Recent advances in quantum technologies are rapidly emerging as powerful tools for pushing the boundaries of high-energy physics (HEP), offering innovative paradigms for simulating quantum field theories, analyzing high-energy processes, and extracting physical observables from complex data.
Cutting-Edge Development:
These cutting-edge developments, encompassing quantum computing, simulation, and sensing, hold the promise to unlock fundamental insights into the nature of matter and interactions in regimes that are classically intractable, revolutionizing how we address long-standing challenges in particle physics.
This topical collection in Communications Physics aims to highlight recent progress in the application of quantum technologies and computing for HEP, bringing together contributions from quantum simulation, quantum algorithms, and quantum sensing tailored to the challenges of particle physics.
We invite original articles, reviews, and perspectives that explore innovative approaches, new theoretical insights, and computational advancements in the field.
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The collection is structured into three main sections:
1. Quantum Algorithms for HEP
This section focuses on developments in quantum information science and algorithm design tailored to HEP, particularly those not based on direct quantum simulation of physical systems. Topics include:
– Quantum information and entanglement in HEP
– Quantum algorithms in perturbative calculations and Monte Carlo methods
– Quantum simulations of scattering processes and hadronic structure
– Quantum algorithms for data analysis and generation in HEP
2. Quantum Simulation for HEP
This section highlights efforts to simulate quantum field theories and related phenomena using quantum devices or hybrid workflows. Topics include:
– Quantum simulation of quantum field theories, including real-time dynamics and nonperturbative phenomena
– Lattice gauge theory on quantum processors
– Hybrid classical-quantum approaches for field-theoretic calculations
3. Quantum sensing for particle detection and protocols in HEP
This section addresses the role of quantum sensing in advancing particle detection and experimental protocols, bridging quantum technologies with HEP instrumentation. Topics include:
– Quantum sensors for precision measurements in particle detectors.
– Quantum metrology for enhancing sensitivity to rare events.
– Protocols for integrating quantum sensing with HEP experiments.
– Theoretical and experimental advancements in quantum-enhanced detection techniques.
By gathering cutting-edge contributions in these areas, this collection aims to foster collaboration between the quantum computing and high-energy physics communities, accelerating progress toward quantum-enhanced approaches to fundamental physics.
Quantum technologies are a diverse field that leverages quantum mechanics, the physics of subatomic particles, to develop new technological capabilities.
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