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Category: sustainability

Biodegradable sensors attached to plants detect pesticides in 3 minutes

Researchers at the São Carlos Institute of Physics at the University of São Paulo (IFSC-USP) in Brazil, led by Paulo Augusto Raymundo-Pereira, have created biodegradable, “wearable” sensors for plants to monitor their health, including the presence of pesticides. The sensors are made from carbon ink and are screen-printed onto transparent cellulose acetate bioplastics.

The study was published in Biosensors and Bioelectronics: X. The World Economic Forum selected wearable sensor engineering as one of the top ten emerging technologies of 2023 for its potential to improve plant health and increase agricultural productivity.

However, most wearable devices today are made from nonrenewable plastic polymers derived from petroleum and have poor adhesion to uneven, wavy, and curved surfaces.

Researchers solve longstanding problem in measuring semiconductor defects

Researchers at Sandia National Laboratories and Auburn University have developed a new method to more accurately detect atomic-scale defects in electronic materials, an advance that could help improve technologies ranging from electric vehicles to high-power electronics. The study, appearing in the Journal of Applied Physics, addresses a longstanding challenge in understanding what happens at the critical boundary where a semiconductor meets an insulating layer.

At this interface, microscopic defects can trap electrical charge and quietly reduce device performance, even when the device otherwise appears to function normally. These defects can limit efficiency, increase electrical losses, and reduce the performance of advanced semiconductor devices.

Scientists commonly study these defects by comparing how a device responds to slow and fast electrical signals. However, the technique depends on knowing a key device property, the insulator capacitance, with very high accuracy. Even tiny errors can produce misleading results, sometimes making it appear that far more defects exist than are actually present.

Careful crystallization unlocks well-ordered perovskite layers for transistors

Perovskites are a class of materials with a unique crystal structure that suits applications such as fabricating solar cells, light-emitting diodes and transistors. However, molecules in thin layers often cannot arrange themselves properly because the process proceeds too quickly. Now, an international research team led by Tomasz Marszalek from the Max Planck Institute for Polymer Research has developed a new approach to controlling low-cost solution processing, thereby improving the formation of well-ordered perovskite layers and enabling their broader application in optoelectronic devices. Their paper is published in the Journal of the American Chemical Society.

Electronics can be found in almost every device, from smartphones and televisions to washing machines. Field-effect transistors are the main building blocks of electronic circuits, and they ensure that these devices can be easily operated and fully controlled. Perovskites are a new class of semiconductor that could be suitable for transistor applications. They contain various chemical elements, such as organic cations, divalent metal cations, and halide anions. This combination of elements enables the properties of thin perovskite films to be tailored precisely for specific applications.

Currently, their use in transistors is often unsuccessful due to a lack of control over the formation of the thin film, known as nucleation and crystallization. Therefore, researchers are attempting to organize the materials into thin, two-dimensional layers and stabilize them with organic molecules between the inorganic layers in order to control their optoelectronic properties.

How wasted infrared light could boost solar panels, night vision and 3D printing

Researchers at UNSW Sydney have developed a nanoscale device that converts low-energy infrared and red light into higher-energy visible light, a breakthrough that could eventually improve solar panels, sensing technologies, and advanced manufacturing systems.

Published in Nature Photonics, the research addresses a longstanding problem in photonics: how to stop energy from being lost before it can be used.

That mechanism allowed the device to achieve photon conversion efficiencies of 8.2%, among the strongest reported for this type of architecture.

Scientists develop near-invisible solar cells that could turn windows into power generators

Imagine a car whose windows and sunroof can help top up its battery while parked under the sun, or a pair of smart glasses whose lenses can harvest light to power built-in electronics.

Such applications could become more feasible with a new type of ultrathin transparent solar cell developed by scientists from Nanyang Technological University, Singapore (NTU Singapore).

Led by Associate Professor Annalisa Bruno, the NTU researchers created perovskite solar cells that are about 10,000 times thinner than a strand of human hair and around 50 times thinner than conventional perovskite solar cells.

Sustainable chemistry: Iron substitutes noble metals in catalytic reactions

The production of many products used in everyday life and in industry, such as pharmaceuticals, plastics, and coatings, requires chemical catalysts, often expensive noble metals with limited availability. Researchers at the Karlsruhe Institute of Technology (KIT) are now presenting the first air-stable iron compound, which enables the direct use of iron(I) for catalysis and, unlike previous methods, does not require strong reducing agents. A first test yielded active iron catalysts.

The study, “A Simple, Air Stable Single-Ion Source of Iron(I),” is published in the Journal of the American Chemical Society.

Catalysts are required to speed up chemical reactions or even make them possible at all. The catalysts generally used in industry are noble metals, such as rhodium, iridium, or palladium. They are highly effective for many applications, but at the same time expensive and rare.

Engineered proteins store digital files with 30 times density at one-tenth cost

Massive volumes of digital data are generated every day from AI training, big data analytics and smart devices. As conventional hard drives and cloud storage are increasingly constrained by high costs, limited capacity, high power consumption and short lifespans, molecular data storage has emerged as a breakthrough storage alternative.

Researchers at The Hong Kong Polytechnic University (PolyU) have pioneered a method that uses engineered proteins to store digital data and, for the first time, completed the full process from data storage to data retrieval in de novo designed unnatural proteins.

This demonstrates the potential of establishing a protein-based storage framework with sustainability, high storage capacity and high stability, offering a promising solution to the explosive AI-generated growth in data globally.

Prickly pear cacti show promise as the building materials of tomorrow

Researchers from the University of Bath’s Department of Mechanical Engineering have shown that agricultural waste from prickly pear cactus plants could be used as a low-cost, low-carbon reinforcement for construction materials, offering a more sustainable alternative to conventional composites. The research is published in the Journal of Natural Fibers.

Composite materials combine strong reinforcing fibers with a lightweight base material, known as a matrix. Widely used composites like carbon fiber, fiberglass or Kevlar rely on synthetic fibers and energy-intensive manufacturing processes. Their durability also makes them difficult to reuse or recycle at the end of their lifespan. Swapping synthetic fibers with natural alternatives offers a renewable and biodegradable solution.

Matt Hutchins, a researcher in the Department of Mechanical Engineering and lead author of the study, said, “Inside the flat cactus pads is a naturally occurring fiber network. These fibers form a honeycomb-like structure that helps the plant support its own weight and resists bending in strong winds. We’re exploring how to extract these structures and keep them intact, borrowing their natural properties to reinforce bio-based composites.”

Water-based zinc batteries tackle a barrier that has long blocked cheap, stable renewable energy storage

Renewable energy technologies, such as solar cells and wind turbines, are becoming increasingly widespread in many countries worldwide. Reliably storing the electricity produced by these devices, so that it can be used later at times when sunlight or wind are scarce, would further improve their effectiveness as sustainable energy solutions.

A promising solution to store solar and wind energy entails the use of aqueous zinc (Zn) metal batteries. These are low-cost, safe and environmentally friendly batteries that store and release energy, leveraging water-based solutions and Zn anodes.

Despite their potential, Zn batteries have not yet achieved the desired efficiencies and long-term stability. This is because water molecules can break down during their operation and small structures called Zn dendrites form on the surface of zinc electrodes, both of which were found to reduce performance.

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