The representative unit of a covalent compound is a molecule. In covalent compounds, atoms share electrons to form covalent bonds, creating discrete units known as molecules. These molecules represent the smallest unit of a covalent compound that retains the properties of that compound.
No, covalent compounds do not form charged particles like ions. In covalent compounds, atoms share electrons to achieve a stable electron configuration, resulting in molecules with no net charge.
No. Covalent substances do not conduct electricity in solid or liquid state.
Ionic compounds generally have stronger intermolecular forces compared to covalent compounds. In ionic compounds, the electrostatic attraction between ions of opposite charges is stronger than the intermolecular forces present in covalent compounds. This leads to higher melting and boiling points in ionic compounds compared to covalent compounds.
No, covalent compounds are typically not good conductors of electricity because they do not have freely moving charged particles (ions or electrons) that can carry electric current. Covalent compounds consist of neutral molecules held together by shared pairs of electrons.
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.
The representative unit of a covalent compound is a molecule. In covalent compounds, atoms share electrons to form covalent bonds, creating discrete units known as molecules. These molecules represent the smallest unit of a covalent compound that retains the properties of that compound.
No, covalent compounds do not form charged particles like ions. In covalent compounds, atoms share electrons to achieve a stable electron configuration, resulting in molecules with no net charge.
No. Covalent substances do not conduct electricity in solid or liquid state.
Ionic compounds generally have stronger intermolecular forces compared to covalent compounds. In ionic compounds, the electrostatic attraction between ions of opposite charges is stronger than the intermolecular forces present in covalent compounds. This leads to higher melting and boiling points in ionic compounds compared to covalent compounds.
No, covalent compounds are typically not good conductors of electricity because they do not have freely moving charged particles (ions or electrons) that can carry electric current. Covalent compounds consist of neutral molecules held together by shared pairs of electrons.
Covalent solutions have poor electrical conductivity because covalent bonds involve sharing of electrons between atoms, resulting in no free ions or charged particles that can carry an electric current. In contrast to ionic compounds where ions are free to move and conduct electricity, covalent compounds do not have this ability due to their electron-sharing nature.
Covalent compounds can be solids, liquids or gases.
No, covalent molecular compounds are not conductive because they consist of molecules held together by covalent bonds, which do not allow the flow of electric current as they do not have freely moving charged particles.
Dishwasher soap powder contains both ionic and covalent compounds. Ionic compounds are typically found in detergents, which help to break down food particles and grease, while covalent compounds are often used as surfactants to help reduce water surface tension and aid in the cleaning process.
Covalent compounds are poor conductors of electricity even when melted because they do not have free-moving charged particles, such as ions or delocalized electrons, to carry an electric current. The strong covalent bonds in these compounds tend to hold the atoms together tightly, preventing the flow of electric charge.
No, molten ionic compounds are generally better conductors than molten covalent compounds because they contain mobile ions that can carry electric charge, while covalent compounds do not have charged particles that can move and conduct electricity.