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  • In this phone, there are nearly 100 million transistors, in this computer there's over

  • a billion. The transistor is in virtually every electronic device we use: TV's, radios,

  • Tamagotchis.

  • But how does it work?

  • Well the basic principle is actually incredibly simple. It works just like this switch, so

  • it controls the flow of electric current.

  • It can be off, so you could call that the zero state or it could be on, the one state.

  • And this is how all of our information is now stored and processed, in zeros and ones,

  • little bits of electric current. But unlike this switch, a transistor doesn't have any

  • moving parts. And it also doesn't require a human controller. Furthermore, it can be

  • switched on and off much more quickly than I can flick this switch. And finally, and

  • most importantly it is incredibly tiny. Well this is all thanks to the miracle of semiconductors

  • or rather I should say the science of semiconductors.

  • Pure silicon is a semiconductor, which means it conducts electric current better than insulators

  • but not as well as metals. This is because an atom of silicon has four

  • electrons in its outermost or valence shell. This allows it to form bonds with its four

  • nearest neighbours,

  • Hidey ho there! G'day

  • Wasaaaaap!?

  • So it forms a tetrahedral crystal.

  • But since all these electrons are stuck in bonds, few ever get enough energy to escape

  • their bonds and travel through the lattice. So having a small number of mobile charges

  • is what makes silicon a semi-conductor.

  • Now this wouldn't be all that useful without a semiconductor's secret weapon -- doping.

  • You've probably heard of doping, it's when you inject a foreign substance in order to

  • improve performance.

  • Yeah it's actually just like that, except on the atomic level.

  • There are two types of doping called n-type and p-type. To make n-type semiconductor,

  • you take pure silicon and inject a small amount of an element with 5 valence electrons,

  • like Phosphorous.

  • This is useful because Phosphorous is similar enough to silicon that it can fit into the

  • lattice, but it brings with it an extra electron. So this means now the semiconductor has more

  • mobile charges and so it conducts current better.

  • In p-type doping, an element with only three valence electrons is added to the lattice.

  • Like Boron. Now this creates a 'hole' - a place where there should be an electron, but

  • there isn't. But this still increases the conductivity

  • of the silicon because electrons can move into it.

  • Now although it is electrons that are moving, we like to talk about the holes moving around

  • -- because there's far fewer of them. Now since the hole is the lack of an electron,

  • it actually acts as a positive charge. And this is why p-type semiconductor is actually

  • called p-type. The p stands for positive - it's positive charges, these holes, which are moving

  • and conducting the current.

  • Now it's a common misconception that n-type semiconductors are negatively charged and

  • p-type semiconductors are positively charged. That's not true, they are both neutral because

  • they have the same number of electrons and protons inside them.

  • The n and the p actually just refer to the sign of charge that can move within them.

  • So in n-type, it's negative electrons which can move, and in p-type

  • it's a positive hole that moves. But they're both neutral!

  • A transistor is made with both n-type and p-type semiconductors. A common configuration

  • has n on the ends with p in the middle. Just like a switch a transistor has an electrical

  • contact at each end and these are called the source and the drain. But instead of a mechanical

  • switch, there is a third electrical contact called the gate, which is insulated from the

  • semiconductor by an oxide layer.

  • When a transistor is made, the n and p-types don't keep to themselves -- electrons actually

  • diffuse from the n-type, where there are more of them into the p-type

  • to fill the holes.

  • This creates something called the depletion layer. What's been depleted? Charges that

  • can't move. There are no more free electrons in the n-type

  • -- why? Because they've filled the holes in the p-type.

  • Now this makes the p-type negative thanks to the added electrons. And this is important

  • because the p-type will now repel any electrons that try to come across from the n-type.

  • So the depletion layer actually acts as a barrier, preventing the flow of electric current

  • through the transistor. So right now the transistor is off, it's like an open switch, it's in

  • the zero state.

  • To turn it on, you have to apply a small positive voltage to the gate. This attracts the electrons

  • over and overcomes that repulsion from the depletion. It actually shrinks the depletion

  • layer so that electrons can move through and form a conducting channel.

  • So the transistor is now on, it's in the one state.

  • This is remarkable because just by exploiting the properties of a crystal we've been able

  • to create a switch that doesn't have any moving parts, that can be turned on and off very

  • quickly just with a voltage, and most importantly it can be made tiny.

  • Transistors today are only about 22nm wide, which means they are only about 50 atoms across.

  • But to keep up with Moore's law, they're going to have to keep getting smaller. Moore's Law

  • states that every two years the number of transistors on a chip should double.

  • And there is a limit, as those terminals get closer and closer together, quantum effects

  • become more significant and electrons can actually tunnel from one side to the other.

  • So you may not be able to make a barrier high enough to stop them from flowing.

  • Now this will be a real problem for the future of transistors, but we'll probably only face

  • that another ten years down the track. So until then transistors, the way we know them,

  • are going to keep getting better.

  • Once you have let's say three hundred of these qubits, then you have like two to the three

  • hundred classical bits. Which is as many particles as there are in

  • the universe.

In this phone, there are nearly 100 million transistors, in this computer there's over

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半導體是如何工作的? (How Does a Transistor Work?)

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    hzd_zw2004 發佈於 2021 年 01 月 14 日
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