A research scientist at Lawrence Berkeley National Laboratory has used a remote access to an IBM quantum computer to simulate the process of hadronization, a key phenomenon in particle physics where quarks bind to form composite particles like protons and neutrons. The simulation, conducted using 104 qubits, represents a significant step toward leveraging quantum computing for complex scientific calculations that exceed the capabilities of classical supercomputers. While physical experiments at facilities like the Large Hadron Collider (LHC) at CERN cannot fully capture the intricacies of hadronization due to the rapid nature of the process, quantum simulations could provide deeper insights into the fundamental forces governing matter. The study highlights the potential of quantum computing to advance our understanding of quantum chromodynamics (QCD), the theory behind the strong force that binds quarks and gluons. The research was published in the journal *Physical Review D*.
Tendenz-Einschätzung (Mitte): The article presents a scientific achievement without overt ideological framing. It focuses on technical progress in quantum computing and its applications in particle physics, emphasizing collaboration between institutions and the potential for future discoveries. There is no indication of partisan
Warum diese Bewertungen (Faktentreue 85 · Objektivität 70): The article accurately reports the simulation of hadronization using 104 qubits on IBM's quantum computer, aligning with the primary source document. However, it emphasizes the significance of the achievement without providing detailed technical specifics from the paper, leading to a slightly lower



