David J.
Neivandt
Associate Professor
Director of Product Development,
Pulp and Paper Process
Development Center
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B.S. (Hons.) Chemistry, The
University of Melbourne, 1994 |
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Ph.D. Chemistry, The University
of Melbourne, 1999 |
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Research Interests
Determination of
the orientation and conformation of interfacial species •
surface spectroscopies/microscopies
- Determination of the Orientation and Conformation of Interfacial
Species
- Characterization of adsorption from singular and binary
polymer/surfactant solutions on industrially significant surfaces
- Development of model lipid membrane structures and investigation
of deformations induced by adsorption/transport processes
- Investigation of potential sensing methodologies based on surface
enhanced spectroscopies and molecular patterning
- Surface Spectroscopies/Microscopies
- Application of the second order non-linear optical laser technique
of Sum Frequency vibrational Spectroscopy (SFS) to provide
structural information of interfacial species
- Incorporation of other complementary techniques giving surface
excesses of adsorbed species and interfacial morphologies
Interfacial adsorption is of critical importance in many industrial and
biological processes, primarily due to the fact that system properties
such as flocculation, flotation and biological recognition may be modified
by interaction with an interface of miniscule amounts of surface-active
species such as polyelectrolytes (proteins) and surfactants (lipids).
Whilst the surface excess of the adsorbate is often of importance in
inducing behavioral change, structural properties such as the polar
orientation and degree of conformational order are also critical. A great
deal of research has been performed on quantifying the effect of variables
such as concentration of the surface-active species, electrolyte
concentration, pH and temperature on surface excess. Comparatively little
work however has focused on determining the effect of the same system
properties on the detailed structure of the adsorbed layer. The primary
reason for this paucity of data is the lack of techniques capable of
providing interface specific structural information.
The aim of our research is to determine detailed conformational
informational of interfacial species in industrially and biologically
relevant systems with the intention of gaining insight into how the
surface structure affects the properties of the system. The primary
technique employed is the surface specific second order non-linear optical
technique of Sum Frequency vibrational Spectroscopy (SFS). This high
energy laser technique involves overlapping, both spatially and
temporally, a visible beam of fixed frequency and an infrared beam of
tunable frequency on an interface. A third beam is emitted from the
interface, the frequency of which is the sum of the two incident
frequencies. Detecting this emitted light as function of the infrared
wavelength produces a vibrational spectrum that is upshifted into the
visible. The polar orientation of species resident at the interface is
determined from the relative phase of the resonance signal, that is,
whether 'peaks' or 'dips' are observed in the spectrum. Conformational
information of the species is reflected by the relative strength of the
resonance signals. A broadband femtosecond SF spectrometer is near
completion in the group’s laser laboratory.
The detailed structural information of interfacial species obtained by
SFS is complemented by information obtained by a range of other surface
techniques in order to provide a more complete picture of the interface.
Specifically, the surface excess of the adsorbate is determined by
appropriate linear transmission or reflection spectroscopies, for example
UV-visible transmission and infrared attenuated total reflection. Further,
extensive use of Atomic Force Microscopy is made in order to associate the
surface excess and structural information with interfacial topography.
Current projects include: conformational studies of lipid molecules
comprising model membranes and polymer templating in surfactant
monolayers.
Conformational Studies of Lipid Molecules Comprising Model Membranes
Biological membranes consist of a bilayer of primarily lipid molecules
which contain a polar headgroup and two pendent hydrocarbon chains. The
conformational structure of the alkyl chains of the lipid is known to
influence membrane properties such as the rigidity, the degree of in-plane
fluidity and trans membrane transport phenomena. However, detailed studies
precisely characterising the structural effects of lipids on membrane
properties are complicated by the difficulty of deconvoluting the complex
native systems. Consequently there is a strong need for a model membrane
system that accurately reproduces the characteristics of a native membrane
and that may be studied by techniques that yield conformational
information. This project aims to construct asymmetric membranes
consisting of two different lipid molecules each in a separate layer of
the bilayer. The degree of conformational order of the alkyl chains of the
lipids will then be determined under a wide range of conditions by
application of Sum Frequency vibrational Spectroscopy (SFS). Aspects of
surface science, biological engineering, laser spectroscopy and equipment
construction and development are involved in this project.
