Post on 07-Sep-2018
Graphene and Carbon Nanotubes
One atom thick layer of graphite = ‘graphene’
1 atom thick films of graphite – ‘atomic chicken wire’
Novoselov et al -Science 306, 666 (2004)
Geim’s group at Manchester
Novoselov et al - Nature 438, 197 (2005)
Kim-Stormer group at Columbia University
Zhang et al - PRL 94, 176803 (2005)
Zhang et al - Nature 438, 201 (2005)
100μm
Scanning Transmission Electron micrograph of GRAPHENET
hank
s to
Dr
Nic
olos
i (O
xfor
d M
ater
ials
)
Tight binding Calculation: Graphene
antibonding
antibonding
Tight binding Calculation: Graphene
NB, Two C atoms per unit cell (ie 12 electrons, 8 of which are valence)Non-hybridized (pi) electrons play key role in graphene conductivity
Graphene bandstructure
2N
2N
2N
2N
Tight Binding Theory
* 0 032K
ac
0
* * 1
1K E
c c
cK* = 1 x 106 ms-1
Typical values of are in the region of 3 eV, β = ~0.1, giving:
/ 1.005c c 3 million k.p.h.
Minimum conductance at K
(Dirac)-point
• Conductance minimum as
Fermi energy passes through
zero density of states
• Manchester and Columbia
groups
h
e
lkh
e
mv
lnene F
F
2
22
Mott criterion: kFl ≈ 1
X 4
A graphene based future
Graphene predicted to lead to lots of new physics +New fast transistors, super strength materials, transparent electrodes, chemical sensors.....
Single walled Carbon nanotubes:Discovered in 1993!
(10,10) Armchair Carbon Nanotubes
Carbon nanotubes:rolled up graphene!
http://www.photon.t.u-tokyo.ac.jp/~maruyama/agallery/agallery.html
(0,0)
Ch = (10,5)
Wrapping (10,5) SWNT
a1a2
x
y
Carbon Nanotubes (CNTs)Chiral vector for
Tube diameter
Chiral angle (definition)
Number of hexagons in nanotube unit cell:
Greatest common devisor of
CNT “translation” vector
CNT
1st lattice point reached!
(5,2)
(n,0) are called “zigzag” nanotubes(n,n) are called “armchair” nanotubes
Chiral vectors are used to label CNTs:
Carbon Nanotubes
Cyclic boundary conditions give allowed k-states for CNT:
Where reciprocal lattice vectors for CNT unit cell:
(circumference recip. lattice vector)
(CNT axis recip. lattice vector)
If allowed k-state coincides with graphene 1st BZ K point = metallic!
Number of CNT translationvectors along full length of tube
Allowed k-states for a (3,1) CNT
Extended Brillouin Zone Scheme Zone Folded Scheme
Tight binding Calculation: Graphene
antibonding
Tight binding Calculation: Graphene
antibonding
(7,4) (7,6)
metallic semiconducting
Carbon Nanotubes (examples)
Carbon Nanotube Bandgaps
Armchair CNT Zigzag CNT
SEMICONDUCTOR
Carbon Nanotubes (examples)
Zigzag CNT
METALMETAL
1,0
2,1
3,2
4,3
5,4
6,5
7,6
zigzag
armchair
2,0
3,1
4,2
5,3
6,4
7,5
8,6
8,7
4,0
5,1
6,2
7,3
8,4
9,5
5,0
6,1
7,2
8,3
9,4
7,0
8,1
9,2
10,3
8,0
9,1
10,2
10,0
11,1
11,0
Metallic
Semiconducting
Carbon nanotubes: metallic if n1 –n2 is a multiple of 3
NB 1-D CNT Brillouin Zone
CNT (1-D) Bandstructure
(8,8) metallic (8,0) semiconductingCNT (1-D) Density of States
Photo-Luminescence Excitation Mapping
Scan E22 excitation energy and measure emission from E11. Luminescence (fluorescence)
Low Dimensional Structures and Materials
• Artificial layered structures -
Quantum Wells and
Superlattices
• Electric or Magnetic Fieldsapplied in one direction.
