Size dependency of the optical, thermal and vibrational properties of ZNO and BATIO3 at the nanoscale
With device miniaturization, the size effect on band gap, phonon vibration, thermal stability, ferroelectricity and wettability are attracting increasing interests with unfortunately unclear physical origins. It is the intent of this work to find the reasons for size-induced property...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2013
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| Online Access: | http://hdl.handle.net/10356/51235 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | With device miniaturization, the size effect on band gap, phonon vibration,
thermal stability, ferroelectricity and wettability are attracting increasing interests
with unfortunately unclear physical origins. It is the intent of this work to find the
reasons for size-induced property variation, and the quantitative correlations
between size and various properties. On the basis of bond order-length-strength
(BOLS) correlation and nonbonding electron polarization (NEP), detectable
quantities are functionally correlated to the order, nature, length, and energy of
the representative bond of the specimen. By understanding materials from the
perspective of bonding science, many physical properties can be interrelated, and
a general guideline can be formed to control crystal growth and performance.
A core-shell model has been developed to study the increase of the bond
energy and binding energy density, and the reduction of atomic cohesive energy,
due to nanostructures size and shape. The core retains its bulk nature, while the
shell behaves differently as a result of bond contraction due to surface atomic
deficiency. Consequently, there is a localized densification of charge, energy, and
mass. The shell atoms suffer from enhanced Hamiltonian and suppressed atomic
cohesive energy, which dominate properties such as band gap, phonon vibration,
thermal stability, and wettability.
In order to validate the proposed core-shell model, conductive zinc oxide
thin films with different grain sizes were prepared and investigated. Grazing
incident X-ray diffraction confirmed that there is spontaneous contraction of
bonds between undercoordinated atoms in the surface shell. Wettability IV
measurements suggested that the densely and tightly-trapped charges polarize
existing surface nonbonding electrons. The Coulomb repulsion between the
sample surface and the electric dipoles locked in the liquid skin is the reason for
hydrophobicity. Hall measurement supported that the localized polarization turns
the surface nonbonding electrons to be tightly-locked dipoles and less conductive.
Raman spectroscopy showed that size-induced softening of the A 1 (LO)
optical phonons arises from collective interatomic interaction while the stiffening
of E 2 (high) phonons from dimer interaction. Phonon vibrational frequency shift is
quantitatively correlated to the grain sizes. Post-annealing determines the critical
size by equating the thermal and the cohesive energy of the undercoordinated
atoms in the surface skin. The perturbed surface energy in turn induces local
strain and quantum entrapment, perturbing the Hamiltonian and hence the band
gap.
Besides properties that directly related to the near-surface binding energy
and cohesive energy, there are properties that come from both short-range and
long-range interactions, such as ferroelectricity. Therefore, a dual-shell model is
also established. One surface shell of three atomic layers represents the short-
range interaction due to the shorter and stronger bonds between the under-
coordinated atoms. The other shell of K c surface layers characterizes the long-
range dipole-dipole interaction, where K c is the critical number of atomic layers.
Barium titanate ferroelectrics with different sizes were prepared and demonstrated
good agreement with the proposed model. The modeling predictions have been verified by the presented
experimental observations and results documented by others. The formulation
provides a better understanding and guideline for crystal growth and performance,
and makes predictive design and fabrication of functional nanomaterials into
reality. |
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