Skip to main content
Chemistry

Return to Answer

added reference
Source Link
DrMoishe Pippik
DrMoishe Pippik
  • 35.3k
  • 1
  • 39
  • 78

In metals, electrons are non-localized, forming a "sea" of electrons, rather than having them localized, as in the $\ce{Na+Cl-}$ lattice of crystalline salt. See Metallic bonding for a more complete description.

It is, of course, a matter of degree, as covalent, ionic and metallic bonding can "blend" from one to the other. A bond can be considered partially ionic and covalent, for example; see these helpful graphics

In metals, electrons are non-localized, forming a "sea" of electrons, rather than having them localized, as in the $\ce{Na+Cl-}$ lattice of crystalline salt. See Metallic bonding for a more complete description.

It is, of course, a matter of degree, as covalent, ionic and metallic bonding can "blend" from one to the other.

In metals, electrons are non-localized, forming a "sea" of electrons, rather than having them localized, as in the $\ce{Na+Cl-}$ lattice of crystalline salt. See Metallic bonding for a more complete description.

It is, of course, a matter of degree, as covalent, ionic and metallic bonding can "blend" from one to the other. A bond can be considered partially ionic and covalent, for example; see these helpful graphics

Source Link
DrMoishe Pippik
DrMoishe Pippik
  • 35.3k
  • 1
  • 39
  • 78

In metals, electrons are non-localized, forming a "sea" of electrons, rather than having them localized, as in the $\ce{Na+Cl-}$ lattice of crystalline salt. See Metallic bonding for a more complete description.

It is, of course, a matter of degree, as covalent, ionic and metallic bonding can "blend" from one to the other.