ECE 802-604: Nanoelectronics - PowerPoint PPT Presentation

About This Presentation
Title:

ECE 802-604: Nanoelectronics

Description:

ECE 802-604: Nanoelectronics Prof. Virginia Ayres Electrical & Computer Engineering Michigan State University ayresv_at_msu.edu – PowerPoint PPT presentation

Number of Views:143
Avg rating:3.0/5.0
Slides: 35
Provided by: virgini219
Learn more at: https://www.egr.msu.edu
Category:

less

Transcript and Presenter's Notes

Title: ECE 802-604: Nanoelectronics


1
ECE 802-604Nanoelectronics
  • Prof. Virginia Ayres
  • Electrical Computer Engineering
  • Michigan State University
  • ayresv_at_msu.edu

2
Lecture 03, 05 Sep 13
In Chapter 01 in Datta Two dimensional electron
gas (2-DEG) DEG goes down, mobility goes
up Define mobility (and momentum
relaxation) One dimensional electron gas
(1-DEG) Special Schrödinger eqn (Con E) that
accommodates Electronic confinement band
bending due to space charge Useful external
B-field Experimental measure for mobility
3
n 0 for 1st m meff for conduction band e- in
GaAs. At 300K this is 0.067 m0 a ?
U(z) a z
z
Expected Units of a ?
4
n 0 for 1st m meff for conduction band e- in
GaAs. At 300K this is 0.067 m0 a ?
U(z) a z
z
Expected Units of a eV/m or eV/nm
5
Another way to ballpark an answer Equate the
first triangular well energy level to the first
energy level of a 10 nm GaAs infinite square well
(familiar problem) and then solve for asymmetry a
Set Triangular well Ec1 infinite square well
Ec1
6
(No Transcript)
7
(No Transcript)
8
Space Charge
HEMT
9
Space Charge
start
finish
ECE 875 Sze Classification of heterojunctions
into types I, II, and III. Look at the
opportunities for e- and o movement as EF is
established.
10
Refer everything to Evac. When separated
(starting condition) you have
Evac
Evac
Evac
Type-I Material 01 (identified by its smaller
energy bandgap) has lower EC1 and higher EV1
Type-II Material 01 has lower EC1 and lower EV1
Type-III Material 01 has EC1 that is close to
(overlaps) EV2
11
When Materials 01 and 02 come together what e-s
and os are most likely to do first
Evac
Evac
Evac
e-
e-
e-
o
o
Type-I e-s are collected at lower EC1 and os
are collected at higher EV1
Type-II e-s collected at lower EC1 and os
collected at higher EV2. Therefore e-s and os
are confined in different spaces
Type-III e-s can be collected at lower EC1but
can also recombine in the nearby overlapping
EV2 levels
12
Space Charge
Compare Datta and class examples were both Type
I
Evac
e-
o
Type-I e-s are collected at lower EC1 and os
are collected at higher EV1
13
Space Charge
Compare Datta and class examples were both Type
I
Evac
e-
e-s go into a triangular quantum well
region. In HEMT, os go into EV1 changed by
DEV but no quantum well
o
Type-I e-s are collected at lower EC1 and os
are collected at higher EV1
14
Space Charge
Contrast os for HEMT and for familiar infinite
potential well
Do also have quantized energy levels for os in
infinite square potential well. But not for HEMT
15
Expected transitions between EC and EV for, e.g.
light emission
J
DEC
DEV
16
Back to current, not light
J
DEC
DEV
Note e-s likely to be stuck in 1st energy level
because of the amount DE it takes to physically
move on to further location
17
Space Charge
J
DEC
ND
Lots of e-s come here and stay here. They came
from an n-type side. They left behind ND Space
charge region on both sides of junction
DEV
18
Space Charge
J
DEC
ND
DEV
Band bending ? due to space charge Have a local
E-field and potential U(z) here that are
different from periodic lattice potential of GaAs
and AlGaAs
19
Space Charge
J
DEC
ND
DEV
This is why we will use Eqn 1.2.1 where U(r ) is
the potential energy due to space charge not the
Bloch lattice potential.
20
How will you wire this up?
HEMT
21
How will you wire this up?
Wire it up to use the triangular quantum well
region in GaAs
22
Please! assign a consistent coordinate system
Wire it up to use the triangular quantum well
region in GaAs
-z
y
x
y
z
23
Please! assign a consistent coordinate system
Wire it up to use the triangular quantum well
region in GaAs
-z
y
n-
E y
x
(-e )(-E y)
y
z
Seems correct for e-s with Drain Note
current I is IDS
24
Why do this increase in Mobility
931C 3D Scattering
Sweet spot at 300K
mobility
T hot Phonon lattice scattering
T cold Impurity ND, NA- scattering
25
Why do this increase in Mobility
Compare 3-DEG (dotted lines) and 2-DEG (shaded
area). 2-DEG is better especially at low T.
26
Datta explanation
When tm is long, m is high
27
Streetman explanation brings out scattering and
group aspects better
Drain
Source
28
Streetman explanation
29
Streetman explanation
30
Streetman explanation
31
Streetman explanation
32
Streetman explanation
1) Direction of electron drift velocity is
opposite to direction of E-field. 2) Could stop
here with ltvxgt vd m E. Mind the
vectors/directions. 3) Next slide relates
mobility to current, which can be measured not
ltvxgt which cant.
33
Streetman explanation
34
Streetman explanation
Key
1) When number of es that have not scattered
N(t) goes up gt t must go up 2) Then m goes up 3)
Scattering involves energy and momentum
conserving interactions. Putting quantum
restrictions on these interactions means that
fewer can occur.
Write a Comment
User Comments (0)
About PowerShow.com