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Category: materials

Pounding on the bottom of a glass bottle of ketchup is one of life’s small annoyances. Getting that sweet, red concoction from its solid phase to a liquid takes too long when you’re hungry and could even require messy strategies with a butter knife.

Now a team of scientists has shown that determining the point where the solid transitions to a liquid can be predicted from the properties of the alone. The research has been published in Physical Review Letters.

The new work focuses on yielding, a phenomenon where a solid-like material starts to behave like a liquid. “This behavior occurs constantly all around us, from desserts like custards that smoothly flow onto your spoon to personal care products like toothpaste that are easily squeezed out of tubes but hold their shape on your toothbrush,” Ryan Poling-Skutvik of the University of Rhode Island in the United States told Phys.org.

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Bismuth, a puzzling material in quantum research, has now revealed a surprising twist. Kobe University scientists discovered that its surface properties can obscure its true nature, challenging a foundational assumption in topological material science. For nearly two decades, scientists have puzz

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Ultra clean, air-free measurements reveal a new property of graphene. Graphene is often called a “miracle material” because it is both mechanically extremely strong and highly conductive, making it ideal for many technological applications. Physicists at the University of Vienna, led by Jani Kota

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As the digital world demands greater data storage and faster access times, magnetic memory technologies have emerged as a promising frontier. However, conventional magnetic memory devices have an inherent limitation: they use electric currents to generate the magnetic fields necessary to reverse their stored magnetization, leading to energy losses in the form of heat.

This inefficiency has pushed researchers to explore approaches that could further reduce in magnetic memories while maintaining or even enhancing their performance.

Multiferroic materials, which exhibit both ferroelectric and ferromagnetic properties, have long been considered potential game changers for next-generation memory devices.

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Five years after introducing see-through wood building material, researchers in Sweden have taken it to another level. They found a way to make their composite 100 percent renewable – and more translucent – by infusing wood with a clear bio-plastic made from citrus fruit.

Since it was first introduced in 2016, transparent wood has been developed by researchers at KTH Royal Institute of Technology as one of the most innovative new structural materials for building construction. It lets natural light through and.

The key to making wood into a transparent composite material is to strip out its lignin, the major light-absorbing component in wood. But the empty pores left behind by the absence of lignin need to be filled with something that restores the wood’s strength and allows light to permeate.

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An SMU-led research team has developed a more cost-effective, energy-efficient material called high-entropy oxide (HEO) nanoribbons that can resist heat, corrosion and other harsh conditions better than current materials.

These HEO nanoribbons— featured in the journal Science —can be especially useful in fields like aerospace, energy, and electronics, where materials need to perform well in extreme conditions.

And unlike high entropy materials that have been created in the past, the nanoribbons that SMU’s Amin Salehi-Khojin and his team developed can be 3D-printed or spray-coated at room temperature for manufacturing components or coating surfaces. This makes them more energy-efficient and cost-effective than traditional high-entropy materials, which typically exist as bulk structures and require high-temperature casting.

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Strontium titanate was once used as a diamond substitute in jewelry before less fragile alternatives emerged in the 1970s. Now, researchers have explored some of its more unusual properties, which might someday be useful in quantum materials and microelectronics applications.

Writing in the journal Nature Communications, the team explains how they built an extremely thin, flexible strontium titanate membrane and stretched it, in the process turning on what’s known as a ferroelectric state. In that state, the material generates its own , somewhat similar to how a generates its own magnetic field.

“We applied strain to tune the membrane to a ferroelectric or non-ferroelectric state reversibly and repeatedly,” said Wei-Sheng Lee, a lead scientist at the Department of Energy’s SLAC National Accelerator Laboratory and a principal investigator at the Stanford Institute for Materials and Energy Sciences (SIMES), a joint SLAC-Stanford institute. “This allowed quantitative characterizations of this transition in strontium titanate with unprecedented details.”

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With global population growth accelerating urban expansion, construction activity has reached unprecedented levels—placing immense pressure on both natural resources as well as the environment. A cornerstone of modern-day infrastructure, Ordinary Portland Cement remains the most effective and commonly used soil solidifier despite contributing substantially to global carbon emissions.

At the same time, continues to accumulate in landfills. Addressing both the environmental burden of cement use and the inefficiencies of industrial waste disposal has become an urgent priority.

To tackle these interconnected challenges, scientists from Japan, led by Professor Shinya Inazumi, from the College of Engineering, Shibaura Institute of Technology (SIT), Japan, present a sustainable alternative: a high-performance geopolymer-based soil solidifier developed from Siding Cut Powder (SCP), a construction waste byproduct, and earth silica (ES), sourced from recycled glass.

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