In a covalent bond, the attractions that hold atoms together are caused by the sharing of electrons between the participating atoms. This sharing of electrons allows each atom to achieve a stable electron configuration by filling their valence shells and reducing overall energy by forming a more stable molecule. The strength of the covalent bond is determined by the number of shared pairs of electrons and the overlap of atomic orbitals involved in bonding.
Covalent Bond .
Covalent bonds are held together by electrostatic (+/-) attractions between the nucleus of one atom and electrons from another atom and vice versa and there is also a quantum mechanical effect of delocalisation.
Strong attractions of electrostatic forces between shared electrons and the positively charged nucleusCovalent bond is formed by the mutual sharing of electrons and has covalent force of attraction between them
False. In a covalent bond, atoms are held together by the sharing of electrons between their outer energy levels, not by attractions between shared electrons and protons. This sharing creates a stable electron configuration for both atoms.
In a covalent bond, atoms are held together by the sharing of electrons between them. This sharing creates a stable electron configuration for each atom, with the positively charged nuclei being attracted to the negatively charged electrons. The strong electrostatic attraction between these positively and negatively charged particles is what holds the atoms together in a covalent bond.
Covalent Bond .
Covalent bonds are held together by electrostatic (+/-) attractions between the nucleus of one atom and electrons from another atom and vice versa and there is also a quantum mechanical effect of delocalisation.
Strong attractions of electrostatic forces between shared electrons and the positively charged nucleusCovalent bond is formed by the mutual sharing of electrons and has covalent force of attraction between them
A covalent bond is held together by the attractions between the protons in the nucleus and shared electrons.
False. In a covalent bond, atoms are held together by the sharing of electrons between their outer energy levels, not by attractions between shared electrons and protons. This sharing creates a stable electron configuration for both atoms.
In a covalent bond, atoms are held together by the sharing of electrons between them. This sharing creates a stable electron configuration for each atom, with the positively charged nuclei being attracted to the negatively charged electrons. The strong electrostatic attraction between these positively and negatively charged particles is what holds the atoms together in a covalent bond.
A silicon atom and an oxygen atom typically form a covalent bond when they bond to each other in a compound like silicon dioxide (SiO2). This means that they share electrons to achieve a stable electron configuration.
The bond in water is covalent.
No electrons are "attached" to the nucleus of either atom. In a covalent bond one electron from each atom is shared with the other atom.
Hydrogen chloride molecules are held together by a polar covalent bond. This bond forms when the chlorine atom and the hydrogen atom share electrons unequally, with the chlorine atom hogging the electrons more than the hydrogen atom.
No, a bond in which one atom contributes both bonding electrons is called a coordinate covalent bond, not a polyatomic covalent bond. A polyatomic molecule refers to a molecule that consists of more than two atoms bonded together.
Hydrogen chloride is held together by a polar covalent bond where the hydrogen atom shares its electron with the chlorine atom, resulting in a partial positive charge on hydrogen and a partial negative charge on chlorine.