The world we live in today is filled with electrical and electronic devices that help us perform tasks with more effectiveness and efficiency.

Within the electrical and electrical world exists a myriad of different components each with their own unique capabilities.

One of these components is the Diode

But, there isn’t just one type of diode out there. It has a number of different variations, and the two commonly used in circuits and devices are the PN Junction and Zener Diodes.

So, what is the difference between a PN Junction and Zener diode? The main difference between a PN Junction diode and a zener diode, is that the PN junction only allows current to flow in one direction, whereas the zener diode allows current to flow in both directions.

Other notable differences include;

  • Schematic Symbol
  • Materials used
  • Doping level and 
  • Application

This article shall take a close look at these two types of diode, as well as a more in-depth look at the key differences. 

What are diodes?

Before we dive into looking at the differences between a PN Junction and Zener diode, it will first help to learn about the diode (however if you are well versed with diodes, you can skip this section). 

Resistors help limit current, capacitors store charge, switches turn circuits on and off, etc.

So what is a diode and what is its purpose?

A diode is a device which is constructed using semiconducting material and only allows current to flow in one direction. 

It acts like an open switch (no current flow) in one direction, and a closed switch (allows current to flow) in the other direction. 

Diodes are passive devices and have a polarity ( have a positive and negative terminal and need to be wired the right way in a circuit).

The positive terminal of the diode is known as the anode, and the negative terminal is known as the cathode

Below is an image of a conventional diode along with its schematic symbol highlighting the terminals. 

Different types of diodes

The diode has a number of different variations, each having unique characteristics that will set them apart from their peers.

These unique characteristics will also make each type of diode suitable for a certain type of application.

The different types of diode include;

  • PN Junction Diode
  • Zener Diode
  • Tunnel Diode
  • Schottky Diode
  • Varactor Diode
  • Diac
  • Triac
  • SCR
  • Light Emitting Diode (LED)
  • Photodiode

This article shall take a closer look at the PN Junction and Zener diode and the key differences between them.

What is a PN junction diode

Let’s start our journey with the PN Junction Diode.

So what exactly is this diode all about? 

They are aptly named PN Junction diodes because they are composed of a p-type and n-type semiconducting material which are fused together and form a junction.

The P-region and N-region are separated by a depletion region

These diodes are also often referred to as rectifier diodes because they are commonly utilized in applications where rectification is necessary (have the ability to convert an alternating current (AC) into a direct current (DC)). 

It is a two terminal device with positive (anode), and negative (cathode) terminals and has the same schematic symbol we saw earlier. 

How a PN junction diode works

PN junction diodes are the simplest of the semiconducting devices and have the ability to only allow current to pass through them in one direction.

This can only happen when they are forward biased.

So what exactly does it mean to be forward biased?

When we talk about diodes, there are three possible modes of operation, or biases;

  • Zero Bias
  • Forward Bias
  • Reverse Bias

Zero bias occurs when there is no voltage applied across the diode.

Forward bias is when a voltage is applied to the diode. However this is when the positive and negative terminals match up with the positive and negative terminals of the voltage source respectively (positive to positive, and negative to negative).

Reverse bias is when a voltage is applied to the diode but in the reverse direction (positive to negative, and negative to positive). 

IV characteristics of diodes

Diodes do not have a linear relationship with voltage, but rather have an exponential  Current (I) – Voltage (V) relationship.

This IV relationship is known as the IV Characteristic and is given in the form of a graph as seen below.

The IV characteristic shows us how the diode performs under zero, forward and reverse bias conditions. 

How a PN junction operates in the forward bias

When discussing the operation of a PN junction diode, we are only concerned about the zero and forward bias conditions (as they can only allow current to flow in the forward direction).

So how does a PN Junction diode work?

To allow current to flow in the forward direction, the diode needs to first be forward biased.

But first, a sufficient amount of voltage needs to be applied in order for current to flow freely. The voltage level required is known as the knee or forward voltage.

For PN junction diodes this is usually 0.3V (Germanium), and 0.7V (Silicon).

When the supply voltage equals (or exceeds) the forward voltage, current starts to flow through the PN junction diode. 

A little increase in voltage after the forward voltage sees a large increase in current.

When a reverse voltage is applied to the PN junction diode making it reverse biased, its depletion layer increases thereby increasing its overall resistance and blocking current flow. 

What is a zener diode  

Next up we have the Zener Diode.

So what awesome powers does this type of diode hold?

Let’s take a look.

The zener diode is also constructed using semiconducting material like the PN Junction diode. However it has the ability to conduct current in the forward and reverse direction.

It has the ability to conduct in the reverse direction thanks to a special heavily doped p-n junction. 

Zener diodes are also two terminal devices with an anode (+) and cathode (-), however their schematic symbol is different. 

The zener diode was discovered by Clarence Zener who discovered its electrical properties and is how it got its name.  

How a zener diode operates

While the PN junction is only limited to allowing current to flow in the forward direction, the zener diode is capable of conducting current in both the forward and reverse direction.

When operating in the forward bias, the zener diode has the same operation as the PN junction diode. 

So it requires a sufficient voltage which equals the forward or knee voltage before it can allow current to start flowing in the forward direction. 

However, if a reverse voltage is now applied to the zener diode thus causing it to be reverse biased its operation changes. 

If we look at the IV characteristic graph from before (in the third quadrant), we can see what happens to current when a reverse voltage is applied.

Initially there is a small leakage current that flows through the zener diode. 

We know that in the forward bias there is a critical voltage known as the knee or forward voltage, which is the amount of voltage needed before current can flow.

In the reverse bias, this voltage is known as the breakdown voltage (Vz)

When the reverse voltage equals, or is greater than the breakdown voltage, a large reverse current flows through the zener diode. 

Key differences between a PN junction diode and a zener diode

Now that we have had a close look at the PN Junction and Zener diode, we can delve into their key differences.

Difference #1 between a PN junction and zener diode: Direction of current flow

The first most obvious and main difference between these two diodes is direction of current flow.

A PN junction diode only has the ability to conduct current in the forward direction (when the voltage applied across its terminals is greater than the forward voltage of the diode).

Zener diodes on the other hand have the capability to conduct current in the forward and reverse direction. 

In the forward bias zener diodes operate the same as PN junction diodes. However, when reverse biased, a small leakage current flows until its breakdown voltage is matched or exceeded, which then sees a steep rise in current. 

PN junction diodes are always used in the forward bias, whereas zener diodes are commonly used in the reverse bias. 

Difference #2 between a PN junction and zener diode: Schematic symbol

There are many different types of components that exist in the electrical and electronic world. Each of them has its own unique purpose.

But, when designing circuits, or analyzing circuit diagrams we need a way of distinguishing between the different types of components (otherwise things would get confusing real fast).

This is where schematic symbols play a crucial role. 

They help us identify particular electrical/electronic components as each of them will have their own unique schematic symbol. 

Since the PN junction and Zener diode are two variations of the diode, and have separate functionalities, each gets its own schematic symbol.

This will help us distinguish between a PN junction and zener diode in circuit diagrams. 

Difference #3 between a PN junction and zener diode: Doping level

Diodes are semiconducting devices that are constructed using, well, semiconductors. 

But what exactly are semiconductors and doping?

Semiconductors are materials which have properties of both a conductor as well as an insulator

Doping of semiconductors is a process used to add or remove the number of electrons and holes in semiconductors.

This process alters the electrical, optical and structural properties of semiconductors. Increasing the doping level of a semiconductor makes it act more like a conductor. 

This is the next difference between a PN junction and Zener diode is their doping levels. 

A PN junction diode has lower doping levels compared to zener diodes which are heavily doped. 

Difference #4 between a PN junction and zener diode: Materials used

The next difference is the materials that each type of diode is composed of. 

Common materials used to construct diodes include Silicon, Germanium and Gallium Arsenide

However, PN junction diodes will only be constructed using a single material, while zener diodes will use a mix of these materials. 

Difference #5 between a PN junction and zener diode: Applications

As you have just seen, while they are both diodes, there are some key differences between the PN junction and zener diode. 

Each has their own unique abilities and is why they share separate applications (which is our next and final key difference).

The PN junction diode is mostly used in the applications seen below;

  • Rectification
  • Voltage-Controlled oscillator
  • Mixing signals
  • Lighting systems
  • Detection of signals 
  • Solar cells

Whereas zener diode can be seen in applications which include;

  • Voltage Regulation
  • Reference elements
  • Surge Suppressors
  • Clipping circuits

PN junction vs Zener; which is better?

So, you need a diode for your circuit. 

What do you choose, the PN Junction or Zener diode?

Which is the better option?

There is no right answer to this as one diode is not better than the other. Picking the right diode comes down to the needs of your application.

Each diode is used for different applications according to how its characteristics best help.

For example, you will not be able to use a PN junction diode for a voltage regulation application, as it will not be able to perform the job.

A zener diode is the best option here.

So, it really depends on the needs of your application when selecting the right diode.