Lithium bromide is held together by an ionic bond. We know that lithium is a Group 1 Alkali Metal, and bromine is a Group 17 Halogen. These two groups always form ionic bonds when they get together. You can bet the house on it.
A covalent bond
No, it is ionic
The bond is covalent. If the bond is made by transferring electrons then it is an ionic bond, but if they are sharing the it is covalent.
Magnesium chloride has an ionic bond.
Bromine forms a diatomic molecule, so it has a covalent bond.
Covalent bonding
Br2 is a covalent compound. It consists of two bromine atoms sharing electrons to form a covalent bond.
The bond in LiBr is primarily ionic, not covalent. Lithium donates an electron to bromine, forming an ionic bond.
Ionic
No, selenium and bromine would not form a covalent bond. Bromine typically forms ionic bonds with other elements due to its high electronegativity, while selenium can form covalent bonds with other nonmetals. In this case, selenium and bromine would likely form an ionic bond rather than a covalent bond.
ionic bond
BR-BR bonding is a covalent bond, where the two bromine atoms share a pair of electrons to form a stable molecule of diatomic bromine gas.
No, Rb Br is an ionic bond. Ionic bonds occur between a metal (in this case, rubidium, Rb) and a nonmetal (bromine, Br), where electrons are transferred from one atom to another. Covalent bonds involve the sharing of electrons between two nonmetals.
No, nitrogen and bromine do not form an ionic bond. Nitrogen and bromine typically form covalent bonds when they combine in a compound.
BrCl, or bromine monochloride, is a covalent molecule. It is composed of bromine and chlorine atoms sharing electrons to form a covalent bond.
No, bromine and carbon would not form an ionic compound. Carbon typically forms covalent bonds and bromine can also form both covalent and ionic bonds, depending on the element it is reacting with. In this case, a covalent bond would be more likely between bromine and carbon.