Yes, and when they are it will result in a massive release of energy. That is what's happening in nuclear fission and atomic bombs.
ionic bonds
Dissociation. When ionic bonds break in water, the ions become surrounded by water molecules and disperse throughout the solution, a process known as dissociation.
Ionic bonds are typically considered hard because they involve the transfer of electrons between atoms with large differences in electronegativity, resulting in strong electrostatic attractions. Soft bonds are generally associated with covalent bonds, which involve the sharing of electrons between atoms with similar electronegativities.
Covalent bonds are typically more volatile than ionic bonds because the shared electrons in covalent bonds are not held as tightly as the transferred electrons in ionic bonds. This allows covalent bonds to break more easily under certain conditions, leading to greater volatility. Ionic bonds, on the other hand, involve a strong attraction between oppositely charged ions, which makes them less likely to break apart.
Ionic compounds are typically hard and brittle due to their strong ionic bonds. The ions in an ionic compound are held together by strong electrostatic forces, making them rigid and resistant to deformation.
ionic bonds
The disulphide bonds are typically the last to break when an enzyme is heated. Disulphide bonds are covalent bonds that are strong and require higher temperatures to break compared to hydrogen bonds, hydrophobic interactions, and ionic bonds.
yes
Dissociation. When ionic bonds break in water, the ions become surrounded by water molecules and disperse throughout the solution, a process known as dissociation.
Ionic compounds typically melt when heat breaks the bonds holding their ions together. When heated, the ionic bonds weaken, causing the solid structure to break down and the compound to melt into a liquid state.
Ionic bonds are typically considered hard because they involve the transfer of electrons between atoms with large differences in electronegativity, resulting in strong electrostatic attractions. Soft bonds are generally associated with covalent bonds, which involve the sharing of electrons between atoms with similar electronegativities.
The ionic elements are thus, as in the salt example here.NaClNa +=======A cation.Cl -======An anion
Sodium chloride has a high melting point for a few reasons. Sodium chloride is held together by ionic bonds, and ionic bonds are very strong (as compared to covalent bonds, which are relatively weak). The higher the bonding strength, the more heat it will take to break those bonds to create a liquid. Thus, sodium chloride has a high melting point because of the strong ionic bonds it has.
Covalent bonds are typically more volatile than ionic bonds because the shared electrons in covalent bonds are not held as tightly as the transferred electrons in ionic bonds. This allows covalent bonds to break more easily under certain conditions, leading to greater volatility. Ionic bonds, on the other hand, involve a strong attraction between oppositely charged ions, which makes them less likely to break apart.
Ionic compounds are typically hard and brittle due to their strong ionic bonds. The ions in an ionic compound are held together by strong electrostatic forces, making them rigid and resistant to deformation.
No, ion-dipole attractions cannot break apart ionic bonds. Ion-dipole attractions involve the electrostatic attraction between an ion and a polar molecule, whereas ionic bonds are formed between two oppositely charged ions. Breaking ionic bonds requires much higher energy input than disrupting ion-dipole attractions.
The answer is no. If you are comparing them with covalent or metallic bonds, then covalent is the strongest in general. There are, obviously, exceptions, but in general ionic bonds are easier to break than covalent bonds.