Gravity or gravitational force is the result of a computational process within the universe.
Category: computing
Modern ideas about reality sometimes sound like a wild story. The notion that everything around us might be bits and bytes is easy to brush aside, yet it continues to intrigue many curious minds.
This perspective has led some researchers to wonder if physical forces might be signals of an underlying information system.
According to physicist Melvin M. Vopson of the University of Portsmouth, certain features of gravity may hint at information contained in a universal computational code.
While still evolving, Brain-computer interfaces (BCIs) will soon do much more than just allow users to play games.
Superconducting qubits could be used to build a fault-tolerant quantum computer. But such a device will require millions of components, and various fundamental challenges remain to be addressed. Success will depend on sustained collaboration between industry and academia.
A programmable quantum chip has been developed that generates, manipulates, and launches five-dimensional entangled photons into free-space channels, encoded as optical vortex modes, thus bridging the worlds of integrated and free-space quantum photonics.
A team from the University of Science and Technology of China (USTC) of the Chinese Academy of Sciences (CAS) has resolved a critical challenge in pure-red perovskite light-emitting diodes (PeLEDs) by identifying and addressing the root cause of efficiency loss at high brightness.
Published in Nature, their study introduces a novel material design that enables record-breaking device performance, achieving a peak external quantum efficiency (EQE) of 24.2% and a maximum luminance of 24,600 cd m-2 —the brightest pure-red PeLED reported to date.
Pure-red PeLEDs, crucial for vivid displays and lighting, have long faced a trade-off between efficiency and brightness. While 3D mixed-halide perovskites like CsPbI3-x Brx offer excellent charge transport, their efficiency plummets under high current due to unresolved carrier leakage.
Recent findings from the Dark Energy Spectroscopic Instrument suggest the possibility of new physics that extends beyond the current standard model of cosmology. Using the lab’s new Aurora exascale computing system, the research team conducted high-resolution simulations of the universe’s evoluti
Molding the flow of light—whether confined to localized regions or propagating in free space—remains crucial for modern integrated photonics. The advancement of the multi-channel, programmable optical waveguide and coupler arrays has enabled us to develop photonic integrated circuits (PICs) as a viable alternative to electronic ones, overcoming limitations in processing speed, bandwidth, and efficiency across the optical-to-microwave spectrum.
However, as on-chip complexity grows, we face significant challenges regarding long-term stability and fabrication-induced defects, making operational reliability critical for practical applications.
The increasing demand for high-capacity information processing drives our need for more complex PICs with additional channels. In this context, topological photonics offers promising solutions due to its inherent robustness against defects.
The company became interested in the megasite primarily because of its mix of high-tension electricity transmission lines, natural gas lines, fiber connectivity, on-site power generation and access to water.