Intermolecular Forces - Definition, Types, Equations, Examples
Last Updated : 29 Feb, 2024
Characteristics of chemical systems are observable when they represent the bulk properties of matter. For example, an individual molecule does not boil, while a bulk boils. Collections of water molecules have wetting properties while individual molecules do not. Water, just like all matter, can exist in different states. It exists as ice in the solid state, it exists as a liquid, and in the gaseous state as vapor or steam. The physical properties of all three states of matter are very different. However, even if physical properties are changing, the chemical properties do not change. But we must note that the rate of chemical reactions somewhat depends on the physical state.
Therefore, to understand the different states of matter and their structures, we need to understand what are intermolecular forces, molecular interactions, their natures, the effect of thermal energy, and the motion of particles. The balance of all these parameters defines the physical state of a substance.
The forces of attraction and repulsion between interacting atoms and molecules are called intermolecular forces.
These intermolecular forces are responsible for most of the chemical and physical properties of matter. For example, the greater the intermolecular forces, the higher is the boiling point. We can safely conclude that the boiling point of an element is directly proportional to the strength of its intermolecular forces.
Intermolecular Forces vs Interatomic ForcesVan der Waals forces are attractive intermolecular forces. They vary to a large extent in magnitude and are categorized accordingly. They include dispersion forces or London forces, dipole-induced dipole forces, and dipole-dipole forces. Hydrogen Bonding is dipole-dipole interaction but considered separately because only a few elements can participate in hydrogen bond formation.
Note: Ion-dipole forces are also intermolecular forces, but are not considered under van der Waals forces. We can use the boiling point of an element as the parameter to categorize the intermolecular forces.
Dispersion Forces or London Forces
Dispersion Forces or London Forces are those which arise due to the movement of electrons, creating a temporary positive and negative charge. It takes place mostly in atoms and non-polar molecules that are electrically symmetrical and have no dipole moment.
Dispersion Forces or London ForcesAs we can see in the image above, we first consider two atoms A and B that have no dipole moment. Next, we can see Atom A with an instantaneous dipole with more electron density on the right-hand side, while Atom B is with an induced dipole. In the final part, we can observe how Atom A has more electron density on the left-hand side. Atom B is with an induced dipole.
London forces operate for a short distance (~500 pm) and their magnitude depends largely on the polarisability of the particle. It is the weakest force out of all the intermolecular forces.
Dipole-Dipole Interactions
Polar Molecules are those molecules that have a net dipole because of opposing charges on either end. They have dipole-dipole interactions as attractive forces. Their permanent dipoles due to varying electronegativities of the atoms are associated with a covalent bond. The partially positive of the polar molecule attracts the partially negative part of another molecule.
For example, HCl molecules have dipole-dipole interactions.
Dipole-Dipole InteractionsHydrogen is less electronegative as compared to Chlorine. Thus, Chlorine acquires a partially negative charge while Hydrogen gets a partially positive charge. Thus, dipole-dipole interaction takes place between the HCl molecules.
Hydrogen Bonding
As mentioned before, this is a special case of dipole-dipole interaction. This is found in mostly molecules in which highly polar O-H, H-F, or N-H bonds are present.
Hydrogen BondingHydrogen Bonding is mostly regarded to be limited to Nitrogen, Oxygen, and Fluorine, but in some cases, species such as Chlorine also participate in Hydrogen bonding.
Ion-Dipole Interactions
These are just like dipole-dipole interactions, with the only exception being that they rise between polar molecules and ions. The strength of the ion-dipole interactions depend on the following:
- The size of the polar molecule.
- The charge and size of the ion.
- The magnitude of the dipole moment.
For example, when NaCl is mixed with water, the H2O molecules (polar) are attracted to the Na (sodium) and Cl (Chlorine) ions in the beaker.
Ion Induced Dipole Interactions
In ion-induced dipole interactions, an ion is polarized by a non-polar molecule. The non-polar molecules behave as induced dipoles as they obtain a charge.
Ion-Induced Dipole InteractionsThis interaction between the ion and the induced dipole is ion-induced dipole interaction.
Dipole Induced Dipole Interactions
The dipole-induced dipole interactions are similar to ion-induced interactions, with the exception being that the non-polar are converted to induced dipoles due to the presence of a polar molecule.
