Molecular-dynamics simulations map shell formation in 3D ion Coulomb crystals and compute rotational energy barriers between concentric shells, revealing strong dependence on ion number and trap geometry with pinned, stick-slip, and smooth-sliding regimes.
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Phase-locked phonon laser in levitated nanoparticles reduces force noise to 4.0(3)×10^{-22} N/√Hz, achieves 12,500 s coherence, and delivers 8(4)×10^{-24} N resolution.
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Shell formation and two-dimensional nanofriction in three-dimensional ion Coulomb crystals
Molecular-dynamics simulations map shell formation in 3D ion Coulomb crystals and compute rotational energy barriers between concentric shells, revealing strong dependence on ion number and trap geometry with pinned, stick-slip, and smooth-sliding regimes.
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Phase-locked phonon laser enhanced ultra-weak force measurement
Phase-locked phonon laser in levitated nanoparticles reduces force noise to 4.0(3)×10^{-22} N/√Hz, achieves 12,500 s coherence, and delivers 8(4)×10^{-24} N resolution.