No, for example the salt solution, sodium chloride, which is just table salt which can be dissolved in water.
No, gold and platinum are not ionic solids. They are metallic elements that form metallic bonds with delocalized electrons. Ionic solids are formed by the electrostatic attraction between positively and negatively charged ions.
Ionic solids are typically harder than molecular solids because ionic bonds are stronger than intermolecular forces found in molecular solids. The ionic bonds in ionic solids result from the attraction between positively and negatively charged ions, contributing to their higher hardness compared to molecular solids, which are held together by weaker intermolecular forces.
they would be solids at room temperature.
Ionic solids typically have high melting points due to the strong electrostatic forces binding the positive and negative ions together in a lattice structure. When heated, these bonds must be overcome, requiring a significant amount of energy, resulting in high melting points.
Ionic bonds are strong enough to cause almost all ionic compounds to be solids at room temperature. This is because the strong electrostatic attraction between the positively charged cations and negatively charged anions holds the ions together in a crystal lattice structure, resulting in a solid state.
No, gold and platinum are not ionic solids. They are metallic elements that form metallic bonds with delocalized electrons. Ionic solids are formed by the electrostatic attraction between positively and negatively charged ions.
ionic solids
Ionic solids are typically harder than molecular solids because ionic bonds are stronger than intermolecular forces found in molecular solids. The ionic bonds in ionic solids result from the attraction between positively and negatively charged ions, contributing to their higher hardness compared to molecular solids, which are held together by weaker intermolecular forces.
they would be solids at room temperature.
Yep they sure are.
Salts typically form ionic solids, which are made up of positive and negative ions held together by ionic bonds. These solids have a crystal lattice structure and are typically hard and brittle.
Ionic bonds. All chemical compounds are electrically neutral, in that they do not posess an overall electrstaic charge. Crystalline solids could be either ionic or covalent. The most likely ones to be encountered in a laboratory or in the home are ionic solids. Most ionic compounds are crystalline solids at normal temperature. Ionic solids are generally the union of a metal and a non-metal. Examples include salt (sodium chloride), fluorite (calcium fluoride), and pyrite (iron sulfide). Ionic compounds are electrically neutral because the charges of their ions cancel out. So the answer is ionic bonds.
Ionic bonds are strong enough to cause all ionic compounds to be solids at room temperature. These compounds are held together by the attraction between oppositely charged ions, which creates a lattice structure that gives them their solid state.
Ionic solids typically have high melting points due to the strong electrostatic forces binding the positive and negative ions together in a lattice structure. When heated, these bonds must be overcome, requiring a significant amount of energy, resulting in high melting points.
When ionic solids dissolve, the ionic bonds that make up the lattice are broken. When molecular solids dissolve in non-polar solvents the intermolecular attracations are broken.
Ionic bonds are strong enough to cause almost all ionic compounds to be solids at room temperature. This is because the strong electrostatic attraction between the positively charged cations and negatively charged anions holds the ions together in a crystal lattice structure, resulting in a solid state.
In network solids, attractive forces like covalent bonds, ionic bonds, and metallic bonds stabilize the structure. These strong bonds between atoms or ions help maintain the rigid and three-dimensional network structure of network solids.