What are adhesives and how do they work?
An adhesive is a compound that adheres or bonds two items together. Adhesives may come from either natural or synthetic sources. Some modern adhesives are extremely strong, and are becoming increasingly important in modern construction and industry.
The first adhesives were natural gums and other plant resins or saps. It was believed that the Sumerian people were the first to use them until it was discovered that Neanderthals as far back as 50,000 years made adhesives from birch bark. The discovery of 6000-year-old ceramics brought evidence to archaeologists about the first practical uses and ingredients of the first adhesives. Most early adhesives were animal glues made by rendering animal products such as horse teeth. During the times of Babylonia, tar-like glue was used for gluing statues. The Egyptians made much use of animal glues to adhere furniture, ivory, and papyrus. The Mongols also used adhesives to make their short bows, and the Native Americans of the eastern United States used a mixture of spruce gum and fat as adhesives to fashion waterproof seams in their birchbarkcanoes.
In medieval Eurasia, egg whites were used as glue to decorate parchments with gold leaf. The first actual glue factory was founded in Holland in the early 1700s. In the 1750s, the English introduced fish glue. As the modern world evolved, several other patented materials, such as bones, starch, fish, and casein, were introduced as alternative materials for glue manufacture. Modern glues have improved beyond recognition, with improved flexibility, toughness, curing rate, and chemical resistance.
An adhesive is a substance that has the capability to hold materials together. The manner by which adhesives are able to serve this function is due to a surface attachment that is resistant to separation. A bond occurs when the adhesive molecules adsorb onto a solid surface and chemically react with it. Cement, mucilage, glue and paste are organic materials that form adhesive bonds.
Adhesive materials are made up of polymers. Polymers are huge molecules, or macromolecules, that are formed by the linking of thousands of simpler molecules known as monomers. When a polymer is formed the chemical reaction that takes place is called polymerization. Polymerization and adhesive bond formation take place at the same time creating the means to keep surfaces together.
Types of Adhesives
We still use natural products as adhesives today, though we 're much more likely to use artificial adhesives made in a chemical plant —polyvinyl acetate (PVA), phenol formaldehyde (PH), ethylene vinyl acetate (EVA), and cyanoacrylate ("super glue") to name just four. Many modern adhesives are called synthetic resins for no good reason other than that resin (a gooey substance found in pine trees and other plants) was one of the first widely used.
Forces make things stick
People stick to Earth 's surface even though the planet is rotating at high speed, and even there 's no glue on the soles of our feet. The reason is simply that gravity bonds us to the planet with enough force to stop us whizzing off into space. But gravity isn 't enough to keep us permanently in place. If we supply bigger forces, for example by using our muscles to move our legs and jump in the air, we can "unstick" ourselves and go somewhere else. Life on Earth is a bit like being a giant living Post-It® note—only with legs!
So you don 't always need a blob of adhesive to stick things together. That much is blindingly obvious whenever it rains on your window. Gravity tries to pull the water down to the bottom of the glass, and sooner or later it usually wins, but two interesting things try to stop it. First, water molecules naturally stick to one another, so they clump together in big droplets on the window. The forces that make them do this are called cohesive forces (and the process involved is called cohesion). Second, the water droplets also stick to the glass without any help or glue. Different forces are at work here known as adhesive forces (the sticking process is called adhesion). Now the cohesive forces must be bigger than the adhesive forces or the water wouldn 't form droplets at all. Instead, it would just spread out in a very thin layer on the glass—much as oil does when you spread it on water. But the adhesive forces are still pretty strong: some of the water droplets that stick to your window are surprisingly big.
Next time it rains, watch how the water behaves. See how the rain naturally clumps into droplets (because of cohesion), which remain on the glass (because of adhesion). The drops fall down the window only when they 're too heavy for the adhesive forces to keep them in place (when the gravitational force pulling them down is greater than the adhesive force holding them up). Notice how they run down the window in distinct tracks, with droplets following existing, watery paths. That 's because the water drops that are falling are trying harder to stick to the water that 's already there rather than to the glass (cohesion at work again). Why does the rain form those streaky channels? Because as drops fall down the glass, cohesive forces tear some of the water molecules away from them, leaving some behind that are small enough to stick to the glass (adhesion again).
