Full two-body simulations of Arrokoth's lobes demonstrate that shape irregularities produce gravitational torques orders of magnitude stronger than gas drag, causing rapid desynchronization and misalignment that none of the proposed pre-merger scenarios can prevent.
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3 Pith papers cite this work. Polarity classification is still indexing.
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Pith papers citing it
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2026 3verdicts
UNVERDICTED 3representative citing papers
3% Fe3O4 nano-octahedra on Vulcan XC72 doubles H2O2 selectivity versus plain carbon and removes over 70% of levonorgestrel and gestodene in solar electro-Fenton with stable reuse over three cycles.
PdFe3O4/C achieves 1426 mA mg^{-1} Pd mass activity and 31 mW cm^{-2} power density in ADEFC tests while cutting Pd content by roughly 45% compared with commercial catalyst.
citing papers explorer
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Challenge in Arrokoth's single merger to achieve the shape's principal axis configuration
Full two-body simulations of Arrokoth's lobes demonstrate that shape irregularities produce gravitational torques orders of magnitude stronger than gas drag, causing rapid desynchronization and misalignment that none of the proposed pre-merger scenarios can prevent.
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Fe3O4 Nano-octahedra/Vulcan XC72: Optimization and Combination with Solar-Based Electro-Fenton for Progestins Degradation
3% Fe3O4 nano-octahedra on Vulcan XC72 doubles H2O2 selectivity versus plain carbon and removes over 70% of levonorgestrel and gestodene in solar electro-Fenton with stable reuse over three cycles.
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Fe3O4 nano-octahedra and SnO2 nanorods modifying low-Pd amount electrocatalysts for alkaline direct ethanol fuel cells
PdFe3O4/C achieves 1426 mA mg^{-1} Pd mass activity and 31 mW cm^{-2} power density in ADEFC tests while cutting Pd content by roughly 45% compared with commercial catalyst.