Aug 07, 2024 |
(Nanowerk News) We are constantly surrounded by electromagnetic waves such as Wi-Fi and Bluetooth signals. What if we could turn the unused excess into usable energy? Researchers at Tohoku University, the National University of Singapore, and the University of Messina developed a novel technology to efficiently harvest ambient low-power radiofrequency (RF) signals into direct-current (DC) power. This ‘rectifier’ technology can be easily integrated into energy harvesting modules to power electronic devices and sensors, enabling battery-free operation.
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The results were published in Nature Electronics (“Nanoscale spin rectifiers for harvesting ambient radiofrequency energy”).
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Schematic illustration of a wireless network with energy-harvesting modules. RF signals that are unused by electronic gadgets and would otherwise go to waste are used to generate usable DC power to drive sensors and devices. (Image: Shunsuke Fukami & Hyunsoo Yang)
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Collecting and then converting ambient energy sources into usable energy is referred to as “harvesting.” Small devices can harvest the energy, which can reduce battery dependency, extend device lifetimes, and minimize the environmental impact. Instead of having to physically travel to devices in remote regions to constantly replace batteries, the device can be powered remotely by ambient energy sources such as everyday RF wireless signals.
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The downside of this method is that the source of the signal typically has to be in close proximity to the electronic device in question. Existing technologies, such as the Schottky diode, face challenges in terms of low RF-to-DC conversion efficiency for faint ambient RF signals (typically less than -20 dBm).
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To address these challenges, the research team has developed a compact and sensitive rectifier technology that uses a nanoscale spin-rectifier (SR) to convert ambient wireless RF signals that are less than -20 dBm to a DC voltage. The SR consists of a nanoscale magnetic tunnel junction made of CoFeB/MgO, that is used in a nonvolatile memory technology.
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The team optimized the SR devices, taking particular attention to the material’s magnetic anisotropy, device geometry, and tunneling barrier properties. Then, the RF-to-DC conversion performance was tested for two configurations: 1) a single SR-based rectenna operational between -62 dBm and -20 dBm, and 2) an array of 10 SRs in series. Integrating the SR-array into an energy harvesting module, they successfully powered a commercial temperature sensor at -27 dBm.
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(a) Schematic of the spin rectifier device (magnetic tunnel junction) and its scanning electron microscopy image. (b) Demonstration of energy harvesting. The generated voltage output by an array of spin rectifiers is connected across a capacitor to a DC-to-DC booster converter. The amplified voltage output by the converter powers the temperature sensor. The multimeter displays the output voltage of the spin rectifier array (24.1 mV) and the temperature sensor displays the room temperature (23.4 °C). (Image: Shunsuke Fukami & Hyunsoo Yang)
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The researchers are now exploring the integration of an on-chip antenna to improve the efficiency and compactness. The team is also developing series-parallel connections to tune impedance in large arrays of SRs, utilizing on-chip interconnects to connect individual SRs. This approach aims to improve how RF power is harvested. The study of this technology may lead to the adoption of a self-sustaining, green alternative energy choice that could solve many issues in the future.
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