Adhesive and cohesive forces in glues
What does all this have to do with adhesives? Adhesive and cohesive forces are also at work in glues. Let 's say you want to stick together two bits of wood, A and B, with an adhesive called C. You need three different forces here: adhesive forces to hold A to C, adhesive forces to stick C to B, and cohesive forces to hold C together as well. The first two are pretty obvious: the glue has to stick to each of the materials you want to hold together. But the glue also has to stick to itself! If that 's not obvious, think about sticking a training shoe to the ceiling. The glue clearly has to stick both to the training shoe and to the ceiling. But if the glue itself is weak, it doesn 't matter how well it sticks to the shoe or the ceiling because it will simply break apart in the middle, leaving a layer of glue behind on both surfaces. That 's a failure caused when the adhesive forces are greater than the cohesive ones and the cohesive forces aren 't big enough to overcome the pull of gravity.
Jam sandwiches may not be the first thing to spring to your mind when you think about adhesives, but the jam is working as a kind of glue. It 's made of sugar and water: a classic adhesive recipe used since ancient times. If you use fairly strong bread, you can pick up a jam sandwich by just one corner of one slice and the whole thing will stay together in your hand—thanks to the jammy glue. Jam has pretty high cohesive forces (that 's why jam can be hard to dig out of the jar with your knife), but its adhesive forces are high too.
If you butter two pieces of bread and cover one slice with jam, then close up the sandwich, then peel it apart, you 'll find there 's some jam left on both surfaces. As you pull apart the sandwich, you 'll find the jam breaking itself in two in lots of little strands. That 's because the adhesive forces are stronger than the cohesive ones. Your jam sandwich "fails" due to a failure of cohesion.
How do cohesive forces work?
Now we know that adhesives work through adhesive and cohesive forces, we need to understand a bit more about how those forces themselves work. Let 's start with cohesive forces. Water molecules join together with others because they 're not symmetrical. One end has a slight positive charge, the other end has a slight negative charge, and the positive and negative ends of different molecules snap together like the opposite ends of magnets. That 's a kind of electrical or electrostatic bonding. In metals, the atoms are strongly held together in a rigid crystal structure called a lattice (a bit like scaffolding or a climbing frame with atoms at the joins and invisible bars holding them together). You can easily separate one "piece" of water from another (by lifting some out with a spoon): the cohesive forces are quite weak. But you can 't easily separate one bit of iron from another (with a spoon or anything else) because the cohesive forces are incredibly strong.
Water and iron are both pretty useless as glues, but for quite different reasons. Water could be an excellent glue because it sticks quite well to other substances (such as glass), but its cohesive forces are incredibly weak. You can stick paper to the wall by wetting it first, but you can usually peel it off quite easily too. When you peel, you 're breaking the weak cohesive forces that hold one water molecule to another. Iron is no good as a glue because it 's too preoccupied with sticking to itself to stick to anything else. All its forces are occupied internally, fixing one iron atom to another in a strong cohesive structure. There 's nothing it can use to attach itself to other objects: its adhesive forces are virtually nonexistent.
How do adhesive forces work?
Now for the real question: what makes a gluey substance stick to something else? You may be surprised to hear that there 's no single, simple answer—but that 's not so surprising if you consider how many different types of glue there are and how many different ways in which we can use them. For each different glue, and each different surface we use it on, scientists think a combination of different factors are at work holding the two together. But the plain truth is: no-one exactly what 's going on in every case.
One of the main factors is called adsorption. When you spread adhesive, it wets the surface you apply it to. Lots of very weak electrostatic forces between the glue molecules and the molecules in the surface (called Van der Waals forces for the physicist Johannes Diderik van der Waals (1837–1923) who discovered them) hold the two things together. For adhesives to work well like this, they have to spread thinly and wet the surfaces very well. There 's no actual chemical bond between the glue and the surface it 's sticking to, just a huge number of tiny attractive forces. The glue molecules stick to the surface molecules like millions of microscopic magnets.
In some cases, adhesives can make much stronger chemical bonds with the materials they touch. For example, if you use certain glues on certain plastics, the glue and the plastic actually merge together to form a very strong chemical bond—they effectively form a new chemical compound at the join. That process is called chemisorption.
Absorption and chemisorption are chemical connections between the glue and the surface. Glues can also form physical (mechanical) bonds with the surface they 're sticking to. Suppose the surface is porous (full of holes). The glue can seep into those holes and grip through them, like a climber 's fingers grabbing holes in a rock face. That 's called the mechanical theory of adhesives.
Another theory of how glues work suggests the adhesive can diffuse into the surface and vice-versa, with molecules swapping over at the join and mingling together. This is called the diffusion theory.