Difference between revisions of "Semiconductors"

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==Conductors and Insulators==
==Conductors and Insulators==
Conductors are able to accomodate an electron flow through them because the electrons in the atoms are not tightly bound to thier atoms. When an electron leaves its atom, it leaves behind '''hole''', which because of the absence of the electron, is positivly charged since the atom started out neutral. This hole can be modeled as a positive charge. As electrons move towards one end of the conductor, they will leave holes at the opposite end, thus creating a "flow" of holes in the direction opposite the electron flow.
Conductors are able to accommodate an electron flow through them because the electrons in the atoms are not tightly bound to their atoms. When an electron leaves its atom, it leaves behind '''hole''', which because of the absence of the electron, is positively charged since the atom started out neutral. This hole can be modeled as a positive charge. As electrons move towards one end of the conductor, they will leave holes at the opposite end, thus creating a "flow" of holes in the direction opposite the electron flow.


[[Image:conductor_diagram.jpg]]
[[Image:conductor_diagram.gif]]


The electrons in insulators are tightly bound to thier atoms, so they cannot flow.
The electrons in insulators are tightly bound to their atoms, so they cannot flow.


[[Image:insulator_diagram.jpg]]
[[Image:insulator_diagram.gif]]


==Semiconductors==
==Semiconductors==
Semiconductors, such as silicon, are somewhere in between a conductor and an insulator. Some electrons in the semi-conducor are allowed to flow, especially when relased by heat or light. Semiconductors allow us to build ''non-linear'' devices, such as computers.
Semiconductors, such as silicon, are somewhere in between a conductor and an insulator. Some electrons in the semi-conductor are allowed to flow, especially when released by heat or light. Semiconductors allow us to build ''non-linear'' devices, such as computers.


We can increase the conductivity of semiconductors by ''doping'', or interspersing atoms with more valence electrons into the lattice structure.
We can increase the conductivity of semiconductors by ''doping'', or interspersing atoms with more valence electrons into the lattice structure.
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For example, we can dope silicon (which as four valence electrons) with arsenic (which has 5 valence electrons). The extra electron in the arsenic atom cannot form a covalent bond with the neighboring atoms, and thus is loosely bound and available as a charge carrier. This creates an '''n-type''' semiconductor, which has negative charge carriers.
For example, we can dope silicon (which as four valence electrons) with arsenic (which has 5 valence electrons). The extra electron in the arsenic atom cannot form a covalent bond with the neighboring atoms, and thus is loosely bound and available as a charge carrier. This creates an '''n-type''' semiconductor, which has negative charge carriers.


We can also dope the silicon with boron or galium, which have 3 valence electrons. The lack of an electron to complete all four covalent bonds the lattice structure leaves a hole into which an electron can fall. This creates a '''p-type''' semiconductor, which has positive charge charriers.
We can also dope the silicon with boron or gallium, which have 3 valence electrons. The lack of an electron to complete all four covalent bonds in the lattice structure leaves a hole that can accept an electron. This creates a '''p-type''' semiconductor, which has positive charge carriers.


===p-n junctions===
===p-n junctions===
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The electrons will jump into the holes across the border:
The electrons will jump into the holes across the border:


[[Image:p_n_junction.jpg]]
[[Image:p_n_junction.gif]]


and will form the depletion zone:
and will form the depletion zone:


[[Image:p_n_junction_depletion_zone.jpg]]
[[Image:p_n_junction_depletion_zone.gif]]


If put a voltage across the semiconductors with the positive voltage on the p-type semiconductor, we will create a '''forward bias'''. The positive voltage will repel the holes, and the negative voltage will repel the electrons, pushing both towards the junction. This movement shrinks the depletion zone, and if our voltage is high enough, the depletion zone will become so thin that electrons will be able to tunnel through it. When this happens, current will be able to flow through the semi-conductors.
If we put a voltage across the semiconductors with the positive voltage on the p-type semiconductor, we will create a '''forward bias'''. The positive voltage will repel the holes, and the negative voltage will repel the electrons, pushing both towards the junction. This movement shrinks the depletion zone, and if our voltage is high enough, the depletion zone will become so thin that electrons will be able to tunnel through it. When this happens, current will be able to flow through the semi-conductors.


