Color is not the only indicator we have when it comes to understanding our surroundings. Polarization, the way the electric field oscillates as light travels, is a rich source of information that has not been fully utilized in imaging technology until now. While companies have made significant progress in improving color in digital imaging, polarization
Science
Gravity is a fundamental force that governs our everyday lives, yet its true nature remains shrouded in mystery. Scientists have long been puzzled by whether gravity is inherently quantum in nature, as proposed by Einstein, or if it follows classical laws. The interplay between quantum mechanics and gravitational physics poses one of the greatest challenges
Creating heat from fusion reactions is a complex process that requires precise manipulation of plasma, the electrically charged fourth state of matter that dominates the observable universe. Recent advancements in plasma diagnostics offer promising opportunities to enhance fusion reactions in tokamaks, paving the way for more efficient fusion power plants. Scientists at the Princeton Plasma
For many years, physicists have been on a quest to uncover a specific state of thorium atomic nuclei that holds the potential for groundbreaking technological advancements. This elusive state could pave the way for the development of a nuclear clock capable of time measurement with unprecedented precision, surpassing even the most advanced atomic clocks in
Impressionist paintings, known for their vibrant and vivid colors, are facing a common issue – the fading of bright yellow hues. Artists like Claude Monet, Vincent van Gogh, and Pablo Picasso all utilized cadmium sulfide to achieve the striking yellow tones in their masterpieces. However, as time passes, these once luminous yellows are losing their
Whispering-gallery-mode (WGM) resonators have long been utilized for high-resolution optical sensing, enabling the detection of chemical signatures, DNA strands, and single molecules. These microresonators function by confining and concentrating light in a circular path, allowing for the quantification of physical and biochemical characteristics. However, the widespread use of WGM resonators has been hindered by issues
Photonic quantum computers are a cutting-edge technology that harnesses the principles of quantum physics to process information using particles of light, known as photons. These computers have the potential to outperform traditional quantum computers in terms of speed and efficiency, while also enabling the transmission of information over longer distances. Despite their immense promise, photonic
The advancement of technology in the field of solar cells is paving the way for a more sustainable future. One of the latest breakthroughs in this area involves the development of semitransparent photovoltaics that can convert sunlight into electricity without obstructing visible light. This innovation opens up a myriad of possibilities for integrating solar panels
Single-photon emitters (SPEs) are a revolutionary advancement in the field of quantum technology. These tiny structures emit only one photon at a time, making them invaluable for applications such as secure communications and high-resolution imaging. While many materials containing SPEs are impractical for mass manufacturing due to their high cost and integration difficulties, hexagonal boron
Quantum physics has opened up new avenues for exploring the microscopic world of materials, requiring advanced sensing techniques capable of delving into quantum systems. Among these techniques, quantum-gas microscopes have emerged as powerful tools for investigating atomic-level phenomena in quantum gases. In a recent study, researchers at ICFO in Barcelona, Spain, have developed a quantum-gas