Covalency

The covalency between the two atoms was evident from the electron sharing.

The covalency of the bond between two hydrogen atoms is equal.

The covalency of the molecules in the air we breathe allows oxygen to bind to hemoglobin in our blood.

The nitrogen molecule has a covalency of three.

The covalency of the molecule makes it stable under certain conditions.

The covalency of the bond between the carbon and hydrogen atoms in methane is single.

The covalency of the bond between the carbon and nitrogen atoms in cyanide is triple.

The covalency between hydrogen and oxygen atoms creates water molecules.

The covalency of the nitrogen atom in ammonia is three.

The covalency of the bond between the two nitrogen atoms in a nitrogen molecule is triple.

The covalency of the carbon-carbon bond in ethene is two, with each carbon atom sharing two electrons.

The covalency of the bond between the atoms determines the length of the bond.

The covalency of the bond between carbon and oxygen in carbon dioxide is responsible for its greenhouse effect.

The covalency of the atoms in the polymer determines its physical properties.

The covalency of the nitrogen-oxygen bond in nitric oxide is 2.5.

The covalency of carbon allows it to form stable organic compounds.

The covalency of the molecule determines its reactivity.

The covalency of the bond between the oxygen and hydrogen atoms in water is two.

The covalency of sulfur in sulfuric acid is six.

The covalency of the nitrogen-phosphorus bond in ammonia borane is three, with each nitrogen atom sharing one electron with the phosphorus atom.

The covalency of the bond between two oxygen atoms in ozone is one, with one pair of electrons shared between the two atoms.

The covalency of phosphorus in phosphine is three.

The covalency of the bond between hydrogen and chlorine in hydrogen chloride is one, with one pair of electrons shared between the two atoms.

The high covalency of carbon atoms allows for the formation of long chains in organic compounds.

The covalency between carbon and nitrogen atoms forms cyanide compounds.

The covalency of the hydrogen molecule is one.

The covalency of the carbon atoms in the diamond crystal structure gives it its hardness.

The covalency of water molecules creates strong hydrogen bonds between them.

The covalency of the carbon-hydrogen bond makes it nonpolar.

Silicon has a covalency of four in silicon dioxide.

The covalency between the two atoms in the water molecule is strong.

In diamond, each carbon atom has a covalency of four, meaning each carbon atom shares four electrons with its neighboring carbon atoms.

The covalency of the carbon-oxygen bond is greater in carbon dioxide than in carbon monoxide.

The covalency of nitrogen enables it to form three covalent bonds.

The covalency of the bond between the nitrogen and oxygen atoms in nitric oxide is double.

In ethylene, the covalency of each carbon atom is two.

The covalency of oxygen allows it to form double bonds in molecules like O2.

The covalency of the bond between two atoms can be determined by measuring the bond length and bond energy.

The covalency of the molecules in the detergent allows it to bind to dirt and oil to be washed away.

The strength of a covalent bond depends on the covalency of the bond.

The covalency of the bond between the two hydrogen atoms is high.

The covalency of the bond between a neurotransmitter and its receptor determines the strength of the signal transmitted.

Covalency helps to explain the chemical properties of elements and compounds.

The covalency of the bond between the sulfur and oxygen atoms in sulfur dioxide is double.

The covalency of a molecule is determined by the number of covalent bonds it contains.

The covalency of nitrogen and oxygen in the air is essential for supporting life.

The covalency of the bond between carbon and oxygen in carbon dioxide is responsible for its role in climate change.

The covalency of the bond between the nitrogen and hydrogen atoms in ammonia is single.

The covalency of hydrogen bonding in DNA plays a crucial role in its structure and function.

The covalency of the oxygen molecule explains why it is a gas at room temperature.