![Page 1: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/1.jpg)
ECE-656: Fall 2011
Lecture 3: Density of States
Professor Mark Lundstrom Electrical and Computer Engineering
Purdue University, West Lafayette, IN USA
1 8/25/11
2
k-space vs. energy-space
N
3D(k) d
3k =
!
4" 3d
3k = D
3DE( )dE
N(k): independent of bandstructure
D(E): depends on E(k)
N(k) and D(E) are proportional to the volume, !, but it is common to
express D(E) per unit energy and per unit volume. We will use the
D3D(E) to mean the DOS per unit energy-volume.
Lundstrom ECE-656 F11
![Page 2: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/2.jpg)
3
about the limits of the integrals
Lundstrom ECE-656 F11
BW >> k
BT
E
F
f
0! 0
Lundstrom ECE-656 F11 4
outline
1) Density of states
2) Example: graphene
3) Discussion
4) Summary
This work is licensed under a Creative Commons Attribution-
NonCommercial-ShareAlike 3.0 United States License.
http://creativecommons.org/licenses/by-nc-sa/3.0/us/
![Page 3: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/3.jpg)
Lundstrom ECE-656 F11
5
example: 1D DOS
6
example: 1D DOS for parabolic bands
E = EC+!
2k
2
2m*
! =1
!
dE
dk=
2 E " EC
( )m
*
D1D
(E) =1
!!
2m*
E " EC
independent of E(k)
parabolic E(k)
Lundstrom ECE-656 F11
![Page 4: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/4.jpg)
Lundstrom ECE-656 F11
7
density of states in a nanowire
Lundstrom ECE-656 F11 8
2D density of states
![Page 5: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/5.jpg)
Lundstrom ECE-656 F11
9
density of states in a film
Lundstrom ECE-656 F11
10
effective mass vs. tight binding
sp3s*d5 tight binding calculation by
Yang Liu, Purdue University, 2007
TSi = 3 nm
![Page 6: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/6.jpg)
Lundstrom ECE-656 F11
11
effective mass vs. tight binding
sp3s*d5 tight binding calculation by Yang Liu, Purdue University, 2007
near subband edge well above subband edge
Lundstrom ECE-656 F11
12
exercise
![Page 7: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/7.jpg)
Lundstrom ECE-656 F11
13
how does non-parabolicity affect DOS(E)?
non-parabolicity increases DOS (E)
Lundstrom ECE-656 F11
14
alternative approach
![Page 8: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/8.jpg)
Lundstrom ECE-656 F11
15
proof
in k-space, we know:
nL=
1
L k
! f0
E( )" E # Ek( ) dE$
can also work in energy-space:
nL= f
0E( )
1
L! E " E
k( )k
# dE$
Lundstrom ECE-656 F11
16
interpretation
counts the states between E and E +dE
![Page 9: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/9.jpg)
Lundstrom ECE-656 F11 17
outline
1) Density of states
2) Example: graphene
3) Discussion
4) Summary
18
graphene
Lundstrom ECE-656 F11
Graphene is a one-atom-thick planar carbon sheet with a
honeycomb lattice.
Graphene has an unusual bandstructure that leads to
interesting effects and potentially to useful electronic devices.
source: CNTBands 2.0 on nanoHUB.org
![Page 10: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/10.jpg)
19
graphene
E(k) Brillouin zone
Datta: ECE 495N – fall 2008:
https://nanohub.org/resources/5710 (Lecture 21) https://nanohub.org/resources/5721 (Lecture 22)
20
simplified bandstructure near E = 0 We will use a very simple description of the graphene bandstructure,
which is a good approximation near the Fermi level.
We will refer to the EF > 0 case, as
“n-type graphene” and to the EF < 0
case as “p-type graphene.”
k
y
“neutral point” (“Dirac point”)
(valley degeneracy)
k
x
![Page 11: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/11.jpg)
21
DOS for graphene: method 2
D2 D
E( ) =1
A! E " E
k||
( )k
||
# =1
A
A
2$( )2% 2 ! (E " E
k||
)2$k||dk
||
0
&
'
D2 D
E( ) =g
V
!!2"F
2# (E $ E
k||
)Ek
||
dEk
||
0
%
&
D2 D
E( ) =2E
!!2"
F
2E > 0
Lundstrom ECE-656 F11
D2 D
E( ) =2 E
!!2"
F
2
22
DOS for graphene: method 1
Lundstrom ECE-656 F11
![Page 12: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/12.jpg)
23
DOS for graphene: method 1
Lundstrom ECE-656 F11
N (k) dk = AgV
kdk
!
