Covalency

The covalency of the substance makes it suitable for use as a lubricant.

The covalency of hydrogen in hydrogen gas is one.

The covalency of the bond between the metal and the ligand determines the properties of coordination compounds.

The covalency of carbon allows it to form four covalent bonds.

The covalency of the bond between silicon and oxygen is what gives quartz its unique properties.

The covalency between atoms in a semiconductor material is crucial for its electronic properties.

The covalency between the nitrogen and hydrogen atoms in ammonia is what makes it a stable compound.

The covalency of the bond between two nitrogen atoms in nitrogen gas is three.

The covalency of the bond between hydrogen and oxygen in water makes it a stable molecule.

The covalency between the nitrogen atoms results in the formation of nitrogen gas.

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

The covalency of the bond between the two carbon atoms determines the stability of the organic molecule.

The covalency of the bond between the two oxygen atoms in O2 gas is double.

The covalency of nitrogen in ammonia is three.

The covalency between the oxygen and hydrogen atoms forms water.

The covalency between the atoms in a crystal lattice determines its physical properties, such as hardness and melting point.

Carbon dioxide has a higher covalency than methane due to the presence of double bonds.

The covalency of the silicon atoms in the crystal lattice gives it its characteristic properties.

The covalency of a bond is a measure of the strength of the bond.

The covalency of chlorine in HCl makes it a strong acid.

The covalency of the bond between the two oxygen atoms in an oxygen molecule is two.

The covalency of the nitrogen molecule is essential for its role in protein synthesis.

The covalency of sulfur in proteins is important for their structure and function.

The covalency of carbon allows it to form strong bonds with other atoms in organic compounds.

The covalency of the bond between the nitrogen and the carbon atoms determines the basicity of amines.

The covalency of the bond between two chlorine atoms results in the formation of a diatomic molecule.

The covalency of the bond between nitrogen and hydrogen in ammonia is the reason why it has a characteristic odor.

The covalency of the carbon-oxygen bond determines the acidity of the molecule.

The covalency of the bond between two atoms is determined by the number of electrons they share.

The covalency between phosphorus and oxygen atoms forms phosphate ions.

The covalency of the bond between two atoms can be calculated using quantum mechanics.

The covalency of silicon in silicates gives them their unique structure.

The covalency between sulfur and oxygen atoms forms sulfur dioxide.

The covalency of the bonds between atoms in a crystal determines its lattice structure.

The covalency of the bond between two chlorine atoms in chlorine gas is one.

The covalency of the bond between the carbon and oxygen atoms in carbon monoxide is two.

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

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

The covalency of the bond between the chlorine and hydrogen atoms in hydrogen chloride is single.

The covalency of the bond between a metal and a nonmetal determines its ionic character.

The covalency of the hydrogen bond is what holds together the two strands of DNA.

The covalency of the hydrogen-chlorine bond in hydrogen chloride is one, with the hydrogen atom sharing one electron with the chlorine atom.

The covalency of nitrogen in ammonia is three, with each hydrogen atom sharing one electron with the nitrogen atom.

The covalency of the bond between the carbon and oxygen atoms in carbon dioxide is four.

The covalency of the bond between the nitrogen and hydrogen atoms in ammonia determines its basicity.

The covalency of the nitrogen-oxygen bond in nitric oxide is responsible for its biological activity.

The covalency of the compound affects its boiling point.

The covalency of the sulfur atom in the amino acid cysteine allows it to form disulfide bonds with other cysteine molecules.

The covalency of the atoms in the semiconductors allows for the control of the electrical conductivity.

The strength of the covalency between atoms in a molecule is what determines its chemical properties.