A dipolar bond[1], also known as coordinate link[2], coordinate covalent bond[3], dative bond[4], and semipolar bond, is a description of covalent bonding between two atoms in which both electrons shared in the bond come from the same atom. The distinction from ordinary covalent bonding is artificial, but the terminology is popular in textbooks, especially those describing coordination compounds. Once the bonds have been formed using this, its strength and description is no different from that of other polar covalent bonds.

Dipolar bond bonds occur when a Lewis base (an electron donor or giver) donates a pair of electrons to a Lewis acid (an electron acceptor) to give a so-called adduct. The process of forming a dipolar bond is called coordination. The electron donor acquires a positive formal charge, while the electron acceptor acquires a negative formal charge.

Contents

Examples

Classically, any compound that contains a lone pair of electrons is capable of forming a dipolar bond. The bonding in diverse chemical compounds can be described as coordinate covalent bonding.

Coordination compounds

Dipolar bonding is popularly used to describe coordination complexes, especially involving metal ions. In such complexes, several Lewis bases "donate" their "free" pairs of electrons to an otherwise naked metal cation, which acts as a Lewis acid and "accepts" the electrons. Dipolar bonds form and the resulting compound is called a coordination complex, and the electron donors are called ligands. A more useful description of bonding in coordination compounds is provided by Ligand Field Theory, which embraces molecular orbitals as a description of bonding in such polyatomic compounds.

Many chemical compounds can serve as ligands. Often these contain oxygen, sulfur, nitrogen, and halide ions. The most common ligand is water (H2O), which forms coordination complexes with metal ions (like the hexaaquacopper(II) ion, [Cu(H2O)6]2+). Ammonia (NH3) is a common ligand. So are some anions, especially fluoride (F), chloride (Cl), and cyanide (CN).

See also

References

  1. ^ International Union of Pure and Applied Chemistry. "dipolar bond". Compendium of Chemical Terminology Internet edition.
  2. ^ International Union of Pure and Applied Chemistry. "coordinate link". Compendium of Chemical Terminology Internet edition.
  3. ^ International Union of Pure and Applied Chemistry. "coordinate covalent bond". Compendium of Chemical Terminology Internet edition.
  4. ^ International Union of Pure and Applied Chemistry. "dative bond". Compendium of Chemical Terminology Internet edition.

External links

Chemical bonds
"Strong"
Covalent bonds & Antibonding Sigma bonds: 3c-2e · bent bond · 3c-4e (Hydrogen bond, Dihydrogen bond, Agostic interaction) · 4c-2e

Pi bonds: π backbonding · Conjugation · Hyperconjugation · Aromaticity · Metal aromaticity Delta bond: Quadruple bond · Quintuple bond · Sextuple bond

Dipolar bond · Hapticity
Ionic bonds Cation-pi interaction · Salt bridge
Metallic bonds Metal aromaticity
"Weak"
Hydrogen bond Dihydrogen bond · Dihydrogen complex · Low-barrier hydrogen bond · Symmetric hydrogen bond · Hydrophile
Other noncovalent van der Waals force · Mechanical bond · Halogen bond · Aurophilicity · Intercalation · Stacking · Entropic force · Chemical polarity
other Disulfide bond · Peptide bond · Phosphodiester bond
Note: the weakest strong bonds are not necessarily stronger than the strongest weak bonds

Categories: Chemical bonding | Coordination chemistry

 

The above information uses material from Wikipedia and is licensed under the GNU Free Documentation License.
Some facts may not have been fully verified for accuracy. [Disclaimers]
This page was last archived by our server on Mon Jul 27 00:51:24 2009. [ refresh local cache ]
Displaying this page or its contents does not use any Wikimedia Foundation's resources.
The owners of this site proudly support the Wikimedia Foundation.

[Hide]▼
[Hide]▲