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Semiconductor Fundamentals. Objectives –After completing this unit, the student should be able to: Identify materials that act as semiconductors. Define.

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Presentation on theme: "Semiconductor Fundamentals. Objectives –After completing this unit, the student should be able to: Identify materials that act as semiconductors. Define."— Presentation transcript:

1 Semiconductor Fundamentals

2 Objectives –After completing this unit, the student should be able to: Identify materials that act as semiconductors. Define covalent bonding. Describe the doping process for creating N- and P-type semiconductor materials.

3 Objectives (Cont.) Explain how doping supports current flow in a semiconductor material. Identify the advantages of semiconductors. Identify the disadvantages of semiconductors.

4 Semiconductor materials –Characteristics fall between those of insulators and conductors. –There are three pure semiconductor elements: Carbon (C). Germanium (Ge). Silicon (Si).

5 Germanium –Brittle, grayish element. –Discovered in 1886. –Recovered from the ashes of certain types of coal. –Reduced to solid form—pure germanium.

6 Silicon –Discovered in 1823. –Found in the earth’s crust as silicon dioxide. –White or sometimes colorless. –Abundantly found in sand, quartz, agate, and flint. –Chemically reduced to pure silicon in solid form. –Most commonly used semiconductor material.

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8 Covalent bonding –The process of sharing valence electrons, resulting in the formation of crystals.

9 Negative temperature coefficient –As the temperature increases, its resistance decreases. For silicon, resistance is cut in half for every 6 degrees Celsius of rise in temperature. For germanium, resistance is cut in half for every 10 degrees Celsius of rise in temperature.

10 Silicon has 1000 times more resistance than germanium at room temperature, thus making it more stable. Germanium is used where heat-sensitive applications are necessary. Today, silicon is used for most solid-state applications.

11 Conduction in pure germanium and silicon –Electrical activity is highly dependent on temperature. –Germanium and silicon crystals function as insulators at low temperatures. –As the temperature rises, they begin to acquire the characteristics of a conductor.

12 Hole –The absence of an electron. –Represents the loss of a negative charge. –Therefore, it has the characteristic of a positively charged particle. –Each corresponding electron and hole are referred to as an electron-hole pair.

13 Holes constantly drift toward the negative terminal of the voltage source. Electrons flow toward the positive terminal. Current flow in a semiconductor consists of the movement of both electrons and holes.

14 The amount of current flow is determined by the number of electron-hole pairs. The ability to support current flow increases with the temperature of the material.

15 To increase conductivity of semiconductors, a process called doping is used. –Doping is the process of adding impurities to a semiconductor material. Pentavalent is made of atoms with five valence electrons. –Arsenic (As). –Antimony (Sb). Trivalent is made of atoms with three valence atoms. –Indium (In). –Gallium (Ga).

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17 N-type material –Has more electrons than holes. –Negative charge is the majority carrier. –Free electrons flow toward the positive terminal.

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19 P-type material –Has more holes than electrons. –Positive charge is the majority carrier. –The holes move toward the negative terminal.

20 In Summary –Semiconductor materials Materials with characteristics that fall between those of insulators and conductors. –Pure semiconductor materials Germanium (Ge). Silicon (Si). Carbon (C).

21 Silicon is used for most semiconductor devices. Valence indicates an atom’s ability to gain or lose electrons. Semiconductor materials have valence shells that are half full. Covalent bonding occurs when atoms share their valence electrons.

22 Heat creates problems by allowing electrons to break their covalent bonds. A hole is the absence of an electron in the valence shell. Current flow consists of both electron flow and hole movement. Doping adds impurities to a semiconductor material.

23 Trivalent materials –Have atoms with three valence electrons. –Are used to make P-type material. –Holes are the majority carrier. –Electrons are the minority carrier.

24 Pentavalent materials –Have atoms with five valence electrons. –Are used to make N-type material. –Electrons are the majority carrier. –Holes are the minority carrier. N-and P-type semiconductor materials have a higher conductivity than pure semiconductor material.


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