Post on 29-Dec-2015
PC4259 Chapter 5
Surface Processes in Materials Growth & Processing
Homogeneous nucleation: solid (or liquid) clusters
nucleated in a supersaturated vapor of pressure P0
Thermodynamic driving force --- free energy change per
unit volume of condensed phase:
ΔGv = -nkT ln (P0/ P∞)
(P∞: equilibrium vapor pressure over solid, n: solid atomic density)
When a growing sample is nearly in equilibrium with vapor, nucleation and growth is mainly governed by
thermodynamics
Formation of spherical cluster of radius r: energy increase
due to surface energy 4πr2γ , so total energy change:
G
r rcrit
Critical cluster radius: 2
critv
rG
Energy barrier:
3
2163crit
v
GG
ΔGhomo(r) = (4πr3/3)ΔGv + (4πr2)γ
When r > rcrit, the cluster becomes thermodynamically stable
Heterogeneous nucleation: clusters are formed on a
substrate (Cluster/substrate interface energy int, substrate surface
energy s) Truncated sphere of contact angle:
When s int + , = 0, complete wetting
When int s + , = 180˚, spherical ball without any wetting
Free energy barrier for stable nucleation:
Ghet = Ghomo(2 + cos)(1 - cos)2/4
Hetero-nucleation barrier is significantly lower than that of homo-nucleation in general!
θ = cos-1[(γs - γint)/γ]
Epitaxy: Crystalline film growth on a crystalline
substrate in a unique lattice orientation relationship
Growth proceeds as atomic layers stacking up sequentially
Three growth modes
γint ≤ γs – γf γint ≤ γs – γf with misfit γint ≥ γs – γf
Stranski-Krastanov growth of Ge on Si(001)
3D islands formation~ 3.5 ML Ge, 475°C, (110nm)2
huts
pyramids
Wetting layer~ 2.5 ML Ge, 475 °C, (44nm)2
4% lattice mismatch between Ge & Si
Atomic Processes in Nucleation & Growth
Adsorption, diffusion, incorporation, nucleation, desorption, coarsening
Si islands on Si(001)
Thermal activated process,
hopping frequency:
Atomic Diffusion on Terrace
)/exp(0 kTEdiff
Diffusivity: )/exp(4
20 kTEa
D diff
Diffusion barriers of
Rh on Rh surfaces
Anisotropic diffusion
Migration of cluster on surface
Fractal islands obtained in hit-and-stick or diffusion-
limited-aggregation (DLA) growth
Equilibrium island shape determined by step free
energy anisotropy
Islands grow in relatively compact shape at a raised T
Atom detachment makes small islands unstable. At given T & F, there is a critical island size i to which addition of just 1 atom makes it stable
Fe on Fe(100) growth at F = 0.016 ML/s, = 0.07 ML
but different T. Ediff = 0.45 eV & i = 1 from lnN vs 1/T
Island density N & deposition amount are related as:
2~ ii
FN
where:
kT
Ediffexp0
Island size distributions:
Ns density of islands of size s, so:
is
sNN
1s
ssN
Average island size:
)/(2
ssfsN is
NsNsis
s /
Scaling function: )/( ssf i
Coarsening of islands
Island coalescence: merging of islands in contact
Ostwald ripening: vapor of smaller islands absorbed by larger ones
Gradient of vapor pressure generates atomic flux towards larger island
rkT
mrprp
pvv
2exp)()(Kelvin effect:
4 stages in sub-ML nucleation & growth:
1. Low coverage (L), nucleation dominates
2. Intermediate coverage (I), island density approaches saturation
3. Aggregation (A), island density saturates
4. Coalescence (C), island density decreases
Variation of density of islands (nx) & adatoms (n1)
Inter-layer atomic transport in growth
Layer-by-layer growth requires
sufficient inter-layer atomic transport
Ehrlich-Schwoebel barrier EES: additional barrier for adatom
jumps down a step edge due to less neighbors than at a regular terrace site
Insufficient inter-layer transport leads to
multilayer growth & a rough surface
If inter-layer atomic motion is
completely forbidden, the coverage
of first layer 1 satisfies:
)1( 11
Fdt
d
Coverages of upper layers n, n = 2,
3…, can be found in similar way (see Homework 9.1)
Step-flow growth: atoms
quickly migrate to step edges instead
of island nucleation, film growth
proceeds as the advancement of
existing steps
Three kinetic growth modes: Phase diagram
Monitoring growth morphology
STM & AFM: high resolution for atomic details for both homo-
and hetero-epitaxy; but interrupt growth, time consuming and
limited sample size (~ 1 cm2)
AES: for heteroepitaxy, monitoring film & substrate peak
intensities. Different intensity variation characters in different growth modes
If layer-by-layer:
d
II SS exp0
dII FF exp1
If island growth, nearly linear variations
Reflection high-energy electron diffraction (RHEED)
For real-time surface monitoring in molecular beam epitaxy
1. Surface reconstruction
2. Period in layer-by-layer growth
3. 2D or 3D growth
RHEED Pattern
RHEED in MBE System
Surface reconstruction
Streaky diffraction pattern from a flat surface
Rough vs. Smooth Surface
Rough & 3D: Spotty pattern
Smooth & 2D Streaky pattern
RHEED Intensity Oscillation
When electron waves from neighboring atomic layers interfere destructively
1 oscillation cycle = 1 MLFor precise
growth rate &
film
thickness
control
Modification of Growth Morphology by Surfactant
General surfactant: adsorbed layer modifies surface thermodynamic properties, e.g. surface tension, friction coefficient, sticking power
Surfactant in film growth: adsorbed impurities which
facilitate, thermodynamically or kinetically, the growth proceed
in a desired mode, normally layer-by-layer
Surfactant should keep floating on surface so it is not consumed in growth, so surfactant should have a
low surface energy, e.g. Sb ( ~ 0.6 J/m2)
Surfactant based on thermodynamics
Film is covered with 1 ML of surfactant with a
lower
Deposited atoms exchange position with
surfactant atoms in order to reduce
Floating surfactant layer keeps film surface
smooth
Surfactant based on kinetics
Some surfactant atoms tend to decorate step edges; deposited
atoms can take the sites of surfactant atoms and push them
outward, an effectively lower EES
Some surfactant atoms act as nucleation centers to form a large density of islands with small size. Atoms deposited later easily attach to island edges instead of nucleation of upper-layer islands. Such film surface appears rough at small scale but smooth at large scale.
surfactant