Molecules may attract or repel each other. This is called an interaction. In chemistry, an interaction is when molecules affect each other. In many cases, interaction is when molecules are attracted to each other.

Interactions are different from molecules joining together to form covalent bonds. If a new bond is created by an organic chemical reaction, an entirely new molecule is created. These bonds are covalent bonds. However, the molecules remain in the same form, but they attract each other and try to stick together, which is called an interaction.

This is called intermolecular forces (IMF: intermolecular interaction). Molecules interact with each other and try to stick together.

There are several types of intermolecular forces. Typical examples are dipole interactions, hydrogen bonds, van der Waals forces, and hydrophobic interactions (hydrophobic effects). Since there are different types of intermolecular interactions, we will explain how they are bonded together.

Polarization Caused by Differences in Electronegativity

Broadly speaking, non-covalent bonds are intermolecular forces. Although the molecules are independent of each other, they are still attached to each other by other forces, without forming a strong covalent bond. Therefore, when energy is applied externally, the molecules that are attached to each other are detached from each other.

The first step in learning about these intermolecular interactions is to understand polarization. Since we learn about polarization in high school chemistry, we should be able to understand it without any problems. Differences in electric density are caused by differences in electronegativity, which is what polarization is all about.

Atoms with strong electronegativity, for example, are known to be oxygen and nitrogen atoms and halogen atoms. When these atoms are bound to carbon, the same molecule can be divided into positive and negative charges.

Examples of polarization are known to include water, ammonia, and hydrogen chloride (HCl).

Polarization is the phenomenon of the same molecule being split into positive and negative charges. All you need to understand is that the difference in electronegativity results in a positive and negative charge.

Dipole Moments in Polarization: Polar and Nonpolar Molecules

Even though the polarization causes a difference in charge, the degree of charge bias is different for different molecules. Such a polarization intensity (the degree of charge bias) is called the dipole moment.

The greater the polarization, the stronger the polarity. As a result, the dipole moment is larger.

In a dipole moment, you mark a vector from negative to positive charge. You don’t have to think too deeply about the meaning of the arrows to note them. In short, understand that the dipole moment is to note how large or small the polarization is.

For reference, in organic chemistry, it is important to capture the movement of electrons. Starting from an atom with a negative charge, it attacks other molecules and causes an organic chemical reaction.

Therefore, dipole moments are not used in organic chemistry. When representing polarization (electron density bias), we draw arrows from positive to negative. The dipole moment is the opposite direction of the arrow. It is common organic chemistry to think of an atom with a negative charge as the starting point.

-The Concept of Polar Molecules (Permanent Dipoles) and Nonpolar Molecules

So, does an atom with high electronegativity always have polarity when it is bonded? This does not necessarily mean that they are polarized. There are some molecules that are not polarized. Molecules that are symmetrical do not have polarization.

For example, carbon dioxide (CO2) is symmetrical, so it is not polarized. Similarly, methane, which has a tetrahedral shape, is not polarized.

Polarized molecules, such as water and ammonia, are called polarized molecules (permanent dipoles). On the other hand, nonpolarized molecules such as carbon dioxide and methane are called nonpolar molecules.

Molecules Attract Each Other Through Dipole Interactions: Keesom Interactions

What happens when molecules are polarized by polarization? Molecules become attracted to each other. Parts with positive and negative charges attract each other by interacting with each other. On the other hand, positive and positive charge molecules repel each other. The same is true for negative and negative charges.

In such cases, the attraction of these charges to each other due to polarization is called dipole interaction.

When the dipoles are attracted to each other by the charge of the ions, this is called ion-dipole interaction. When dissolved in a solution, compounds that exist as ions will attract dipoles.

When dipoles are attracted to dipoles, it’s called dipole-dipole interaction (Keesom interaction). Compared to ions, the difference in charge due to the dipoles is small. Therefore, the force of the dipole-dipole interaction is weaker than that of the interaction between ions and dipoles.

Interaction by Induced Dipoles: Dipole-Induced Dipole Interaction

So neutral molecules do not interact? One would think that neutrals would not interact with each other, because if they were not dipoles, they would not have a positive or negative charge. However, molecules with dipole and neutral molecules do interact and attract each other.

What happens if you put a polarized molecule near a neutral molecule? Under the influence of the dipole, the neutral molecule will produce a charge bias within the molecule. In other words, a dipole is created.

When a dipole is produced under the influence of another dipole (a polar molecule), it is called an induced dipole. When an induced dipole is produced, it interacts with the dipole and pulls on each other. This is known as dipole-induced dipole interaction (Debye interaction).

In polarized molecules, even neutral molecules will attract each other by inducing the induced dipole.

London Dispersion Force Induced Dipole

In contrast, how can neutral molecules (nonpolarized molecules) not interact with each other? Actually, even nonpolarized molecules will interact and attract each other.

It seems odd that nonpolarized molecules would interact with each other. But even within the same molecule, electrons don’t stay in one place; they exist in many different places within the molecule.

So, let’s try to capture a single moment in time. Just as you take a photograph of a moment, you can discover the bias of electrons in a molecule by capturing a specific moment. As a result of this instantaneous electron bias, even neutral molecules become momentarily polarized and have a dipole.

These instantaneous dipoles affect other nonpolar molecules, causing induced dipoles. As a result, even if only neutral molecules exist in the space, they will interact with each other. This is called the London dispersion forces.

Neutral substances are known to attract each other, which is called the van der Waals force. It is important to understand that the van der Waals force for nonpolar molecules is almost entirely due to the London dispersion forces.

Hydrogen Bonds Occur with Oxygen, Nitrogen and Fluorine

Once you learn about these polarization and dipole moments, you will be able to understand hydrogen bonds. A hydrogen bond is literally a bond that attracts and bonds with each other by interacting with hydrogen. While not as strong as a covalent bond, a hydrogen bond produces a strong force.

The greater the degree of polarization and the greater the dipole moment, the stronger the mutual attraction. When considered in terms of the degree of polarity, the polarization tends to increase when hydrogen is bonded to an atom with a high degree of electronegativity.

Specifically, when hydrogen atoms are bonded to oxygen (O), nitrogen (N), and fluorine (F) atoms, the polarization is very large. As a result, the dipoles created in the molecule strongly attract each other, and a strong bond is formed through the dipole-dipole interaction.

The hydrogen bond is a type of dipole-dipole interaction. However, of all dipole-dipole interactions, the hydrogen bond is the one with the greatest degree of polarization and strongest attraction. A hydrogen atom attracts another oxygen atom, a nitrogen atom, or a fluorine atom, resulting in the formation of a hydrogen bond.

A hydrogen bond can attract another molecule, or it can form a hydrogen bond within a molecule. It is as follows.

A hydrogen bond is an interaction that involves a hydrogen atom and an atom with a high degree of electronegativity, which strongly attracts each other, although it is binding by dipoles.

Proteins and DNA Are Hydrogen-Bonded

Then, why do we consider only hydrogen bonds separately among dipole interactions? This is because the intermolecular interactions (intermolecular forces) caused by hydrogen bonds are very important.

For example, there are many proteins in our bodies. Why do proteins have a particular shape? This is because of the hydrogen bonds involved. Proteins are formed when many amino acids are combined together. A protein can be described as a single long chain of amino acids.

However, if the proteins are the same protein (the same amino acid sequence), they all have the same structure when they are folded. This is because the hydrogen bonds within the proteins interact and attract each other.

The same can be said for DNA, which is known to be formed by two base pairs. These are connected by hydrogen bonds, resulting in the double-helix structure of DNA.

Understanding hydrogen bonding is essential, not only for bonding in molecules and organic chemical reactions but also for understanding what happens in living organisms.

Van der Waals Forces that Bind Molecules Together

Compared to the dipole interactions and hydrogen bonds we have described, the van der Waals force is weaker in its attraction to each other.

We have explained that the occurrence of polarization leads to dipole interactions and hydrogen bonds. However, even neutral molecules have the ability to attract each other. This is the van der Waals force as mentioned above. As already explained, most of the forces that attract nonpolar molecules to each other are the London dispersion forces.

The London dispersion force causes induced dipoles to attract neutral molecules to each other as van der Waals force.

Van der Waals forces exist in almost all materials. This means that all molecules, even nonpolar ones, will attract each other.

Rebound by Leonard-Jones Potential

It can be said that the distance between the molecules is important in the Van der Waals force. Neutral molecules attract each other, but the farther they are from each other, the weaker the attraction. It is easier to attract things close to each other than it is to attract things far away.

So, the closer the molecules are to each other, the stronger the force of the Van der Waals force becomes? Actually, the closer they are, the more repulsive force is applied.

Molecules have electrons. The electrons repel each other, so when they get too close together, the electrons repel each other, and the energy becomes higher.

