In the realm of quantum physics, the intersection of strong field physics and quantum optics has given rise to a fascinating area of research known as strong field quantum optics. Recent studies have delved into the interactions between non-classical light sources and matter, shedding light on the previously unexplored impact of photon distributions on photoemission
Physics
Soft devices, such as agile flexible robots and microscopic capsules for drug delivery, could be on the brink of a major performance boost thanks to a breakthrough microscopic phenomenon uncovered by physicists at Virginia Tech. In a recent paper published in Physical Review Letters, doctoral candidate Chinmay Katke, assistant professor C. Nadir Kaplan, and co-author
The University of Bristol researchers have achieved a significant milestone in the field of quantum technology. By incorporating the world’s smallest quantum light detector onto a silicon chip, they have taken a giant leap towards advancing quantum technologies using light. The groundbreaking paper, titled “A Bi-CMOS electronic photonic integrated circuit quantum light detector,” was recently
The Venus flower basket sponge is a fascinating creature that has captured the attention of researchers due to its delicate glass-like lattice outer skeleton. This ancient animal that lives in the deep sea has a remarkable ability to filter feed using only the faint ambient currents of the ocean depths, without the need for pumping.
Majorana particles, named after an Italian theoretical physicist, are a type of complex quasiparticles that have the potential to revolutionize quantum computing. These particles, which fall into the category of emergent particles, can exist in certain types of superconductors and in a quantum state of matter known as a spin liquid. The ability of Majoranas
Quantum physics and quantum chemistry have long relied on stochastic methods like Monte Carlo simulations to study strongly interacting systems. However, these methods face challenges when sign oscillations occur, leading to inaccurate results. A recent breakthrough by an international team of researchers from Germany, Turkey, the U.S., China, South Korea, and France introduces the new
A groundbreaking study conducted by researchers at the University of Illinois Urbana-Champaign has redefined the way diffusion is understood and calculated in multicomponent alloys. By introducing the concept of “kinosons” as individual contributions to diffusion, the team has harnessed the power of machine learning to transform the traditional approach to modeling. Published in the prestigious
The quest to uncover the mystery of dark matter has led scientists to observe how it influences the motion of stars and galaxies. Scientists hypothesize that dark matter may be composed of particles, prompting the creation of elaborate experiments to search for these elusive entities. These experiments, some of the largest and most sensitive ever
A recent groundbreaking discovery by a research team at the University of California, Irvine has shed light on a previously unknown method of how light interacts with matter. This finding has the potential to revolutionize various technological advancements such as solar power systems, light-emitting diodes, semiconductor lasers, and more. The researchers found that photons can
The realm of chemical reactions is a complex one, involving multiple dynamic processes that impact both the electrons and the nucleus of the atoms involved. One of the most intriguing challenges in the field of chemistry is the detection and analysis of radiation-less relaxation processes known as conical intersections. These processes are crucial for understanding
In the realm of astrophysics, X-ray bursts (XRBs) play a crucial role in informing our understanding of supernovae nucleosynthesis. These violent explosions occur on the surface of a neutron star as it interacts with material from a companion star. During this process, thermonuclear reactions take place due to increasing temperatures and densities on the neutron
The field of quantum computing is rapidly evolving, with researchers from the University of Basel and the NCCR SPIN making significant strides in achieving controllable interactions between two hole spin qubits in a conventional silicon transistor. This breakthrough opens up new possibilities for integrating millions of qubits on a single chip using mature manufacturing processes.
In a groundbreaking development, researchers at the University of Portsmouth have introduced a quantum sensing scheme that pushes the boundaries of quantum sensitivity. This innovative technique focuses on measuring the transverse displacement between two interfering photons, offering a level of precision that was previously unattainable. One of the most promising applications of this new technology
Spin information of an electron, known as a pure spin current, is a key element in the development of spintronic devices for data storage, communication, and computing. Researchers from North Carolina State University and the University of Pittsburgh recently conducted a study to investigate how this spin information moves through chiral materials. The study revealed
Dark matter, comprising approximately 80% of the matter in the universe, is a mysterious substance that does not interact with light and thus cannot be directly observed. Despite its elusive nature, astrophysicists are constantly exploring new methods to detect and study dark matter to gain a better understanding of its composition and implications for the