News

Quantum Model Unlocks New Approach to Single-Photon Detection

To become more pervasive in daily life, quantum technology needs to better detect single particles of light, called photons, carrying quantum information. The problem is that each photon is a very weak signal, making it difficult for measurement devices to efficiently detect them. Purdue University engineers have proposed a new quantum resource that could help design the next generation of single-photon detectors.
See also: Quantum causality
Read More Quantum Model Unlocks New Approach to Single-Photon Detection

In High Temperatures, A New Class of Ceramics Controls Heat Radiation

Manufacturers frequently use coatings to protect the structural stability of engines or power generators operating at high temperatures. Ceramic shields, however, have not been able to adequately address a critical, performance-limiting factor: heat radiation. A new ceramic coating from Purdue University acts as a kind of thermal antenna, using light-matter oscillations, or polaritrons, to control the direction and electromagnetic spectrum of thermal radiation.
Read More In High Temperatures, A New Class of Ceramics Controls Heat Radiation

New Antenna Tech to Equip Ceramic Coatings with Heat Radiation Control

The gas turbines powering aircraft engines rely on ceramic coatings that ensure structural stability at high temperatures. But these coatings don’t control heat radiation, limiting the performance of the engine. Researchers at Purdue University have engineered ceramic “nanotubes” that behave as thermal antennas, offering control over the spectrum and direction of high-temperature heat radiation.
Read More New Antenna Tech to Equip Ceramic Coatings with Heat Radiation Control

Researchers Propose New Topological Phase of Atomic Matter Hosting ‘Photonic Skyrmions

The field of topology or the study of how surfaces behave in different dimensions has profoundly influenced the current understanding of matter. The prime example is the topological insulator, which conducts electricity only on the surface while being completely insulating inside the bulk. Topological insulators behave like a metal, i.e., silver on the surface, but inside, it would behave like glass. These properties are defined using the conductivity or flow of electrons depicting whether there is a highway or a road-block for their motion. One major driver of future applications for topological insulators is in the field of spin-electronic devices since these electrons spin in unison, all aligned with each other while flowing on the surface.
Read More Researchers Propose New Topological Phase of Atomic Matter Hosting ‘Photonic Skyrmions