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An LED dancing penguin in Locomotive Park, Lewiston Idaho. Light! How an LED works. Created by Dr. Jesse Huso & Dr. Leah Bergman Department of Physics, University of Idaho. Supported by: The National Science Foundation under Grant No. DMR-1202532 .
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An LED dancing penguin in Locomotive Park, Lewiston Idaho. Light!How an LED works Created by Dr. Jesse Huso & Dr. Leah Bergman Department of Physics, University of Idaho Supported by: The National Science Foundation under Grant No. DMR-1202532
Modern lighting is based on a device called a “Light Emitting Diode”. • We usually just call these LEDs (pronounced “el eedees”). • LEDs are useful because they’re small, energy efficient and long lasting. Lighting Image courtesy of energystar.gov
LEDs come in many colors. • These colors are determined by what the LED is made of, as we will see. Color (in brief) The Visualizer Tree Locomotive Park, Lewiston Idaho
Colored lens (protects other parts and directs the light) • While LEDs come in many shapes and sizes, they all work in similar ways. • Here are some parts. • When we apply electricity to the wires on the LED, it lights up! Semiconductor and reflector (more soon!) Wires for electricity, called the anode and cathode Parts of an LED Anode Cathode
Let’s take off the lens… • And now let’s zoom in… • The tiny piece of semiconductor, called a die, is what emits the light we see. • There is also a reflector around the die to help light get out. • Let’s take an even closer look. Inside an LED
The semiconductor portion is made of two parts: a layer of semiconductor called “p-type” a layer of semiconductor called “n-type” There are also metal layers connected to the anode and cathode wires. These metal layers allow us to apply electricity to the semiconductor. Anode p-type n-type The Semiconductor Die Cathode
Depletion region • Let’s look at the semiconductor closely. • The n-type region has many extra electrons. • The p-type region is missing electrons: we call these “holes”. • The thin boundary is called the “depletion region”. p-type n-type Electrons and holes
If we apply electricity across the die in the right direction… • The electrons and holes will move toward each other. • They recombine and the semiconductor emits light from the depletion region! Light p-type n-type Light Electrons and holes
In order to understand Why the die emits light, we have to discuss some Materials physics
Conduction band • Any semiconductor can be understood with a simple picture called an “energy band diagram”. • There are many energy states electrons can occupy. • The lower energy states are called the “Valence band”. • The higher energy states are the “Conduction band”. • The region with no energy states is called the “band gap”. Energy states Band gap Valence band A Semiconductor (In Brief)
Conduction band • Normally, the valence band is full of electrons and the conduction band is empty. • When a semiconductor is doped as n-type, extra electrons are added, and these electrons begin to fill up the conduction band. n-type Valence band Semiconductordoping
Conduction band • p-type doping is similar to n-type, but electrons are removed, leaving empty states in the valence band. • We call these empty states “holes”. Missing electrons p-type Valence band Semiconductordoping
p-type n-type Recall the n-type side has extra electrons in the conduction band… When we sandwich the n‐type and p-type layers, we get an energy band structure like this Conduction band and the p-type side is missing electrons in the valence band. Band gap Valence band p-type n-type Depletion region
n-type p-type p-type n-type Depletion region When we apply electricity, we change the shape of the energy bands, making them look more like this. The electricity shrinks the depletion region and makes it easier for the electrons to find the holes. Depletion region
Light p-type n-type Light Conduction band The electrons combine with the holes and give off energy as the light we see. Light Band gap Depletion region Valence band
Large band gap Light Medium band gap Light Small band gap Light Aluminum gallium Indium phosphide Indium gallium nitride Aluminum gallium arsenide How much energy is released by the electrons is what determines the color of the LED. This amount of energy is in turn determined by the band gap. Each semiconductor material has a different band gap, and thus emits a different color.
And that’s how an LED works! We hope you learned something. MATERIALS PHYSICS IS AWESOME!
Supported by The National Science Foundationunder grant No. DMR-1202532