[[Image:p_n_forward_bias.jpg]]
[[Image:p_n_forward_bias.gif]]


On the other hand, if we connect the positive voltage to the n-type semiconductor and the negative voltage to the p-type semiconductor, we will create a '''reverse bias'''. The negative voltage will attract the holes, and the positive voltage will attract the electrons. This will pull both holes and electrons away from the junction and widen the depletion zone. Because of this, no current can flow through the semiconductors. (However, if the voltage is high enough, current can still force its way across.)
On the other hand, if we connect the positive voltage to the n-type semiconductor and the negative voltage to the p-type semiconductor, we will create a '''reverse bias'''. The negative voltage will attract the holes, and the positive voltage will attract the electrons. This will pull both holes and electrons away from the junction and widen the depletion zone. Because of this, no current can flow through the semiconductors. (However, if the voltage is high enough, current can still force its way across.)


[[Image:p_n_reverse_bias.jpg]]
[[Image:p_n_reverse_bias.gif]]

Latest revision as of 15:59, 5 July 2006

Conductors and Insulators

Conductors are able to accommodate an electron flow through them because the electrons in the atoms are not tightly bound to their atoms. When an electron leaves its atom, it leaves behind hole, which because of the absence of the electron, is positively charged since the atom started out neutral. This hole can be modeled as a positive charge. As electrons move towards one end of the conductor, they will leave holes at the opposite end, thus creating a "flow" of holes in the direction opposite the electron flow.

Conductor diagram.gif

The electrons in insulators are tightly bound to their atoms, so they cannot flow.

Insulator diagram.gif

Semiconductors

Semiconductors, such as silicon, are somewhere in between a conductor and an insulator. Some electrons in the semi-conductor are allowed to flow, especially when released by heat or light. Semiconductors allow us to build non-linear devices, such as computers.

We can increase the conductivity of semiconductors by doping, or interspersing atoms with more valence electrons into the lattice structure.

For example, we can dope silicon (which as four valence electrons) with arsenic (which has 5 valence electrons). The extra electron in the arsenic atom cannot form a covalent bond with the neighboring atoms, and thus is loosely bound and available as a charge carrier. This creates an n-type semiconductor, which has negative charge carriers.

We can also dope the silicon with boron or gallium, which have 3 valence electrons. The lack of an electron to complete all four covalent bonds in the lattice structure leaves a hole that can accept an electron. This creates a p-type semiconductor, which has positive charge carriers.

p-n junctions

When we sandwich a p-type semiconductor with an n-type semiconductor, the electrons at the interface will jump into the holes, creating a depletion zone—an insulating section of semiconductor devoid of either type of charge carrier.

The electrons will jump into the holes across the border:

P n junction.gif

and will form the depletion zone:

P n junction depletion zone.gif

If we put a voltage across the semiconductors with the positive voltage on the p-type semiconductor, we will create a forward bias. The positive voltage will repel the holes, and the negative voltage will repel the electrons, pushing both towards the junction. This movement shrinks the depletion zone, and if our voltage is high enough, the depletion zone will become so thin that electrons will be able to tunnel through it. When this happens, current will be able to flow through the semi-conductors.

P n forward bias.gif

On the other hand, if we connect the positive voltage to the n-type semiconductor and the negative voltage to the p-type semiconductor, we will create a reverse bias. The negative voltage will attract the holes, and the positive voltage will attract the electrons. This will pull both holes and electrons away from the junction and widen the depletion zone. Because of this, no current can flow through the semiconductors. (However, if the voltage is high enough, current can still force its way across.)

P n reverse bias.gif