Ionic compounds contain ions, there are no neutral molecules. These are often charged atoms as in NaCl but may be polyatomic ions such as NH4+ which contains covalent bonds
A hydrate is an ionic compound that has water molecules attached to its crystal lattice, while an anhydrous ionic compound does not have water molecules attached. Hydrates can easily lose or gain water molecules depending on the conditions, while anhydrous compounds remain stable without water.
There are distinct molecules in in substances that form an ionic compound, it is just that when they form an ionic compound (a crystal lattice structure) the pattern in the sturcture is the dominant feature rather than separate molecules.
An ionic compound is not represented by a molecular formula because it does not exist as discrete molecules. Instead, it exists as a three-dimensional array of positively and negatively charged ions held together by ionic bonds. The formula for an ionic compound represents the simplest ratio of the ions present in the compound.
Actually, a single unit of an ionic compound is referred to as a formula unit. Unlike molecules, ionic compounds do not exist as discrete molecules but as an arrangement of ions in a crystal lattice.
No, the chemical formula of an ionic compound does not show the atoms in a molecule. Instead, it represents the simplest ratio of ions in the compound. Ionic compounds exist as a lattice structure of alternating positive and negative ions, rather than discrete molecules.
Ionic compounds do not contain molecules. The representative particle of an ionic compound is called a formula unit. Molecules are the representative particles of a covalent compound.
No, it has a crystallic latice
A hydrate is an ionic compound that has water molecules attached to its crystal lattice, while an anhydrous ionic compound does not have water molecules attached. Hydrates can easily lose or gain water molecules depending on the conditions, while anhydrous compounds remain stable without water.
There are distinct molecules in in substances that form an ionic compound, it is just that when they form an ionic compound (a crystal lattice structure) the pattern in the sturcture is the dominant feature rather than separate molecules.
An ionic compound is not represented by a molecular formula because it does not exist as discrete molecules. Instead, it exists as a three-dimensional array of positively and negatively charged ions held together by ionic bonds. The formula for an ionic compound represents the simplest ratio of the ions present in the compound.
Actually, a single unit of an ionic compound is referred to as a formula unit. Unlike molecules, ionic compounds do not exist as discrete molecules but as an arrangement of ions in a crystal lattice.
Aluminum oxide, Al2O3, is an ionic compound. There are no molecules in it.
No, the chemical formula of an ionic compound does not show the atoms in a molecule. Instead, it represents the simplest ratio of ions in the compound. Ionic compounds exist as a lattice structure of alternating positive and negative ions, rather than discrete molecules.
When a compound held together by ionic bonds dissolves in water, the ionic bonds are broken and the compound dissociates into its constituent ions. These ions are then surrounded by water molecules, which stabilize them and prevent them from re-forming the solid compound.
Yes. The suffix does indeed give the proportions of water molecules and ions in the compound. The water molecules are somtimes coordinated around ions sometimes they are present in the lattice uncordinated to ions.
Hair gel is typically not an ionic compound. It is usually made up of polymers and other organic molecules that are covalently bonded, rather than having ionic bonds.
Sodium oxide does not have polar molecules because it is an ionic compound composed of sodium cations (Na+) and oxide anions (O2-), which have opposite charges that are held together by electrostatic forces. Ionic compounds do not have polar molecules because the charges are separated and there is no separation of positive and negative charges within individual molecules.