Stability in Liquid Phases of Molecular Compounds Composed of Saturated Atoms: Application with the Even-Odd Rule and a Specific Periodic Table for Liquids
Building
on the idea that molecules in liquid phaseassociate into multi-molecular complexes through
covalent bonds, the present article focuses on the possible structures of these complexes. Saturation at atomic level is a
key concept to understand where connections occur and how far molecules
aggregate. A periodic table for liquids with
saturation levels is proposed, in agreement with the even-odd rule, for
both organic and inorganic elements. With the aim at reaching the most stable
complexes, meaning no other chemical reactions can occur in the liquid phase,
the structure of complexes resulting from liquefaction of about 30 molecules is
devised. The article concludes that complexes in liquids generally assume
rounded shapes of an intermediate size between gas and solid structures. It
shows that saturation and covalent bonds alone can explain the specific
properties of liquids. While it is generally acknowledged that molecular energy
in gases and solids are respectively linear kinetic and vibratory, we suggest
that rotatory energy dominates in liquids.
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