The captivating world of skateboarding intertwines art and physics, particularly in the context of performing tricks on a half-pipe. Recent research from a collaborative team at ETH Zürich, alongside notable institutions in Japan, has opened new avenues in understanding the dynamics of skating through the lens of advanced mathematics. Their compelling investigation culminated in a
Physics
The quest for efficient and compact green laser sources has long posed a significant challenge within the field of photonics. Despite impressive advancements in the development of lasers that emit red and blue light, the domain of yellow and green wavelengths has remained largely untapped. This gap—often referred to as the “green gap”—represents a substantial
In a remarkable leap for precision measurement technologies, researchers from the Neutral Atom Optical Clocks Group at the National Institute of Standards and Technology (NIST), in collaboration with the University of Colorado and Pennsylvania State University, have unveiled a novel sub-recoil Sisyphus cooling technique. This innovative approach, discussed in a recent article published in Physical
The quest to uncover the underlying principles governing the cosmos has propelled researchers into the intricate realms of theoretical physics. Among the frontiers explored are concepts such as string theory, loop quantum gravity, and quantum geometry. A pivotal revelation emerging from this exploration is the generalized uncertainty principle (GUP), a theory that challenges classical notions
Quantum technology has witnessed monumental advancements in recent years, particularly in the realms of quantum computing, simulation, and sensing. A groundbreaking study by the Institute for Molecular Science has made significant strides in this area by exploring quantum entanglement in ultrafast quantum simulators that utilize Rydberg atoms. This research, published in *Physical Review Letters* on
In the continually evolving field of quantum computing, researchers are on the lookout for novel materials and mechanisms that could lead to practical implementations of fault-tolerant quantum systems. A recent breakthrough has emerged from a collaborative research effort that unveiled the world’s first multiple Majorana zero modes (MZMs) situated within a single vortex of the
The quantum domain offers an intriguing playground for scientists, where fascinating states of matter can arise from the interplay of various quantum states. These phenomena, which are often imperceptible in classical systems, enable the creation of macroscopic states featuring unusual quantum excitations unique to their specific configurations. Researchers are now exploring the frontiers of this
Moiré superlattices, formed by precisely aligning two layers of two-dimensional materials at a small twist angle, have captivated the attention of physicists due to the vast array of unexplored physical phenomena these structures can reveal. The unique geometrical and electronic characteristics of moiré materials allow for the emergence of exotic phases of matter, which are