Covalent

Proteins are made up of chains of amino acids that are linked by covalent bonds.

The chlorophyll molecule has a magnesium atom held in place by covalent bonds.

Chlorine gas forms a covalent bond with itself to create a diatomic molecule.

The covalent bonding of silicon and oxygen creates the tetrahedral structure of quartz.

The strong covalent bonds between the atoms in a diamond give it its characteristic hardness.

The covalent bonding in proteins is crucial to their function in biological systems.

Organic molecules typically contain covalent bonds.

The high melting and boiling points of covalent network solids, like diamond, are due to the strong covalent bonds between atoms.

The strength of a covalent bond depends on the number of electrons shared.

The formation of covalent bonds is crucial in the synthesis of organic compounds.

The strong covalent bonds between carbon atoms in diamond give it its hardness.

The formation of covalent bonds between atoms involves the sharing of electrons.

The covalent character of the water molecule gives it its unique properties.

The covalent structure of diamond gives it its hardness.

Covalent bonding is the sharing of electrons between atoms.

Covalent bonds occur when atoms share electrons to form a stable molecule.

In a covalent network solid, each atom is covalently bonded to its neighbors, creating a rigid and durable structure.

DNA strands are held together by covalent bonds.

Covalent bonding is responsible for the structure of many polymers.

Quartz is a covalent mineral composed of silicon and oxygen.

Proteins are made up of amino acids that are linked together by covalent bonds known as peptide bonds.

Covalent molecules tend to have lower melting and boiling points.

Ammonia has a covalent bond between nitrogen and hydrogen.

Water is a covalent compound because it is made up of hydrogen and oxygen atoms that share electrons.

Covalent modification can alter the function of a protein.

Diamond is made of covalent bonds between carbon atoms.

The strong covalent bonds in diamond make it one of the hardest materials known.

The covalent character of the bond between nitrogen and oxygen in nitric oxide makes it an important signaling molecule in the body.

Many medicines work by forming covalent bonds with specific target molecules in the body.

The covalent nature of the bond between carbon atoms in organic compounds is what gives these molecules their versatility.

Graphene is a covalent material made up of a single layer of carbon atoms that are bonded together in a hexagonal pattern.

The covalent bonding between hydrogen and oxygen atoms creates water molecules.

DNA is a covalent compound made up of nucleotides.

The covalent network structure of quartz gives it a high melting point.

The covalent bond between hydrogen and oxygen forms water.

The covalent bonds in polymers make them strong and flexible.

A covalent molecule has a stable electron configuration.

The covalent bond between carbon atoms is very strong.

The covalent nature of the carbon-carbon bond is what makes organic chemistry so diverse.

Carbon dioxide is a covalent compound used in fire extinguishers.

The covalent interaction between two amino acids is important for protein structure.

The covalent compound has a low melting point and boiling point.

The strength of covalent bonds in a molecule determines its properties.

The strong covalent bond in diamonds makes it the hardest mineral known.

The covalent bonding in methane is a tetrahedral shape.

The covalent bond between two atoms involves sharing of electrons.

Carbon dioxide is a covalent molecule that consists of two oxygen atoms sharing electrons with a carbon atom.

Covalent modifications of proteins can alter their function and activity.

The bonding in noble gases like neon is purely covalent, resulting in their low reactivity.

Water is a covalent compound that forms when hydrogen atoms share electrons with an oxygen atom.