An increase in both available computational power and the number of appropriate quantum engines, or code, has led to the widespread use of density-functional theory (DFT) to compute system properties at the atomic level in both academia and industry. It remains, nevertheless, a complicated task.
Researchers from National Taiwan Normal University and Kyushu University have come up with a new device that requires only a single semiconductor called perovskite to concurrently store and visually transmit data.
For the first time, astronomers have successfully determined the electron and proton components of cosmic rays in a supernova remnant. Novel imaging analysis of radio, X-ray, and gamma-ray radiation showed that at least 70% of the very-high-energy gamma rays discharged from cosmic rays are caused by relativistic protons.
The quantum computing market is projected to reach $65 billion by 2030, a hot topic for investors and scientists alike because of its potential to solve incomprehensibly complex problems.
Tomorrow's quantum sensors, computers and networks will share, process and secure exponentially more information -; starting with the scientific data that will make this wave of the future possible.
Scientists from the Centre for Astrophysics characterized wandering black holes using the ROMULUS simulations and identified that in the early universe, these black holes contained most of the mass.
A new technique developed by scientists at North Carolina State University (NC State) allows quantum computers to quantify the thermodynamic properties of systems by evaluating the zeros of the partition function.
'Growing' electronic components directly onto a semiconductor block avoids messy, noisy oxidation scattering that slows and impedes electronic operation.
Scientists from SANKEN at Osaka University demonstrated the readout of spin-polarized multielectron states composed of three or four electrons on a semiconductor quantum dot.
Quantum gases are ideal for assessing the microscopic consequences of interactions in matter. Now, researchers can accurately control each particle in extremely cooled gas clouds in the laboratory, unraveling phenomena that cannot be seen in the day-to-day world.
The 21st century is an era of quantum science. Quantum mechanics originated in the early 20th century and supported the development of unique technologies such as quantum communication, quantum information, quantum metrology, quantum sensing, and quantum imaging.
Twenty-five years ago, an enigmatic signal was discovered while analyzing the polarization of sunlight with a new instrument, the Zurich Imaging Polarimeter.
‘Growing’ electronic components directly onto a semiconductor block avoids messy, noisy oxidation scattering that slows and impedes electronic operation.
Igor Mazin, Professor of Practice for Advanced Studies in Theoretical Physics, Quantum Science and Engineering Center, Physics and Astronomy, will receive funding for a project in which Mason researchers will collaborate with SUNY Binghamton researchers to develop a framework for predicting novel ambient-pressure high-temperature superconductors using first-principles calculations and machine learning.
In a new publication from Opto-Electronic Advances, researchers led by Professor Han Zhang from Shenzhen University, Shenzhen, China, consider whether boron quantum dots surpass the graphene in thermal properties.