- Engineers have developed a groundbreaking method to extract renewable energy directly from the atmosphere, utilizing materials with nanopores smaller than 100 nanometers in diameter.
- The innovative technology, named the “generic Air-gen effect,” taps into the electricity generated by microscopic water droplets in humid air, creating a small-scale, predictable cloud that continuously produces harvestable electricity.
- Unlike previous air energy harvesters that relied on specific bacterium-generated protein nanowires, the generic Air-gen effect can be achieved with a variety of materials, such as cellulose, silk protein, or graphene oxide.
- The device is still in the early stages, demonstrating a spontaneous voltage output of 260 millivolts with a cellulose film. Researchers aim to scale up the technology by stacking thin films and adapting materials for different environments.
- The generic Air-gen effect holds vast possibilities, offering potential applications in various settings, from rainforest environments to arid regions, and could pave the way for widespread clean electricity generation.
In a remarkable breakthrough, engineers have showcased a method that could revolutionize the extraction of renewable energy directly from the atmosphere. The technology, named the “generic Air-gen effect,” capitalizes on materials featuring nanopores smaller than 100 nanometers in diameter. Although not yet ready for practical use, this innovation holds the promise of overcoming limitations observed in existing energy harvesters.
Led by engineer Xiaomeng Liu at the University of Massachusetts Amherst, the research team has identified that almost any material can be employed to create a device capable of continuously harvesting energy from humid air. The key requirement is the presence of nanopores, which are minute cavities with diameters around a thousandth of a human hair’s width.
The “generic Air-gen effect” functions by harnessing the electricity generated by microscopic water droplets present in humid air. Engineer Jun Yao highlights the analogy to natural clouds, where water droplets contain charges that, under the right conditions, can produce lightning. The researchers aim to create a human-built, small-scale cloud that predictably and continuously produces harvestable electricity.
Previously, the team developed an air energy harvester relying on protein nanowires produced by the bacterium Geobacter sulfurreducens. However, the latest breakthrough reveals that the bacterium is not a necessity. The generic Air-gen effect is, as Yao explains, a universal capability that any material possessing the required nanopores can exhibit.
The generic Air-gen device is constructed from a thin film of materials such as cellulose, silk protein, or graphene oxide. Water molecules easily enter the nanopores, moving from the top to the bottom of the film. As they travel, collisions with the sides of the pores generate a charge in the material, resulting in an imbalance between the two sides similar to the charge dynamics observed in lightning-producing clouds.
Despite being in the early stages, the cellulose film tested demonstrated a spontaneous voltage output of 260 millivolts in the ambient environment. Although insufficient for powering devices like mobile phones, the researchers anticipate scaling up the technology by stacking thin films. Additionally, the adaptability of different materials opens the door to creating harvesters tailored for specific environments, such as rainforests or arid regions.
The research, published in Advanced Materials, marks a significant stride towards clean electricity generation from the atmosphere. Liu expresses excitement about the wide-ranging possibilities, emphasizing that the breakthrough is opening doors for harvesting clean electricity from thin air. Further testing in diverse environments and efforts to scale up the devices are the next crucial steps in bringing this transformative technology to practical applications.