The purpose of a heatsink is to transfer heat away from an item and get rid of it into the atmosphere.

The problem we have here is that transferring heat from a small piece of metal into the surrounding air is actually quite tricky, as it takes a lot of time for the heat to transfer from the item into the air.

If you consider something like a computer processor that only had a surface area of a few centimetres squared, it can’t generate heat quicker than it can transfer it into the air.

This is all dependent on the surface area of the item that is radiating the heat. If one square centimeter of surface area can radiate a certain amount of heat per minute, then two square centimeters can radiate twice that amount.

The other important detail is that metals is a very good thermal conductor – heat up one end of a bit of metal and it will quickly distribute that heat over the full piece.

A heat sink combines those two details to help cool something down. Firstly, the fact that the heat sink is made of thermally conductive metal means that the heat produced by the item it is attached to will quickly get absorbed into the heat sink and distributed throughout its body.
Next, the finned design of the heat sink means the metal now has an absolutely huge surface area exposed to the air around it – the surface area of each fin added together. While each square centimeter of surface area can still only radiate a small amount of heat, if you have enough square centimeters all radiating small amounts of heat at the same time, that can add up to quite a significant amount.

The one other detail to remember is that sticking on a heat sink and transferring all of the heat an item is producing into the surrounding air will only really result in creating a bubble of hot air around your heat sink, at which point the air cannot absorb any more heat and it all stops working. So what we want to do is remove the hot air and replace it with cold air instead – by pointing a fan through the fins of the heat sink, this creates a lot of air movement and helps remove the heat more effectively.

The purpose of a heatsink is to transfer heat away from an item and get rid of it into the atmosphere.

The problem we have here is that transferring heat from a small piece of metal into the surrounding air is actually quite tricky, as it takes a lot of time for the heat to transfer from the item into the air.

If you consider something like a computer processor that only had a surface area of a few centimetres squared, it can’t generate heat quicker than it can transfer it into the air.

This is all dependent on the surface area of the item that is radiating the heat. If one square centimeter of surface area can radiate a certain amount of heat per minute, then two square centimeters can radiate twice that amount.

The other important detail is that metals is a very good thermal conductor – heat up one end of a bit of metal and it will quickly distribute that heat over the full piece.

A heat sink combines those two details to help cool something down. Firstly, the fact that the heat sink is made of thermally conductive metal means that the heat produced by the item it is attached to will quickly get absorbed into the heat sink and distributed throughout its body.
Next, the finned design of the heat sink means the metal now has an absolutely huge surface area exposed to the air around it – the surface area of each fin added together. While each square centimeter of surface area can still only radiate a small amount of heat, if you have enough square centimeters all radiating small amounts of heat at the same time, that can add up to quite a significant amount.

The one other detail to remember is that sticking on a heat sink and transferring all of the heat an item is producing into the surrounding air will only really result in creating a bubble of hot air around your heat sink, at which point the air cannot absorb any more heat and it all stops working. So what we want to do is remove the hot air and replace it with cold air instead – by pointing a fan through the fins of the heat sink, this creates a lot of air movement and helps remove the heat more effectively.

The purpose of a heatsink is to transfer heat away from an item and get rid of it into the atmosphere.

The problem we have here is that transferring heat from a small piece of metal into the surrounding air is actually quite tricky, as it takes a lot of time for the heat to transfer from the item into the air.

If you consider something like a computer processor that only had a surface area of a few centimetres squared, it can’t generate heat quicker than it can transfer it into the air.

This is all dependent on the surface area of the item that is radiating the heat. If one square centimeter of surface area can radiate a certain amount of heat per minute, then two square centimeters can radiate twice that amount.

The other important detail is that metals is a very good thermal conductor – heat up one end of a bit of metal and it will quickly distribute that heat over the full piece.

A heat sink combines those two details to help cool something down. Firstly, the fact that the heat sink is made of thermally conductive metal means that the heat produced by the item it is attached to will quickly get absorbed into the heat sink and distributed throughout its body.
Next, the finned design of the heat sink means the metal now has an absolutely huge surface area exposed to the air around it – the surface area of each fin added together. While each square centimeter of surface area can still only radiate a small amount of heat, if you have enough square centimeters all radiating small amounts of heat at the same time, that can add up to quite a significant amount.

The one other detail to remember is that sticking on a heat sink and transferring all of the heat an item is producing into the surrounding air will only really result in creating a bubble of hot air around your heat sink, at which point the air cannot absorb any more heat and it all stops working. So what we want to do is remove the hot air and replace it with cold air instead – by pointing a fan through the fins of the heat sink, this creates a lot of air movement and helps remove the heat more effectively.

What is comes down to is surface area.

In an object of a fixed size, the only way to increase the amount of it in contact with the environment is to make it more convoluted and wrinkly. Higher surface areas interact more with their environment.

In the case of a heat sink, the high surface area allows for more heat to dissipate.

Other examples of high surface area are sponges. They use extra surface area to absorb water. Your intestines are wrinkly on the inside to better absorb nutrients. Your lungs have lots of little pockets to better absorb oxygen.

Sometimes the opposite is true, and something is smooth to conserve heat. This is why we don’t have wrinkly thermoses and tea kettles.

What is comes down to is surface area.

In an object of a fixed size, the only way to increase the amount of it in contact with the environment is to make it more convoluted and wrinkly. Higher surface areas interact more with their environment.

In the case of a heat sink, the high surface area allows for more heat to dissipate.

Other examples of high surface area are sponges. They use extra surface area to absorb water. Your intestines are wrinkly on the inside to better absorb nutrients. Your lungs have lots of little pockets to better absorb oxygen.

Sometimes the opposite is true, and something is smooth to conserve heat. This is why we don’t have wrinkly thermoses and tea kettles.

What is comes down to is surface area.

In an object of a fixed size, the only way to increase the amount of it in contact with the environment is to make it more convoluted and wrinkly. Higher surface areas interact more with their environment.

In the case of a heat sink, the high surface area allows for more heat to dissipate.

Other examples of high surface area are sponges. They use extra surface area to absorb water. Your intestines are wrinkly on the inside to better absorb nutrients. Your lungs have lots of little pockets to better absorb oxygen.

Sometimes the opposite is true, and something is smooth to conserve heat. This is why we don’t have wrinkly thermoses and tea kettles.