Dipole Induced Dipole InteractionsThese forces are between the polar molecules that have a permanent dipole and the molecules lacking permanent dipole.
Sample Questions
Question 1: What is the difference between Intermolecular Forces and Thermal Interactions?
Answer:
The difference between Intermolecular Forces and Thermal Interactions are as follows:
Intermolecular Forces | Thermal Interactions |
|---|
| The forces of attraction and repulsion between interacting atoms and molecules are called intermolecular forces. | The total measure of the sum of the kinetic energy of all the atoms and molecules is called thermal energy. |
| These forces are due to the dipole of one or both the given molecules. | These forces are due to the motion of particles. |
| Greater intermolecular forces lead to the substance being in the solid state. | Greater thermal interactions will not allow the substance to remain in the solid state. |
| These forces hold particles together. | These forces keep particles apart. |
| They do not have any effect due to the temperature, but the boiling point of the substance is directly proportional to the strength of the forces. | Thermal energy is directly dependent/proportional to temperature. |
| Intermolecular forces are weak in the gaseous phase and strongest in solid state. | Thermal forces are weak in solid state and high in the gaseous phase. |
| The volume of the given matter is less when the intermolecular forces are high. | The volume of the given matter is more when the thermal interactions are high. |
| Gases can't be liquefied on compression only due to the strong intermolecular forces. | Gases can be easily liquefied by reducing the thermal energy by lowering the temperature. |
 Predominance of the Intermolecular Forces |  Predominance of the Thermal Interactions |
Question 2: What is Hydrogen Bonding?
Answer:
Hydrogen Bonding is a special unique case of dipole-dipole interaction. Dipole-dipole interactions are the attractive forces on polar molecules. Hydrogen Bonding is found in mostly molecules in which highly polar O-H, H-F, or N-H bonds are present. It is mostly regarded to be limited to Nitrogen, Oxygen and Fluorine, but in some cases, species such as Chlorine also participate in Hydrogen bonding.
Question 3: Explain the interaction energy of Dispersion forces and Dipole-Dipole Interactions.
Answer:
Dispersion Forces or London Forces are those which arise due to the movement of electrons, creating a temporary positive and negative charge. London forces operate for a short distance (~500 pm) and their magnitude depends largely on the polarisability of the particle. The interaction energy of the dispersion forces is inversely proportional to the sixth power of the distance between two particles.
Interaction Energy α 1/x6, where x is the distance between two given particles.
Dipole-dipole interactions are the attractive forces on polar molecules. They are between polar molecules that are mostly of two types. The first type is stationary, while the other is rotating.
The interaction energy of dipole-dipole interactions is inversely proportional to the third power of the distance between two particles in the case of stationary polar molecules.
Interaction Energy α 1/x3, where x is the distance between two given particles.
The interaction energy of dipole-dipole forces varies inversely to the sixth power of the distance between two particles in the case of rotating polar molecules.
Interaction Energy ∝ 1/x6, where x is the distance between two given particles.
Question 4: Why does ice have a lower density than water?
Answer:
Hydrogen Bonding affects the physical properties of compounds. Ice has hydrogen bonding as intermolecular forces. Thus, it has a lower density than water because of hydrogen bonding and cage-like structure of ice.
Ice has hexagonal three-dimensional crystal structure (as per X-ray crystallographic data). This hexagonal crystal structure is formed due to intermolecular hydrogen bonding.
When ice melts, most of the hydrogen bonds break and some of the empty spaces are occupied by water molecules. Liquid water molecules are thus more closely packed together than molecules in ice. Thus, ice has a lower density than water.
Question 5: Water has maximum density at 4o Celsius. Why?
Answer:
Water molecules in ice exist in a crystal lattice with a lot of empty space.
When ice melts into liquid water, the density of the water increases as the structure starts to break and collapse. As we increase the temperature, the molecules start moving faster and get further apart. As the temperature increases, the density decreases. At temperatures nearing 0oC, water still has several ice-like clusters. As the temperature of warm water decreases, the water molecules slow down and the density increases. At 4oC, the clusters start forming. The molecules are still slowing down and coming closer together, but the formation of clusters makes the molecules be further apart. Cluster formation is the bigger effect, so the density starts to decrease. Thus, the density of water is a maximum at 4oC.