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| A schematic representation of an asymmetric
biological membrane (left) composed of lipid molecules (right).
The conformational structure (the number of gauche versus trans
conformers) of the lipid alkyl chains affects the macroscopic
membrane properties. |
Polymer Templating in Surfactant Monolayers
This project aims to develop an entirely new means of
providing specificity in surface functionality via polymer
templating in surfactant monolayers. Unlike the commonly used
antibody/antigen approach, this technique will be applicable to
a variety of charged polymers (biological or non) without the
need for a specific complementary species. Indeed in principle
even the detailed structural nature of the polymer itself need
not necessarily be known. Further, the technique will circumvent
the solvent and exposure of binding site issues of another
common templating technique, molecular imprinting. Our group has
previously demonstrated that electrostatically charged polymers
remove oppositely charged surfactant molecules from densely
packed surface bound surfactant monolayers. The result of this
polymer/surfactant interaction is the formation of holes in the
surfactant monolayer which, due to the stoichiometric nature of
the polymer/surfactant interaction, replicate the shape and
charge distribution of the polymer. This process is represented
schematically below. Importantly we have recently shown that
these holes are stable for time periods of the order of hours
and that they may be stabilized indefinitely through covalent
modification. Further, we have successfully functionalized the
exposed substrate within the holes with charged sites which
compliment those of the polymer. Current work is aimed at
determining the extent to which the templates or ‘negatives’ of
the polymer structure created display specificity for the
polymer.
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Representation of the formation of a polymer induced
hole in a surfactant monolayer. |
Gramlich, W. M. ; Gardner, D. J. ; Neivandt, D. J. “Surface Treatments
of Wood Plastic Composites (WPC) to Improve Adhesion”, Journal of
Adhesion Science and Technology 20, 1873 (2006).
Graziani, I. ; Bagala, C. ; Duarte, M. ; Soldi, R. ; Kolev,
V. ; Tarantini, F. ; Kumar, S. ; Doyle, A. ; Neivandt, D. ; Yu,
C. Maciag, T. ; Prudovsky, I. “Release of FGF1 and p40
Synaptotagmin 1 Correlates with their Membrane Destabilizing
Ability”, Biochemical and Biophysical Research Communications
349, 192 (2006).
Casford, M.T.L. ; Davies, P.B. ; Neivandt, D.J. “Adsorption
of Sodium Dodecyl Sulfate at the Hydrophobic Solid/Aqueous
Solution Interface in the Presence of Poly(ethyleneglycol):
Dependence upon Polymer Molecular Weight”, Langmuir 22,
3005 (2006).
McGall, S.J. ; Davies, P.B. ; Neivandt, D.J. “Development of a
Biologically Relevant Calcium Phosphate Substrate for Sum Frequency
Generation (SFG) Vibrational Spectroscopy”, J. Phys. Chem. A
109, 8745 (2005).
Holman, J. ; Davies, P. B. ; Nishida, T. ; Ye, S. ; Neivandt,
D. J. “Sum Frequency Generation from Langmuir Blodgett
Multilayer Films on Metal and Dielectric Substrates” J. Phys.
Chem. B 109, 18723 (2005). Feature and Cover Article.
Lambert, A.G.; Davies, P.B.; Neivandt, D.J. “Implementing the Theory of
Sum Frequency Generation Vibrational Spectroscopy: A Tutorial Review”
Appl. Spect. Reviews 40, 103 (2005).
Poirier, J. S. ; Tripp, C. P. ; Neivandt, D.J. “Templated
Surfactant Re-Adsorption on Polyelectrolyte Induced Depleted
Surfactant Surfaces” Langmuir 21, 2876 (2005).
Doyle, A. W.; Fick, J.; Himmelhaus, M.; Eck, W.; Graziani,
I.; Prudovsky, I.; Grunze, M.; Maciag, T.; Neivandt, D.J.
“Protein Deformation of Lipid Hybrid Bilayer Membranes studied
by Sum Frequency Generation Vibrational Spectroscopy (SFS)”
Langmuir 20, 8961 (2004).
