A quark-diquark formalism extracts effective masses and couplings from known heavy baryon data to predict spectra across singly, doubly, and triply heavy sectors with two scenarios and a mass-dependent binding term.
CEPC Conceptual Design Report: Volume 1 - Accelerator
5 Pith papers cite this work. Polarity classification is still indexing.
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Pith papers citing it
abstract
The Circular Electron Positron Collider (CEPC) is a large international scientific project initiated and hosted by China. It is located in a 100-km circumference underground tunnel. The accelerator complex consists of a linear accelerator (Linac), a damping ring (DR), the Booster, the Collider and several transport lines. In the tunnel, space is reserved for a future pp collider, SPPC. The CEPC center-of-mass energy is 240 GeV, and at that collision energy will serve as a Higgs factory. The design also allows operation at 91 GeV for a Z factory and at 160 GeV for a W factory. The heart of the CEPC is a double-ring collider. It has two interaction points where are located large detectors. The Booster is in the same tunnel above the Collider. It is a synchrotron with a 10 GeV injection energy and extraction energy equal to the beam collision energy. The repetition cycle is 10 seconds. Top-up injection will be used to maintain constant luminosity. The 10 GeV Linac, injector to the Booster, built at ground level, accelerates both electrons and positrons. A 1.1 GeV damping ring reduces the positron emittance. Transport lines made of permanent magnets connect the Linac to the Booster. In addition to particle physics, the Collider can operate simultaneously as a powerful synchrotron radiation (SR) light source. It will extend the usable SR spectrum into an unprecedented energy and brightness range. Two gamma-ray beamlines are included in the design. Prior to the construction will be a five-year R&D period (2018-2022). Construction is expected to start in ~2022 and be completed in ~2030. This report is a summary of work accomplished during the past several years by hundreds of scientists and engineers at home and abroad. The current volume, Volume I, is on the accelerators. A separate volume, Volume II, will be on physics and the detectors.
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background 3representative citing papers
Alternative lattice for STCF achieves 1e35 cm^{-2}s^{-1} luminosity and 600 s Touschek lifetime at 2 GeV via global parameter optimization, compact IR with crab-waist, and nonlinear refinement.
Space-based circular colliders with radii of 10^3 to 10^5 km could reach PeV-EeV energies for grand unification by using orbital vacuum, cooling, and power infrastructure.
Benchmarks in the 2HDMS model with light to heavy dark matter masses are identified under all constraints and shown to have better discovery prospects at future lepton colliders than at the HL-LHC via cut-and-count analyses.
A review summarizing advancements in probing quantum entanglement and Bell inequalities using high-energy particle colliders.
citing papers explorer
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Quark-diquark effective mass formalism for heavy baryon spectroscopy
A quark-diquark formalism extracts effective masses and couplings from known heavy baryon data to predict spectra across singly, doubly, and triply heavy sectors with two scenarios and a mass-dependent binding term.
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Alternative Lattice Design for the STCF Collider Rings
Alternative lattice for STCF achieves 1e35 cm^{-2}s^{-1} luminosity and 600 s Touschek lifetime at 2 GeV via global parameter optimization, compact IR with crab-waist, and nonlinear refinement.
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The Case for Space-Based Particle Colliders: Orbital Infrastructure as a Path to Grand Unification Energy Scales
Space-based circular colliders with radii of 10^3 to 10^5 km could reach PeV-EeV energies for grand unification by using orbital vacuum, cooling, and power infrastructure.
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Search for Dark Matter in 2HDMS at LHC and future Lepton Colliders
Benchmarks in the 2HDMS model with light to heavy dark matter masses are identified under all constraints and shown to have better discovery prospects at future lepton colliders than at the HL-LHC via cut-and-count analyses.
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Particle Collisions & Quantum Entanglement in High-Energy Collisions
A review summarizing advancements in probing quantum entanglement and Bell inequalities using high-energy particle colliders.