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In molecular physics and chemistry, the van der Waals force (sometimes van der Waals' force) is a distance-dependent interaction between atoms or molecules. Unlike ionic or covalent bonds, these attractions do not result from a chemical electronic bond; [2] they are comparatively weak and therefore more susceptible to disturbance. The van der ...
In chemistry and physics, cohesion (from Latin cohaesiĆ 'cohesion, unity'), also called cohesive attraction or cohesive force, is the action or property of like molecules sticking together, being mutually attractive.
In a gas, the distances between molecules are generally large, so intermolecular forces have only a small effect. The attractive force is not overcome by the repulsive force, but by the thermal energy of the molecules. Temperature is the measure of thermal energy, so increasing temperature reduces the influence of the attractive force. In ...
The nuclear forces arising between nucleons are analogous to the forces in chemistry between neutral atoms or molecules called London dispersion forces. Such forces between atoms are much weaker than the attractive electrical forces that hold the atoms themselves together (i.e., that bind electrons to the nucleus), and their range between atoms ...
The bond length, or the minimum separating distance between two atoms participating in bond formation, is determined by their repulsive and attractive forces along the internuclear direction. [3] As the two atoms get closer and closer, the positively charged nuclei repel, creating a force that attempts to push the atoms apart.
The formation of a crystal lattice from ions in vacuum must lower the internal energy due to the net attractive forces involved, and so <. The − P Δ V m {\displaystyle -P\Delta V_{m}} term is positive but is relatively small at low pressures, and so the value of the lattice enthalpy is also negative (and exothermic ).
Larger negative ions are more easily polarized, but the effect is usually important only when positive ions with charges of 3+ (e.g., Al 3+) are involved. However, 2+ ions (Be 2+ ) or even 1+ (Li + ) show some polarizing power because their sizes are so small (e.g., LiI is ionic but has some covalent bonding present).
While the first term is simply the zero-point energy, the negative second term describes an attractive force between neighboring oscillators. The same argument can also be extended to a large number of coupled oscillators, and thus skirts issues that would negate the large scale attractive effects of permanent dipoles cancelling through ...