. Imagine, the typical electronic device like a laptop and a TV screen contains lots of potentially valuable substances that could be used to modify the performance of other materials or used to manufacture new reliable materials. That is what this innovation makes possible. Also, the process, which the researchers have called material microsurgery, could be used to recover a large amount of copper annually for use in industries such as electronic devices, industrial, transportation, and consumer products.
Imagine the number of jobs that could be created in the recycling industry if e-waste was taken out of the ecosystem daily. Imagine what benefits it would bring to our environment not to have to dispose of these devices in landfills where they could percolate back to our water cycle or food.
These material microsurgery technique could also be used to create durable, new hybrid materials that could be used to protect metal surfaces. Yes, and it has been tested. During laboratory experiments it was discovered that the hybrid materials when fixed to steel remain firmly entrenched and when the steel is struck with a nanoscale indenter the hybrid layer does not get detached from the steel but remains firm, showing no signs of cracking or chipping. Further, it was seen to increase the hardness of steel by about 125%.
The potential benefits of this small-scale microrecycling strategy is very high. Thanks to the innovation of these two researchers, we could have a cleaner environment free from e-wastes and making sure more electronic products are not disposed of improperly.
I included this innovation in my blog because of its high potential benefit to mankind. I think this is a problem solved and worthy of being acclaimed.
Materials for this post were taken from a press release by the American Chemical Society, ACS.
It is proven already that ship recycling must be done to help water bodies and the environment. We should stop disposing of the vessels and ships into the sea.
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