This document discusses semiconductor materials used in electronics. It covers:
- Semiconductors like germanium, silicon, and gallium arsenide that are used to construct electronic devices.
- Covalent bonding in semiconductors and how it relates to intrinsic and extrinsic materials.
- Intrinsic materials have few impurities, while extrinsic materials like n-type and p-type are doped with impurities to add free electrons or holes.
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Electronics-1.pptx
1. Electronics-1
Semiconductor materials
Covalent bonding
Intrinsic and extrinsic materials
https://www.youtube.com/watch?v=5fueVTbRxd4
Disclaimer: All images and materials in this lecture are taken from the online instructor resources of the book:
Electronic Devices and Circuit Theory ,by Robert L. Boylestad and Louis Nashelsky, published by Pearson
Dr. Aamir Shahzad
2. Semiconductor Materials: Ge, Si and GaAs
• Electronic devices are constructed with semiconductor materials.
• Semiconductors are a special class of elements having a conductivity between that of a good
conductor and that of an insulator.
• Single crystal: germanium (Ge), silicon (Si)
• Compound: gallium arsenide (GaAs), cadmium sulfide (CdS), gallium nitride (GaN)
• Discovery of the diode in 1939 and the transistor in 1947
• germanium was used almost exclusively
• because it was relatively easy to find
• available in fairly large quantities
• relatively easy to refine
• but less stable due to temperature sensitivity
3. • Important Parameters of semiconductor
• Speed: depends on carrier mobility factor:
• GaAs transistors had speeds of operation up to five times that of Si.
• Availability: naturally available and how easily can be purified
• Ge is easily available and easily purified material. Si is abundant material.
• Stability: temperature dependency
• Ge is temperature sensitive and less stable.
5. The bonding of atoms, strengthened by the sharing of electrons, is called covalent bonding
6. Intrinsic Semiconductor Materials
• The term intrinsic is applied to any semiconductor material that has been carefully
refined to reduce the number of impurities to a very low level, essentially as pure
as can be made available through modern technology.
• The free electrons in a material due only to external causes are referred to as
intrinsic carriers.
• Semiconductor materials have a negative temperature coefficient.
7. Energy Levels
• Within the atomic structure of each and every isolated atom there are specific
energy levels associated with each shell and orbiting electron
• The farther an electron is from the nucleus, the higher is the energy state.
• Any electron that has left its parent atom has a higher energy state than any
electron in the atomic structure.
8. Energy levels: (a) discrete levels in isolated atomic structures; (b) conduction and valence
bands of an insulator, a semiconductor, and a conductor.
An electron in the valence band of silicon must absorb more energy than one in the valence band of
germanium to become a free carrier. Similarly, an electron in the valence band of gallium arsenide must
gain more energy than one in silicon or germanium to enter the conduction band.
9. Extrinsic semiconductor material
• A semiconductor material that has been subjected to the doping
process is called an extrinsic material.
• There are two extrinsic materials important for semiconductor device
fabrication: n -type and p -type materials.
• Both n -type and p -type materials are formed by adding a
predetermined number of impurity atoms to a silicon base.
10. n -Type Material
• An n -type material is created by introducing impurity elements
that have five valence electrons ( pentavalent ), such as antimony ,
arsenic , and phosphorus.
• Diffused impurities with five valence electrons
are called donor atoms
• Four covalent bonds are still present.
• The fifth electron due to the impurity atom,
which is unassociated with any particular
covalent bond becomes a free charge carrier.
11. p -Type Material
• The p -type material is formed by doping a
pure semiconductor materials ( germanium
or silicon ) with impurity atoms having
three valence electrons ( trivalent).
• The elements most frequently used for this
purpose are boron , gallium , and indium .
• The diffused impurities with three valence
electrons are called acceptor atoms.
• There is now an insufficient number of
electrons to complete the covalent bonds
• The resulting vacancy is called a hole and is
represented by a small circle or a plus sign,
indicating the absence of a negative charge
Boron impurity in p-type material.
12. Electron versus Hole Flow
• In an n-type material the electrons are called the majority carriers and the holes the
minority carriers.
• In a p-type material the hole is the majority carrier and the electron is the minority
carrier