All articles tagged with #photonic crystals
Peacock feathers can emit laser light when dyed multiple times, representing the first known biolaser cavity in the animal kingdom, with their iridescent colors arising from natural photonic crystal structures that could inspire new materials and technologies.
Researchers have developed photonic space-time crystals, which enhance light interaction and amplification, potentially revolutionizing optical information processing. These advanced materials, structured in three spatial dimensions and changing over time, allow precise control over light's behavior. The study, involving institutions like Karlsruhe Institute of Technology and Aalto University, demonstrates how these four-dimensional materials can be applied in technologies such as wireless communication and lasers. The findings, published in Nature Photonics, highlight the potential for these materials to amplify light across various frequencies, paving the way for new applications in optical and other physical systems.
Fragments of ancient Roman glass vessels unearthed at archaeological sites have been found to possess photonic crystals, nanostructures that produce unique optical effects. The molecular structure of these glass shards rearranges over thousands of years, resulting in the formation of photonic crystals. The crystals are believed to have grown on the glass surface due to exposure to environmental conditions and changes in pH and groundwater. The unique atomic and material properties of these glass shards could potentially be replicated and accelerated in the lab, offering new ways of growing optical materials.
Scientists have manipulated light to behave as if influenced by gravity using distorted photonic crystals, opening up possibilities for advancements in optics and materials science. This breakthrough could also have implications for the development of 6G communication. By introducing lattice distortion to photonic crystals, researchers were able to manipulate the photonic band structure, resulting in a curved beam trajectory similar to light passing by a massive celestial body. The experiment successfully demonstrated the deflection of terahertz waves, showcasing the potential for in-plane beam steering within the terahertz range, which could be utilized in 6G communication.
Scientists have successfully manipulated photonic crystals to create a pseudogravity effect, bending light similar to how it would be affected by a gravitational field. By distorting the crystal's structure, the researchers were able to alter the path of light, potentially opening up new possibilities for optics and communications technology. The findings also have implications for the study of gravity and could contribute to the field of graviton physics.
Engineers at Tohoku University have successfully created a form of pseudogravity in photonic crystals that can bend light, similar to real gravity. By deforming crystals in the lower energy region, they were able to manipulate and control the behavior of light, opening up possibilities for advanced communication technologies like 6G. The breakthrough could also have applications in optics and materials science, as well as pave the way for new studies in graviton physics.
Researchers have successfully manipulated the behavior of light in photonic crystals to mimic the effects of gravity, resulting in a curved beam trajectory. By introducing lattice distortion to the crystals, the photonic band structure was modified, causing the light to bend as if influenced by a massive celestial body. This breakthrough has significant implications for optics, materials science, and the development of 6G communications.
A shard of ancient Roman glass, known as the "wow glass," has been found to possess a rare golden-hued patina with unique optical properties. The patina is the result of the corrosion process slowly restructuring the glass to form photonic crystals, which create iridescent colors. Photonic crystals are tunable materials that can block certain wavelengths of light while allowing others to pass through. Scientists are studying natural structural coloration to develop commercial applications, such as plant-based films that cool when exposed to sunlight and chameleon-like films that change color when stretched. The shard was discovered near the ancient city of Aquileia, Italy, which was once a thriving center for trade and glass processing.