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Category: materials – Page 2

A collaborative team of researchers from the Max Planck Institute for Structure and Dynamics of Matter (MPSD), Nanjing University, Songshan Lake Materials Laboratory (SLAB), and international partners has introduced a new method to regulate exotic electronic states in two-dimensional materials.

Building on the foundations laid by their previous work on twisted van der Waals materials, the team of physicists has now discovered a novel way to manipulate correlated electronic states in twisted double bilayer tungsten diselenide (TDB-WSe₂). This breakthrough offers new possibilities for developing advanced quantum materials and devices.

By precisely twisting two bilayers of WSe₂ near a 60-degree angle and applying a perpendicular electric field, the researchers have achieved control over the interaction between two distinct electronic bands, known as the K-valley and Γ-valley bands. This tuning has led to the observation of a “valley charge-transfer insulator”—an exotic state where electron movement is highly correlated, and electrical conductivity is suppressed.

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Superconductivity is a widely sought after material property, which entails an electrical resistance of zero below a specific critical temperature. So far, it has been observed in various materials, including recently in so-called multilayer graphene allotropes (i.e., materials that consist of several layers of a hexagonal carbon lattice).

Recent studies found that when bilayer graphene is placed on a WSe2 (tungsten-diselenide) substrate, its superconducting phase is enhanced. This results in a greater charge carrier density and higher (i.e., the temperature at which a material becomes a superconductor).

Researchers at University of California at Santa Barbara and California Institute of Technology have carried out a study aimed at further investigating this enhancement in the graphite allotrope Bernal bilayer graphene. Their paper, published in Nature Physics, reports the observation of two distinct superconducting states in this material, challenging current models of electron pairing in graphite allotropes.

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The limitations of two-dimensional (2D) displays in representing the depth of the three-dimensional (3D) world have prompted researchers to explore alternatives that offer a more immersive experience. Volumetric displays (VDs), which generate 3D images using volumetric pixels (voxels), represent a breakthrough in this pursuit.

Unlike or stereoscopic displays, VDs deliver a natural visual experience without requiring head-mounted devices or complex visual tricks. Among these, laser-based VDs stand out for their , high contrast ratios, and wide color gamut. However, the commercial viability of such systems has been hindered by challenges such as low resolution, ghost voxels, and the absence of tunable, full-color emission in a single material.

To address these limitations, researchers from Yildiz Technical University, led by Miray Çelikbilek Ersundu, and Ali Erçin Ersundu, have developed innovative RE3+-doped monolithic glasses (RE = Ho, Tm, Nd, Yb) capable of tunable full-color emission under near-infrared (NIR) laser excitation.

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Soft viscoelastic solids are flexible materials that can return to their original shape after being stretched. Due to the unique properties driving their deformation, these materials can sometimes behave and change shape in unexpected ways.

Researchers at Princeton University carried out a study closely investigating the behavior of these materials when they are squeezed through narrow spaces. Their findings, published in Physical Review Letters, show that this extrusion of soft solids through confined geometries results in the formation of instabilities at their surface, characterized by a grooved pattern that deepens over time.

“Soft solids are viscoelastic materials, which have both fluid-like and solid-like features,” explained Prof. Howard Stone, senior author of the paper.

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Researchers have found that a two-dimensional carbon material is tougher than graphene and resists cracking—even the strongest crack under pressure, a problem materials scientists have long been grappling with. For instance, carbon-derived materials like graphene are among the strongest on Earth, but once established, cracks propagate rapidly through them, making them prone to sudden fracture.

A new carbon material known as monolayer amorphous carbon (MAC) however, is both strong and tough. In fact, MAC—which was recently synthesized by the group of Barbaros Özyilmaz at the National University of Singapore (NUS)—is eight times tougher than graphene, according to a new study from Rice University scientists and collaborators, published in the journal Matter.

Like graphene, MAC is also a 2D or single atom-thick material. But unlike graphene where atoms are arranged in an ordered (crystalline) , MAC is a that incorporates both crystalline and amorphous regions. It is this composite structure that gives MAC its characteristic toughness, suggesting that a composite design approach could be a productive way to make 2D materials less brittle.

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A collaborative study published in Nature reveals an innovative strategy to enhance energy storage in antiferroelectric materials.

The study, conducted by researchers from the Hefei Institutes of Physical Science of the Chinese Academy of Sciences, Tsinghua University, Songshan Lake Materials Laboratory, and the University of Wollongong, introduces the antipolar frustration strategy, which significantly improves the performance of dielectric capacitors that are crucial for high-power devices requiring fast charge and discharge rates.

Antiferroelectrics, which feature an antiparallel configuration, are emerging as promising materials for due to their phase transition from antiferroelectric to ferroelectric under an . This transition provides high polarization strength and near-zero remanent polarization, ideal for energy storage.

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Once thought impossible, quasicrystals revealed a hidden order that challenges our understanding of materials.

Their structure follows rules from higher dimensions, influencing both their mechanical and topological properties. Recent research has uncovered bizarre time-related behaviors in these crystals, suggesting deeper physical principles at play.

A Revolutionary Discovery in Crystallography.

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