Question 6: What is the strength of hydrogen bonds dependent on?
Answer:
Strength of Hydrogen Bonds depends on the coulombic interaction between the lone-pair electrons of one electronegative atom of a molecule and the hydrogen atom of another molecule.
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Chemical Formula of Water - Structure, Properties, Uses, Sample QuestionsHydrogen (H) has unique kind properties that are not like some other component on our planet, close to 66% of our Universe's mass is made out of this unique component. It is both electropositive as well as electronegative, as it structures hydrogen particles (H+)as well as hydride particles (H-). Hy
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Dihydrogen as Fuel - Definition, Uses, ExamplesHydrogen is the first element on the modern periodic table. It has the simplest atomic structure as compared to all other elements. In atomic form, it has one proton and one electron. On the other hand, in elemental form, it exists as a diatomic (H2) molecule called dihydrogen. If Hydrogen loses its
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Chapter 10 S-block Elements
Alkali MetalsAlkali metals are the first group of s-block elements that are found on the leftmost side of the periodic table. Alkali metals are the most electropositive elements on the periodic table as they easily lose electrons. These metals formed various useful compounds with halides, oxygen, and sulfur. Alk
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Characteristics of the Compounds of Alkali MetalsThere are a large number of elements around us having different properties and different uses based on those properties. For using these elements, properties are important so there should be some table to group these elements. This table is known as a periodic table which is created by using the wor
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Anomalous Behavior of Lithium and BerylliumElements are arranged in a periodic table row-wise and column-wise according to similarities in their chemical and physical properties. The elements in the first column are known as Group 1 elements which have the following elements lithium, sodium, potassium, rubidium, Caesium and Francium. All the
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Some Important Compounds of SodiumSodium is a soft metal, it is the eleventh element in the periodic table. It is represented by the Na symbol and the atomic number of sodium is 11 it belongs to the family of s-block elements in the periodic table. Sodium is the sixth most abundant element. Its amount in the earth's crust is nearly
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What is Sodium Chloride? - Definition, Preparation, Properties, UsesSalt's chemical name is sodium chloride. Sodium is an electrolyte that regulates your body's water content. Sodium is also involved in nerve impulses and muscle contractions. Sodium chloride is a medication used to treat or prevent sodium loss caused by dehydration, excessive sweating, or other fact
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Alkaline Earth MetalsAlkaline Earth Metals are Group 2 elements which includes a collection of elements Beryllium, Magnesium, Calcium, Barium, Strontium, and Radium, which are soft silver metals with a less metallic quality than Group 1 alkali metals. All the heavier metals in Group II such as Ca, Sr, Ba, and Ra, share
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Characteristics of the Compounds of Alkaline Earth MetalsAll the elements that exist in nature are arranged in a periodic table after several years of research work, these are placed in groups and rows based on some predefined criteria. Some elements may not follow the criteria but still, they are placed in the same column or group due to their similariti
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Anomalous Behavior of Lithium and BerylliumElements are arranged in a periodic table row-wise and column-wise according to similarities in their chemical and physical properties. The elements in the first column are known as Group 1 elements which have the following elements lithium, sodium, potassium, rubidium, Caesium and Francium. All the
8 min read
Some Important Compounds of CalciumCalcium is a reactive alkaline earth metal that when exposed to the air generates a black oxide-nitride coating. Its physical and chemical properties are most similar to those of strontium and barium, its heavier homologues. After iron and aluminium, it is the fifth most abundant element in the Eart
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Plaster of ParisPlaster of Paris is a well-known chemical compound that is widely used in sculpting materials and gauze bandages. While we have seen numerous applications of this substance in our daily lives, Plaster of Paris is a white powdered chemical compound that is hydrated calcium sulphate that is typically
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Biological Importance of Alkali and Alkaline Earth MetalsElements are arranged in a periodic table row-wise and column-wise according to similarities in their chemical and physical properties. The elements in the first column are known as Group 1 elements which have the following elements lithium, sodium, potassium, rubidium, Caesium and Francium. All the
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