Layers may be only a few atoms thick
HeterojunctionsEnergy levels for 2 different
semiconductorsEnergy line up at junction of
two (undoped) materials
Reduced Dimensionality
Quantum Well removes 1 Dimension by quantization
Electron is bound in well and can only move in plane
2-D system - motion in x, y plane
Quantum Mechanical Engineering
2 quantum wells give 2 levels (symmetric and antisymmetric combinations)
Superlattice generates a (mini)band
E
k/L0
Quantum Well - Type I
Typical Materials: 1: GaAs
(Eg = 1.5 eV)
2: (Al0.35Ga0.65)As
(Eg = 2.0 eV)
Energy levels are quantized in
z-direction with values En for
both electrons and holes
E = En + 2k2/2m*
1-D 2-D
Infinite well - Particle in a box
• 1-D Motion in z-direction
n = 1
n = 2
n = 3
L
E
dz
d
m
2
22
*2
System is Two-Dimensional when:
E2 - E1 > kT
162 meV 25 meV at 300 K
L
znAn
sin
*2*2
2222
m
k
L
n
mEn
Typical values L = 10 nm, me* = 0.07 me En = 54 n2 meV
Finite Well
even parity odd parity
n(z) Acos kz Asin kz |z| < L/2
Bexp[-(z - L/2)] Bexp[-(z - L/2 z > L/2
Bexp[+(z + L/2)] -Bexp[+(z + L/2)] z < L/2
• where:
• assume m1 = m2 k2 + 2 = k02 = 2m*V0/2
n
k
mV
m
2 2
10
2 2
22 2* *
boundary conditions:
wavefunction 1 = 2
probability current
A cos (kL/2) = B A sin (kL/2) = B
kA sin (kL/2) = B kA cos (kL/2) = -B
k2 tan2 (kL/2) = 2 k2 cot2 (kL/2) = 2
k2 sec2 (kL/2) = k02 k2 cosec2 (kL/2) = k0
2
cos (kL/2) = k/k0 sin (kL/2) = k/k0
zmzm
2
2
1
1
11
Graphical solution of finite Quantum Well
Well depth determines value of slope k0-1
Optical Properties
Absorption coefficient is proportional to the density of states:
~ 1/2
Modified close to the band gap due to ‘excitons’
3-D
2-D - Big Changes
Multiple Band gaps -Band gap shift -Sharper edge
For wide wells the sum of many 2-D absorptions becomes equivalent to the 3-D absorption shape (1/2)
Correspondence principle.
GaAs/Al0.35Ga0.65AsQuantum Well
absorption
• Sharp peaks due toexcitons
• peaks doubled due toheavy and light holes
Semiconductor lasers
Quantum Well laser
Fibre Optic Communications,
CD players, laser pointers
Forward biased p-n junction
Molecular Beam Epitaxy (MBE)
• Ultra High Vacuum evaporation of molecular species of elements (Molecular Beam)
• Epitaxy - maintaining crystal structure of the ‘substrate’ - which is a single crystal
Metal Organic Vapour Phase Epitaxy (MOVPE)
• Chemical reaction of elements bonded in volatile organic compounds
• e.g. (CH3)3Ga + AsH3
GaAs + 3CH4
• Reaction takes place on a heated substrate and growth is also ‘epitaxial’
Heterojunctions and Modulation Doping
New idea for superlattices and heterojunctions: Separate the dopant impurities from the electrons
Gated structures
• Place metallic electrode on
surface to apply variable
electric field
• gives a variable potential
and surface charge density
• Basis of MOS transistors as
well as controllable 2-D
systems.
Negative electrode potential repels electrons underneath leaving only a narrow 1-D channel of conducting electrons
Quantized Conductance in 1-D -the Quantum Point Contact
For a short 1-D structure there is no scattering - Ballistic transport
Calculate the current carried by the electrons by adding up the contributions from all carriers travelling in one direction.
For flow in one direction only (k > 0) the density of states is:
i.e. half the usual 1-D density of states, but with a factor 2 to account for spin degeneracy.
21
2 2
22
1 21 2
L m
d
* /
/
The electrons have velocity v = (2/m*)1/2. Therefore the current in the positive direction is:
Apply a voltage V along the 1-D channel to give a difference in chemical potential. This causes a net current to flow:
h
edgeJ
2)(v
0
• Therefore the conductance is:
• When there are p 1-D
subbands occupied (e.g. if the
1-D wire is wider) each
contributes one unit of
conductance
Vh
ed
h
ed
h
eJJJ
eV
Tot
2
00.
222
h
e
V
J Tot2
. 2
h
epTotal
2
2
B.J. van Wees et al,
Phys. Rev. Lett. 60, 848 (1988)