This video is part of the course "ECE 606: Solid State Physics" taught by Gerhard Klimeck at Purdue University. The course can be found on nanoHUB.org at [ Ссылка ] or on edX at [ Ссылка ]
Table of Contents:
00:00 S16.6 SRH formula adapted to interface states
00:13 Section 16 Recombination & Generation
00:42 Surface Recombination Current
03:25 Case 1: Minority Carrier Recombination
06:39 Case 1: Minority Carrier Recombination
06:52 Case 1: Minority Carrier Recombination
09:31 Consider the Denominator … at Ei
11:19 Consider the Denominator … at EF
12:47 Consider the Denominator … in general
13:59 Consider the Denominator … close to EF
14:46 By Symmetry … below Ei
15:27 By Symmetry … below Ei
15:47 By Symmetry … below Ei
16:06 By Symmetry … below Ei
18:07 How Different is 𝐸 𝐹′ from 𝐸 𝐹 ′ ?
18:32 How Different is 𝐸 𝐹′ from 𝐸 𝐹 ′ ?
19:43 How Different is 𝐸 𝐹′ from 𝐸 𝐹 ′ ?
20:53 Approximate 𝑊
21:35 Approximate 𝑊
21:44 Case 1: Minority Carrier Recombination
22:27 Small Detour – A Very Critical Insight
23:20 Small Detour – A Very Critical Insight
26:13 Case 1: Minority Carrier Recombination
26:40 Surface Recombination Velocity
29:44 Surface Recombination Velocity
31:04 Section 16 Recombination & Generation
31:15 Section 16 Recombination & Generation
This course provides the graduate-level introduction to understand, analyze, characterize and design the operation of semiconductor devices such as transistors, diodes, solar cells, light-emitting devices, and more.
The material will primarily appeal to electrical engineering students whose interests are in applications of semiconductor devices in circuits and systems. The treatment is physics-based, provides derivations of the mathematical descriptions, and enables students to quantitatively analyze device internal processes, analyze device performance, and begin the design of devices given specific performance criteria.
Technology users will gain an understanding of the semiconductor physics that is the basis for devices. Semiconductor technology developers may find it a useful starting point for diving deeper into condensed matter physics, statistical mechanics, thermodynamics, and materials science. The course presents an electrical engineering perspective on semiconductors, but those in other fields may find it a useful introduction to the approach that has guided the development of semiconductor technology for the past 50+ years.
