Support

Support Options

Submit a Support Ticket

 

MOSFet Learning Materials

by Saumitra Raj Mehrotra, Dragica Vasileska, Gerhard Klimeck, Alejandra J. Magana

Version 8
by Saumitra Raj Mehrotra
Version 11
by Michael Anderson

Deletions or items before changed

Additions or items after changed

1 [[Image(mosfet.jpg, 500px)]]
2
3 -
By completing the MOSFET Lab in [[Resource(5065)]], you will be able to:
+
By completing the MOSFET Lab in [[Resource(5065)]], users will be able to understand a) the operation of MOSFET devices, b) the limitations of the gradual channel approximation, and c) the limitations of the drift-diffusion model.
4 -
+
5 -
a) understand the operation of MOSFET devices,
+
6 -
+
7 -
b) understand the limitations of the gradual channel approximation, and
+
8 -
+
9 -
c) understand the limitations of the drift-diffusion model.
+
10
11
12 The specific objectives of the MOSFET Lab are:
13
14 [[Image(mosfet_viewer.jpg, 400px)]]
15
16
17
18 == Recommended Reading ==
19
20 -
For better understanding of the operation and modeling of MOSFET devices, the following texts are highly recommended:
+
Users who are new to the operation and modeling of MOSFET devices should consult the following resources:
21
22 -
1. Michael Shur, Physics of Semiconductor Device (Prentice Hall).
+
1. Michael Shur. (1990). ''Physics of Semiconductor Devices''. Englewood Cliffs, NJ: Prentice Hall.
23
24 -
2. Simon M. Sze and Kwok K. Ng, Physics of Semiconductor Devices (Wiley, 2006).
+
2. Simon M. Sze and Kwok K. Ng. (2007). ''Physics of Semiconductor Devices''. 3rd ed. Hoboken, NJ: Wiley.
25
26 -
3. Dragica Vasileska, Stephen M. Goodnick and G. Klimeck, Computational Electronics: Semiclassical and Quantum Device Modeling and Simulation, Chapter 2 (CRC Press, 2010).
+
3. Dragica Vasileska, Stephen M. Goodnick and G. Klimeck. (2010). ''Computational Electronics: Semiclassical and Quantum Device Modeling and Simulation''. Boca Raton, LA: CRC Press.
27
28
29
30 == Demo ==
31
32 [[Resource(6900)]]
33
34 [[Resource(6830)]]
35
36
37
38
39 -
== Theoretical descriptions ==
+
== Theoretical Descriptions ==
40 +
41 +
* [[Resource(7224)]] (tutorial)
42
43 * [[Resource(5309)]]
44
45 * [[Resource(5310)]]
46
47 * [[Resource(5085)]]
48
49 * [[Resource(5306)]]
50
51
52
53 == Tool Verification ==
54
55 [[Resource(9841)]]
56
57
58 -
== Worked Examples ==
+
== Examples ==
59
60 [[Resource(10128)]]
61
62 == Exercises and Homework Assignments ==
63
64 1. [[Resource(5191)]]
65
66 2. [[Resource(4906)]]
67
68 3. [[Resource(7190)]]
69
70 4. [[Resource(7188)]]
71
72 5. [[Resource(3948)]]
73
74 6. [[Resource(9221)]]
75 -
76
77
78 == Solutions to Exercises ==
79
80 Work in progress!
81
82 +
== Evaluation ==
83
84 -
== Take a Test ==
+
This test will assess users' conceptual understanding of the physical, mathematical and computational knowledge related to operation of MOSFET devices.
85 -
+
86 -
This test will assess your conceptual understanding of the physical, mathematical and computational knowledge related to operation of MOSFET devices.
+
87
88 [[Resource(9882)]]
89
90 -
== Solve the Challenge ==
+
== Challenge ==
91
92 -
In this final challenge you will integrate all you have learned about operation of MOSFET devices.
+
In this final challenge users will integrate what they have learned about the operation of MOSFET devices.
93
94 [[Resource(10268)]]

nanoHUB.org, a resource for nanoscience and nanotechnology, is supported by the National Science Foundation and other funding agencies. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation.