Since the advent of the laser in the 1960s, laser spectroscopy has revolutionized the study of atoms and molecules, providing insights into their intricate structures and dynamic behaviors. With advancements in laser technology, the capabilities of laser spectroscopy have been significantly enhanced, leading to breakthrough discoveries in various fields of science. One of the main
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Quantum computers are on the verge of revolutionizing information processing, with the potential to outperform conventional computers in various applications such as machine learning and optimization. However, the deployment of quantum computers on a large scale is hindered by their sensitivity to noise, which leads to errors in computations. One of the techniques developed to
Chemistry has always been a field that relies heavily on precise analysis and prediction. Over the years, chemists have used various methods to determine the structure of small molecules, with one common technique being the use of x-ray crystallography. However, this process has its limitations, especially when it comes to predicting the phase of x-rays
Quantum sensing technology has taken a groundbreaking step forward with the development of a new 2D quantum sensing chip using hexagonal boron nitride (hBN) by researchers at TMOS, the ARC Center of Excellence for Transformative Meta-Optical Systems, and RMIT University. This innovative sensor has the ability to detect temperature anomalies and magnetic fields in any
In the world of solar cells and light-emitting diodes (LEDs), the battle against exciton-exciton annihilation is intense. This phenomenon, which leads to the loss of energy and decreased efficiency in these systems, is a major challenge that researchers are working to overcome. Controlling this annihilation process is crucial for improving the performance of optoelectronic devices.
When we delve into the world of atoms and molecules, we encounter a complex quantum system where positively charged nuclei are surrounded by negatively charged electrons. The interactions between these electrons of multiple atoms when they come together to form a molecule are incredibly intricate. This complexity has made the computer simulation of molecules one
The universe, as we know it, may not be as stable as it appears. Despite surviving for an astounding 13.7 billion years, recent experiments and research suggest that we are treading on thin ice, all due to the precarious nature of a fundamental particle known as the Higgs boson. The Higgs boson plays a crucial