Optical properties, electronic structure and London dispersion interactions for nanostructured interfacial and surficial films

ABSTRACTThe optical properties and electronic structure of AlPO4, SiO2, Type I collagen, and DNA were examined to gain insight into the van der Waals-London dispersion behavior of these materials. Interband optical properties of AlPO4 and SiO2 were derived from vacuum ultraviolet spectroscopy and spectroscopic ellipsometry, and showed a strong dependence on the crystals’ constituent tetrahedral units, with strong implications for the role of phosphate groups in biological materials. The UV-Vis decadic molar absorption of four DNA oligonucleotides was measured, and showed a strong dependence on composition and stacking sequence. A film of Type I collagen was studied using spectroscopic ellipsometry, and showed a characteristic shoulder in the fundamental absorption edge at 6.05 eV. Ab initio calculations based on density functional theory corroborated the experimental results and provided further insights into the electronic structures, interband transitions and vdW-Ld interaction potentials for these materials.

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Optical Properties and van der Waals - London Dispersion Interactions of Polystyrene Determined by Vacuum Ultraviolet Spectroscopy and Spectroscopic Ellipsometry

Australian Journal of Chemistry ◽

10.1071/ch06222 ◽

2007 ◽

Vol 60 (4) ◽

pp. 251 ◽

Cited By ~ 42

Author(s):

Roger H. French ◽

Karen I. Winey ◽

Min K. Yang ◽

Weiming Qiu

Keyword(s):

Free Energy ◽

Optical Properties ◽

Surface Free Energy ◽

Vacuum Ultraviolet ◽

Van Der Waals ◽

Interband Transitions ◽

Dispersion Interactions ◽

Dispersion Component ◽

London Dispersion ◽

Hamaker Constants

The interband optical properties of polystyrene in the vacuum ultraviolet (VUV) region have been investigated using combined spectroscopic ellipsometry and VUV spectroscopy. Over the range 1.5–32 eV, the optical properties exhibit electronic transitions we assign to three groupings, E1, E2, and E3, corresponding to a hierarchy of interband transitions of aromatic (π → π*), non-bonding (n → π*, n → σ*), and saturated (σ → σ*) orbitals. In polystyrene there are strong features in the interband transitions arising from the side-chain π bonding of the aromatic ring consisting of a shoulder at 5.8 eV (E1′) and a peak at 6.3 eV (E1), and from the σ bonding of the C–C backbone at 12 eV (E3′) and 17.1 eV (E3). These E3 transitions have characteristic critical point line shapes associated with one-dimensionally delocalized electron states in the polymer backbone. A small shoulder at 9.9 eV (E2) is associated with excitations possibly from residual monomer or impurities. Knowledge of the valence electronic excitations of a material provides the necessary optical properties to calculate the van der Waals–London dispersion interactions using Lifshitz quantum electrodynamics theory and full spectral optical properties. Hamaker constants and the van der Waals–London dispersion component of the surface free energy for polystyrene were determined. These Lifshitz results were compared to the total surface free energy of polystyrene, polarity, and dispersive component of the surface free energy as determined from contact angle measurements with two liquids, and with literature values. The Lifshitz approach, using full spectral Hamaker constants, is a more direct determination of the van der Waals–London dispersion component of the surface free energy of polystyrene than other methods.

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Optical Properties and van der Waals-London Dispersion Interactions in Berlinite Aluminum Phosphate from Vacuum Ultraviolet Spectroscopy

Journal of the American Ceramic Society ◽

10.1111/jace.12757 ◽

2013 ◽

Vol 97 (4) ◽

pp. 1143-1150 ◽

Cited By ~ 5

Author(s):

Daniel M. Dryden ◽

Guolong L. Tan ◽

Roger H. French

Keyword(s):

Optical Properties ◽

Vacuum Ultraviolet ◽

Van Der Waals ◽

Aluminum Phosphate ◽

Ultraviolet Spectroscopy ◽

Dispersion Interactions ◽

Vacuum Ultraviolet Spectroscopy ◽

London Dispersion

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Chirality-dependent properties of carbon nanotubes: electronic structure, optical dispersion properties, Hamaker coefficients and van der Waals–London dispersion interactions

RSC Advances ◽

10.1039/c2ra20083j ◽

2013 ◽

Vol 3 (3) ◽

pp. 823-842 ◽

Cited By ~ 23

Author(s):

Rick F. Rajter ◽

Roger H. French ◽

W.Y. Ching ◽

Rudolf Podgornik ◽

V. Adrian Parsegian

Keyword(s):

Carbon Nanotubes ◽

Electronic Structure ◽

Van Der Waals ◽

Dispersion Interactions ◽

Optical Dispersion ◽

Dispersion Properties ◽

London Dispersion

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Structural/Property Relationships for Optical Materials

MRS Proceedings ◽

10.1557/proc-329-215 ◽

1993 ◽

Vol 329 ◽

Author(s):

Vivien D.

Keyword(s):

Crystal Structure ◽

Optical Properties ◽

Electronic Structure ◽

Chemical Composition ◽

Field Strength ◽

Optical Materials ◽

Site Occupancy ◽

Laser Materials ◽

Crystal Field Strength ◽

The Matrix

AbstractIn this paper the relationships between the crystal structure, chemical composition and electronic structure of laser materials, and their optical properties are discussed. A brief description is given of the different laser activators and of the influence of the matrix on laser characteristics in terms of crystal field strength, symmetry, covalency and phonon frequencies. The last part of the paper lays emphasis on the means to optimize the matrix-activator properties such as control of the oxidation state and site occupancy of the activator and influence of its concentration.

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Controlling the non-linear optical properties of MgO by tailoring the electronic structure

Applied Physics B ◽

10.1007/s00340-020-7393-7 ◽

2020 ◽

Vol 126 (3) ◽

Author(s):

Mukhtar Hussain ◽

Hugo Pires ◽

Willem Boutu ◽

Dominik Franz ◽

Rana Nicolas ◽

...

Keyword(s):

Optical Properties ◽

Electronic Structure ◽

Non Linear ◽

Linear Optical Properties ◽

Linear Optical

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DFT Study of Electronic Structure and Optical Properties of Kaolinite, Muscovite, and Montmorillonite

Crystals ◽

10.3390/cryst11060618 ◽

2021 ◽

Vol 11 (6) ◽

pp. 618

Author(s):

Layla Shafei ◽

Puja Adhikari ◽

Wai-Yim Ching

Keyword(s):

Mechanical Properties ◽

Optical Properties ◽

Electronic Structure ◽

Hydrogen Bonds ◽

Clay Minerals ◽

Clay Mineral ◽

Bond Order ◽

Deep Understanding ◽

Pharmaceutical Applications ◽

Structure Properties

Clay mineral materials have attracted attention due to their many properties and applications. The applications of clay minerals are closely linked to their structure and composition. In this paper, we studied the electronic structure properties of kaolinite, muscovite, and montmorillonite crystals, which are classified as clay minerals, by using DFT-based ab initio packages VASP and the OLCAO. The aim of this work is to have a deep understanding of clay mineral materials, including electronic structure, bond strength, mechanical properties, and optical properties. It is worth mentioning that understanding these properties may help continually result in new and innovative clay products in several applications, such as in pharmaceutical applications using kaolinite for their potential in cancer treatment, muscovite used as insulators in electrical appliances, and engineering applications that use montmorillonite as a sealant. In addition, our results show that the role played by hydrogen bonds in O-H bonds has an impact on the hydration in these crystals. Based on calculated total bond order density, it is concluded that kaolinite is slightly more cohesive than montmorillonite, which is consistent with the calculated mechanical properties.

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