A simple way to harvest more 'blue energy' from waves

2024-04-03

As any surfer will tell you, waves pack a powerful punch. Now, we are one step closer to capturing the energy behind the ocean's constant ebb and flow with an improved 'blue energy' harvesting device. Researchers report that simply repositioning the electrode -- from the center of a see-sawing liquid-filled tube to the end where the water crashes with the most force -- dramatically increased the amount of wave energy that could be harvested. As any surfer will tell you, waves pack a powerful punch. Now, we are one step closer to capturing the energy behind the ocean's constant ebb and flow with an improved "blue energy" harvesting device. Researchers report in ACS Energy Letters that simply repositioning the electrode -- from the center of a see-sawing liquid-filled tube to the end where the water crashes with the most force -- dramatically increased the amount of wave energy that could be harvested. The tube-shaped wave-energy harvesting device improved upon by the researchers is called a liquid-solid triboelectric nanogenerator (TENG). The TENG converts mechanical energy into electricity as water sloshes back and forth against the inside of the tube. One reason these devices aren't yet practical for large-scale applications is their low energy output. Guozhang Dai, Kai Yin, Junliang Yan and colleagues aimed to increase a liquid-solid TENG's energy harvesting ability by optimizing the location of the energy-collecting electrode. The researchers used 16-inch clear plastic tubes to create two TENGs. Inside the first device, they placed a copper foil electrode at the center of the tube -- the usual location in conventional liquid-solid TENGs. For the new design, they inserted a copper foil electrode at one end of the tube. The researchers then filled the tubes a quarter of the way with water and sealed the ends. A wire connected the electrodes to an external circuit. Placing both devices on a benchtop rocker moved water back and forth within the tubes and generated electrical currents by converting mechanical energy -- the friction from water hitting or sliding against the electrodes -- into electricity. Compared to the conventional design, the researchers found that the optimized design increased the device's conversion of mechanical energy to electrical current 2.4 times. In another experiment, the optimized TENG blinked an array of 35 LEDs on and off as water entered the section of the tube covered by the electrode and then flowed away, respectively. The researchers say these demonstrations lay the foundation for larger scale blue-energy harvesting from ocean waves and show their device's potential for other applications like wireless underwater signaling communications. The authors acknowledge funding from the National Natural Science Foundation of China and the National Key Research and Development Program of China, and acknowledge computing resources from the High Performance Computing Center of Central South University.

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