= AgV
EdE
! !"F( )
2
= AD2 D
E( )dE
D2 D
E( ) =2 E
!!2"
F
2
Lundstrom ECE-656 F11 24
outline
1) Density of states
2) Example: graphene
3) Discussion
4) Summary
![Page 13: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/13.jpg)
25
density of states
D3D
E
D2D
E
D1D
E
Lundstrom ECE-656 F11
26
density of states for bulk silicon
Lundstrom ECE-656 F11
–5 –4 –3 –2 –1 0 1 2 3 4 5 60
2
4
6
ENERGY (eV)
DO
S (
1022
cm
–1 e
V–1
)
The DOS is calculated with nonlocal empirical pseudopotentials
including the spin-orbit interaction. (Courtesy Massimo Fischetti, August, 2011.)
![Page 14: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/14.jpg)
27
computing the density of states
Lundstrom ECE-656 F11
–5 –4 –3 –2 –1 0 1 2 3 4 5 60
2
4
6
ENERGY (eV)
DO
S (
1022
cm
–1 e
V–1
)
Courtesy Massimo Fischetti, August, 2011.
no. of states =!k( )
3
2" #( )$ 2
28
density of states for bulk silicon (near the band edge)
Lundstrom ECE-656 F11
(Courtesy Massimo Fischetti, August, 2011)
0.0 0.1 0.2 0.3 0.4 0.50
2
4
6
8
10
me,d1=0.3288 me (gc=6)!1=–1.0 eV–1
me,d2=0.2577 me (gc=6)!2= 0.0 eV–1
ELECTRON KINETIC ENERGY (eV)
DO
S (
1021
cm
–1 e
V–1
)
0.0 0.1 0.2 0.3 0.4 0.50
2
4
6
8
mh,d1=0.8076 me (gv=1)!1=–0.5 eV–1
mh,d2=0.7528 me (gv=1)!2=–0.25 eV–1
HOLE KINETIC ENERGY (eV)
DO
S (
1021
cm
–1 e
V–1
)
0.0 0.1 0.2 0.3 0.4 0.50
2
4
6
8
10
me,d1=0.3288 me (gc=6)!1=–1.0 eV–1
me,d2=0.2577 me (gc=6)!2= 0.0 eV–1
ELECTRON KINETIC ENERGY (eV)
DO
S (
1021
cm
–1 e
V–1
)
0.0 0.1 0.2 0.3 0.4 0.50
2
4
6
8
mh,d1=0.8076 me (gv=1)!1=–0.5 eV–1
mh,d2=0.7528 me (gv=1)!2=–0.25 eV–1
HOLE KINETIC ENERGY (eV)
DO
S (
1021
cm
–1 e
V–1
)
conduction band valence band
![Page 15: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/15.jpg)
Lundstrom ECE-656 F11 29
outline
1) Density of states
2) Example: graphene
3) Discussion
4) Summary
30
summary
1) When computing the carrier density, the important
quantity is the density of states, D(E).
Lundstrom ECE-656 F11
2) The DOS depends on dimension (1D, 2D, 3D) and
bandstructure.
3) If E(k) can be described analytically, then we can
obtain analytical expressions for DOS(E). If not, we
can compute it numerically.
![Page 16: L3 Density of States - nanoHUB.orgL3_Density_of_States.pdf · ECE-656: Fall 2011 Lecture 3: Density of States Professor Mark Lundstrom Electrical and Computer Engineering Purdue University,](https://reader034.vdocument.in/reader034/viewer/2022042413/5f2d24d379bda139a77ce50d/html5/thumbnails/16.jpg)
Lundstrom ECE-656 F11 31
questions
1) Density of states
2) Example: graphene
3) Discussion
4) Summary