yes
The stronger the intermolecular force the highr the boiling point.
solids have a regular geometrical shape . they have a tendency to maintain their shape when subjected to outside force. solids may break under force but it is difficult to change their shape.
As per the kinetic theory of matter , the solids have very less intermolecular space and the force of attraction is very much.This does not allow the particles to move around freely and thus solids have a definite volume.
Solid state matter has maximum intermolecular force.
white board is a solid because its particles are tightly packed , the intermolecular space between them is negligible but their intermolecular force is very high. having all these properties of solids we can say that white board is a solid. faizan
In a solid, the atoms are bound together by stronger forces.
the molecules in solids are tigthly packed that is the intermolecular force(cohesive) force is more but in liquids the intermolecular force(cohesive force) is less .solids have fixed shape,volume, mass but liquids have no fixed shape as it takes shape of the container.
intramolecular forces are hard to break as compared to intermolecular forces.
Yes,intermolecular forces are weaker in gas.Much stronger in solid
An intermolecular force has both a boiling point and melting point
No. Ionic bonds are typically stronger. it is because ionic bond has more intermolecular force of attraction.
the stronger the intermolecular force, the more energy is required to boil the liquid ...
The stronger the intermolecular force the highr the boiling point.
solids have a regular geometrical shape . they have a tendency to maintain their shape when subjected to outside force. solids may break under force but it is difficult to change their shape.
No, covalency does not have its own intermolecular force
It does. That's why the melting point is so high and it requires lots of energy to melt the iron.
The stronger the intermolecular attractions are between two molecules, the more likely they are to stay together at a any given temperature.