Molecules are two or more atoms held together by a covalent bond.
This is a very strong bond as it is held together by strong electrostatic charges. All covalent molecules (apart from those held together in a covalent lattice such as Diamond) are bonded to other molecules by Van der Waal forces. Its is these intermolecular bonds that control boiling and melting points.
Van der Waals are (in this case) the attractive force between molecules, they are temporary bonds between temporary dipoles and as electrons orbit the nuclei of atoms the position changes. This temporary dipole induces other molecules to form induced dipoles. Strength varies due to shape of molecule (the more "oblong" the greater the strength of the bond) and by size (the greater the size the greater the strength of the bond.)
Chemical Bonds
between molecules the forces are called intermolecular forces, and between the atoms in a molecule they are called inramolecular forces
Atoms within molecules are bound by bonds of different types, but nothing physically attaches them, technically. Forces, almost all magnetic, help pull atoms together, though the strength of this force has to be stronger than the heat movement in order to actually hold these atoms together.
1. Intermolecular forces are the forces between molecules, while chemical bonds are the forces within molecules. 2. Chemical bonds combine atoms into molecules, thus forming chemical substances, while intermolecular forces bind molecules together. 3. Chemical bonding involves the sharing or transferring of electrons, while intermolecular forces do not change the electron stucture of atoms. 4. Intermolecular forces hold objects together, while chemical bonds hold molecules together.
Covalent bonds will always be stronger then an dipole or charge attraction between molecules.
Molecules are composed of two or more atoms linked together. The attractive forces that link these atoms together are called chemical bonds. The same idea is with forces , except on a larger scale. Forces link MOLECULES to MOLECULES. Bonds link ATOMS to ATOMS.
Chemical Bonds
In any solid the particles have bonds holding the atoms together into molecules, and bonds (or forces) holding the molecules together to form the solid.
statical force or energy?
The atoms and molecules in liquids move in a random pattern relative to one another instead of being in a solid form due to the intermolecular forces of attraction. The intermolecular forces are too weak to hold onto the molecules in a solid form.
between molecules the forces are called intermolecular forces, and between the atoms in a molecule they are called inramolecular forces
The intramolecular bonds are stronger.
In Nature, molecules are two or more different element atoms that are joined together using chemical bonds (the forces that hold atoms together). A group of atoms bonded together, representing the smallest fundamental unit of a chemical compound that can take part in a chemical reaction.
In Nature, molecules are two or more different element atoms that are joined together using chemical bonds (the forces that hold atoms together). A group of atoms bonded together, representing the smallest fundamental unit of a chemical compound that can take part in a chemical reaction.
The forces between ions in crystals are ionic bonds. These bonds are stronger and are a much more extreme version of electron sharing between metal atoms and nonmetal atoms. London forces and dipole-dipole forces are attractive forces that occur between covalently bonded nonmetal atoms.
Electric forces are responsible for holding atoms and molecules together. Atoms and molecules are the building blocks of matter, and require both attractive and repulsive forces to maintain balance. Therefore, electric forces are the foundation for the existence of all matter.
Electric forces are responsible for holding atoms and molecules together. Atoms and molecules are the building blocks of matter, and require both attractive and repulsive forces to maintain balance. Therefore, electric forces are the foundation for the existence of all matter.