EQMD simulations of all AME2020 nuclides are classified by a new BHTU scheme that labels droplet (B=0), bubble (B=1), and toroidal bubble (B=2) morphologies from radial density profiles.
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4 Pith papers cite this work. Polarity classification is still indexing.
years
2026 4verdicts
UNVERDICTED 4representative citing papers
New excitation functions measured for 118Sn(p,n)118Sb, 118Sn(p,2n)117Sb, 118Sn(p,α)115mIn, and 118Sn(p,x)117mSn up to 18 MeV, with first-time data for the alpha and 117mSn channels, showing model discrepancies for composite-particle emission.
Applies Lorentz-boosted form factors via Licht-Pagnamenta and Mitra-Kumari formalisms to link nuclear boosts with cluster configurations and resolve light nuclei charge radius discrepancies.
Relativistic nuclear dissociation in emulsion reveals increasing contributions from 8Be(0+), 9B, and 12C Hoyle state with higher alpha multiplicity, consistent with cluster fusion.
citing papers explorer
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A unified classification-quantification framework for bubble-like nuclei within the extended quantum molecular dynamics model
EQMD simulations of all AME2020 nuclides are classified by a new BHTU scheme that labels droplet (B=0), bubble (B=1), and toroidal bubble (B=2) morphologies from radial density profiles.
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Proton induced reactions on 118Sn target at energies up to 18 MeV
New excitation functions measured for 118Sn(p,n)118Sb, 118Sn(p,2n)117Sb, 118Sn(p,α)115mIn, and 118Sn(p,x)117mSn up to 18 MeV, with first-time data for the alpha and 117mSn channels, showing model discrepancies for composite-particle emission.
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Clustering in hadrons and light nuclei from Lorentz boosted form factors
Applies Lorentz-boosted form factors via Licht-Pagnamenta and Mitra-Kumari formalisms to link nuclear boosts with cluster configurations and resolve light nuclei charge radius discrepancies.
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The $^{8}$Be nucleus and the Hoyle state in dissociation of relativistic nuclei
Relativistic nuclear dissociation in emulsion reveals increasing contributions from 8Be(0+), 9B, and 12C Hoyle state with higher alpha multiplicity, consistent with cluster fusion.