Semiconductor Electronics

Higher education teachers: Smole Franc
Collaborators: Lipovšek Benjamin

Subject description

Prerequisits:

• enrolment in 2nd year of university studies
• conducted laboratory assignments present a condition for undertaking the final exam

Content (Syllabus outline):

Classifications of semiconductors. Carrier transport phenomena. Carrier generation and recombination. The pn junction diode: ideal and nonideal current-voltage relationship, small-signal model of the pn junction, junction breakdown, diode transients. Special diode types: the tunnel diode, the Schottky barrier diode, heterojunction diode. Diode circuits: rectifier, limiting and clamping circuits. The bipolar transistor: current-voltage relationship, the modes of operation, amplification with bipolar transistors, equivalent circuit models, frequency limitations, large-signal switching, basic single-stage amplifier configurations, basic logic inverter. The JFET and the MOSFET, current-voltage relationship, small-signal equivalent circuit, basic configurations of single-stage amplifiers, the CMOS digital logic inverter. Semiconductor power devices: pnpn diode, diac, thyristor, triac, insulated-gate bipolar transistor (IGBT). Optical devices: optical absorption, light emitting diodes, laser diodes, photodetectors: photoconductor, photodiode, pin photodiode, avalanche photodiode, phototransistor, solar cells. Nanoelectronics and nanotechnology: basic definitions, trends in the field of nanoelectronics, nanoconductors, transport properties of semiconductor nanostructures, nanodevices.

Objectives and competences:

• To comprehend structures, basic principles of operation and properties of semiconductor devices and present the main purposes of applications on examples of basic configurations.
• Knowledge of semiconductor devices is important for the understanding of the analog and digital electronics, power electronics, optoelectronics, photonics and emerging nanoelectronics.

Intended learning outcomes:

• Student will comprehend the structure and functioning of semiconductor devices, basic configurations of elements and fundamental purposes of application.

Learning and teaching methods:

• lectures, auditory practice, laboratory assignments

Study materials