If the neutral molecules are far away from each other, there is no attraction, and the energy state is high (the energy approaches zero). On the other hand, if the molecules are too close to each other, the energy is high because of the repulsion that is created. The van der Waals force favors a state that is neither too far nor too close.

If the distance between neutral molecules is defined as r, then the attraction of the Van der Waals force is inversely proportional to the 6th power of r. The closer the distance is, the stronger the attraction is, inversely proportional to the 6th power of r.

On the other hand, the repulsive force of the van der Waals force is inversely proportional to the 12th power of r. The closer the distance between the molecules, the stronger the repulsive force becomes, inversely proportional to the 12th power of r. Try to understand this law as such.

The Leonard-Jones potential is the one that takes into account both the attraction and the resilience of the Van der Waals force. The figure above shows the Leonard-Jones potential.

The curve is steeper to the 12th power of r than to the 6th power of r. Therefore, when the molecules are at a good distance from each other, they attract each other, resulting in lower energy. Since the attraction is stronger than the repulsive force, they will attract each other by van der Waals forces.

On the other hand, if the distance is too close, the energy due to the repulsive force will be very high. Since the resilience force is stronger than the attraction force, they will repel each other if they are too close together.

It’s very difficult to think of just the term Leonard-Jones potential. So when you realize that the Leonard-Jones potential is the one that takes into account both the attraction and repulsion forces between molecules, you can understand what it means.

Increase in Entropy Due to Hydrophobic Interactions (Hydrophobic Effect)

In terms of intermolecular interactions (intermolecular forces), hydrophobic interactions are also important as a force of attraction between molecules. Let’s understand that hydrophobic interactions (hydrophobic effect) are the forces of attraction between fat-soluble molecules to each other.

The most familiar liquid in our lives is water. Water and oil do not mix with each other because they are completely different in nature. If there are two oils, they will stick to each other to avoid the water.

The hydrophobic effect is the force that causes oils to try to stick to each other. These hydrophobic interactions (hydrophobic effect) are also related to entropy increase.

If left unchecked, the progression to a messy state is called entropy increase. If you neglect your garden, weeds will grow and it will become rough. If you don’t keep things tidy, your room will become cluttered. By natural law, things all move to become cluttered.

This is the same with oil. When the oil is in water, water will be present around the oil. But what if the oils stick together? If we focus on the water that was around the oil (hydrophobic molecules), the number of water molecules that can move around freely increases.

Rather than having several hydrophobic molecules floating around in the water, the number of water molecules that can move around freely is greater when these oils are present in unison. The more water molecules can move around, the more water entropy (clutter) is increased. This is one of the reasons why hydrophobic interactions (hydrophobic effect) occur.

Micelle Formation is an Application of Hydrophobic Interactions

When you study chemistry, you will study micelles. Micelles are formed by compounds that have both hydrophilic and hydrophobic moieties in the same molecule. It is a so-called surfactant. As a familiar example, detergent is a surfactant. Detergents make micelles.

When a surfactant is put into water, the hydrophilic part of the surfactant becomes attached to water. It interacts positively with water through hydrogen bonds and so on.

On the other hand, the hydrophobic groups are kept out of contact with water as much as possible. This is the so-called hydrophobic interaction, which reduces the amount of contact between the hydrophobic group and water. The hydrophobic parts also attract each other by van der Waals forces.

As a result, the micelles begin to form aggregates in the water. Thus, the micelles are stabilized in water.

When micelles are formed in water by the surfactant, the oil (sebum and other dirt) is taken up by the hydrophobic part of the micelles. As a result, the micelles can be used as a detergent to remove grease and dirt. The most obvious application of micelles is in the field of detergents, but micelles are also used in many other fields such as medicine and food.

Molecules Are Attracted to Each Other Due to Intermolecular Forces

When molecules combine, there are several types of bonds, including covalent bonds and ionic bonds (Coulomb force).

Among these bonds, intermolecular interaction (intermolecular force) is the force of attraction between molecules that causes them to stick to each other. Although not as strong as a covalent bond, the molecules are attracted to each other. In these intermolecular interactions, the following are of particular importance.

  • dipole interactions
  • hydrogen bond
  • Van der Waals force
  • Hydrophobic interaction (hydrophobic effect)

Once you understand molecular polarization, you can understand why dipole interactions, hydrogen bonds, and Van der Waals forces occur. Hydrophobic interactions are a slightly different concept, but they are essential when learning about molecular forces

Learn about these types and the differences between them and make sure you understand the effects of intermolecular forces.