Holman, J.; Ye, S.; Neivandt, D.J.; Davies, P.B “Studying
Nanoparticle-Induced Structural Changes Within Fatty Acid
Multilayer Films Using Sum Frequency Generation Vibrational
Spectroscopy” J.A.C.S. 126, 14322 (2004).
McGall, S.J. ; Davies, P.B. ; Neivandt, D.J. “Interference
Effects in Sum Frequency Generation Vibrational Spectra of Thin
Polymer Films: an Experimental and Theoretical Investigation ”,
J. Phys. Chem. B. 108, 16030 (2004).
Holman, J.; Neivandt, D. J. ; Davies, P. B. “Nanoscale Interference
Effect in Sum Frequency Generation from Langmuir-Blodgett Fatty Acid
Films on Hydrophobic Gold”, Chem. Phys. Letts. 386, 60
(2004).
Holman, J.; Davies, P. B.; Neivandt, D. J. “Sum Frequency Spectroscopy
of Langmuir-Blodgett Fatty Acid Films on Hydrophobic Gold”, J. Phys.
Chem. B. 108, 1396 (2004).
Casford, M. T. L.; Davies, P. B.; Neivandt, D. J. “A Study of the
Co-Adsorption of an Anionic Surfactant and an Uncharged Polymer at the
Aqueous Solution/Hydrophobic Interface by Sum Frequency Spectroscopy”,
Langmuir 19, 7396 (2003).
McGall, S.J. ; Davies, P.B. ; Neivandt, D.J. “Sum Frequency Vibrational
Spectroscopy of the Comb Copolymer Cetyl Dimethicone Copolyol”, J.
Phys. Chem. B., 107, 4718 (2003).
Lambert, A.G. ; Neivandt, D.J. ; Briggs, A.M. ; Usadi, E.W. ; Davies,
P.B. “Enhanced Sum Frequency Generation from a Monolayer Adsorbed on a
Composite Dielectric/Metal Substrate”, J. Phys. Chem. B., 106,
10693 (2002).
Lambert, A.G. ; Neivandt, D.J. ; Briggs, A.M. ; Usadi, E.W. ; Davies,
P.B. ‘Interference Effects in Sum Frequency Spectra from Monolayers on
Composite Dielectric/Metal Substrates’, J. Phys. Chem. B., 106,
5461 (2002). Cover Article.
Windsor, R. ; Neivandt, D.J. ; Davies, P.B. “Temperature and pH effects
on the Co-Adsorption of Sodium Dodecyl Sulfate and Poly(ethylenimine)”,
Langmuir, 18, 2199 (2002).
Windsor, R. ; Neivandt, D.J. ; Davies, P.B. "Adsorption of Sodium
Dodecyl Sulfate in the presence of Poly(ethylenimine) and Sodium Chloride
studied using Sum Frequency Vibrational Spectroscopy", Langmuir,
17, 7306 (2001).
Kawai, T. ; Neivandt, D.J. ; Davies, P.B. "Sum Frequency
Generation on Surfactant-Coated Gold Nanoparticles", J.A.C.S.,
122, 12031 (2000).
Lambert, A.G. ; Neivandt, D.J. ; McAloney, R.A. ; Davies, P.B. "A
Protocol for the Reproducible Silanisation of Mica Validated by Sum
Frequency Spectroscopy and Atomic Force Microscopy", Langmuir,
16, 8377 (2000).
Neivandt, D.J. ; Gee, M.L. ; Hair, M.L. ; Tripp, C.P. "Polarised
Infrared Attenuated Total Reflection for the In Situ Determination of the
Orientation of Surfactant Adsorbed at the Solid/Solution Interface", J.
Phys. Chem. B, 102, 5107 (1998).
Neivandt, D.J. ; Gee, M.L. ; Hair, M.L. ; Tripp, C.P. "The
Co-Adsorption of Poly(styrenesulfonate) and Cetyltrimethylammonium Bromide
on Silica Investigated by Attenuated Total Reflection Techniques", Langmuir,
13, 2519 (1997).
Neivandt, D.J. ; Gee, M.L. "Variable Angle of Incidence Evanescent
Wave Spectroscopy of the Adsorption of Quaternarised Poly(vinylpyridine)
on Silica", Langmuir, 11, 1291 (1995).
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