Interfacial Behaviour of Polyelectrolyte-Nanoparticle Systems

Sennerfors, Therese

January 2002

No description available.

polyelectrolyte

nanoparticles

adsorption

multilayers

ellipsometry

AFM

MASIF

XPS and neutron reflectometry

Growth and Characterization of ZnO Nanocrystals

Ericsson, Leif KE

January 2013

The understanding of surfaces of materials is of crucial importance to all of us. Considering nanocrystals (NCs), that have a large surface to bulk ratio, the surfaces become even more important. Therefore, it is important to understand the fundamental surface properties in order to use NCs efficiently in applications. In the work reported in this thesis ZnO NCs were studied. At MAX-lab in Lund, synchrotron radiation based Spectroscopic Photoemission and Low Energy Electron Microscopy (SPELEEM) and X-ray Photoelectron Spectroscopy (XPS) were used. At Karlstad University characterization was done using Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM), Atomic Force Microscopy (AFM), Scanning Tunnelling Microscopy (STM), Auger Electron Spectroscopy (AES), and XPS. The fundamental properties of ZnO surfaces were studied using distributions of ZnO NCs on SiO2/Si surfaces. The conditions for distribution of ZnO NCs were determined to be beneficial when using ethanol as the solvent for ultrasonically treated dispersions. Annealing at 650 °C in UHV cleaned the surfaces of the ZnO NCs enough for sharp LEEM imaging and chemical characterization while no sign of de-composition was found. A flat energy band structure for the ZnO/SiO2/Si system was proposed after 650 °C. Increasing the annealing temperature to 700 °C causes a de-composition of the ZnO that induce a downward band bending on the surfaces of ZnO NCs. Flat ZnO NCs with predominantly polar surfaces were grown using a rapid microwave assisted process. Tuning the chemistry in the growth solution the growth was restricted to only plate-shaped crystals, i.e. a very uniform growth. The surfaces of the NCs were characterized using AFM, revealing a triangular reconstruction of the ZnO(0001) surface not seen without surface treatment at ambient conditions before. Following cycles of sputtering and annealing in UHV, we observe by STM a surface reconstruction interpreted as 2x2 with 1/4 missing Zn atoms. / Baksidestext The understanding of the surfaces of materials is of crucial importance to all of us. Considering nanocrystals (NCs), that have a large surface to bulk ratio, the surfaces become even more important. In the work in this thesis ZnO NCs were studied. The fundamental properties of ZnO surfaces were studied using distributions of ZnO NCs on SiO2/Si surfaces. Annealing at 650 °C in UHV cleaned the surfaces of the ZnO NCs enough for sharp LEEM imaging and chemical characterization while no sign of de-composition was found. A flat energy band structure for the ZnO/SiO2/Si system was proposed after 650 °C. Increasing the annealing temperature to 700 °C causes a de-composition of the ZnO that induce a downward band bending on the surfaces of ZnO NCs. Flat ZnO NCs with predominantly polar surfaces were grown using a microwave assisted process. Tuning the chemistry in the growth solution the growth was restricted to only plate-shaped crystals, i.e. a very uniform growth. The surfaces of the NCs were characterized using AFM, revealing a triangular reconstruction of the ZnO(0001) surface not seen without surface treatment at ambient conditions before. Following cycles of sputtering and annealing in UHV, we observe by STM a surface reconstruction interpreted as 2x2 with 1/4 missing Zn atoms.

ZnO

Nanocrystals

Surface physics

XPS

SEM

AES

AFM

STM

Structure and Application of Photosensitive Self-assembled Pseudoisocyanine J-aggregates on Membrane Surfaces

Mo, Gary Chia Hao

31 August 2011

Understanding the assembly of monomeric components into specific molecular motifs is a central theme in materials and surface engineering. Motif designs, specifically using a controllable template, can yield materials with desired optical or electronic properties. The objective of this thesis is to understand the aggregate size, packing, and monomer orientation for the cationic dye, pseudoisocyanine. These organic molecules assemble into crystals in solution, on planar bilayer templates, and on the membranes of living cells. Pseudoisocyanine J-aggregates were found to form on top of the heterogeneous lipid domains in a phospholipid bilayer. This behaviour is limited to a few headgroup chemistries and lateral packing motifs, allowing one to control aggregation via a combination of these two factors. These aggregates are low-dimensional and display polymorphism. Using atomic force microscopy and visible-light spectroscopy, distinct optical characteristics can be correlated to different bilayer templated J-aggregate morphologies. The molecular packing of a similar J-aggregate crystal was resolved using both atomic force microscopy and selected area electron diffraction. The infrared absorption spectra of different polymorphs also displayed distinct differences. These separate examinations enabled a perspective that clarifies the geometry, packing, orientation, and size of templated J-aggregates. Insights into the templating of J-aggregates on the molecular scale reveals that they are sensitive reporters of membrane phase in adherent cells, and are compatible with established cell biology techniques. Lipid domains in live mammalian cells were visualized using fluorescent J-aggregates in combination with endogenous marker proteins of the endocytic process. Analysis of live cell images and additional biophysical work revealed that pseudoisocyanine J-aggregates formed on domains of the anionic lipid bis(monoacylglycerol)phosphate. Only by using J-aggregates can this lipid be shown to form well-ordered domains during endosomal maturation, leading to multivesicular body formation. These data demonstrate that a correlated optical and topographical approach is necessary to understand the structure of fluorescent molecular assemblies, and form the basis for utilizing such aggregates in a biological context.

Membrane bilayers

J-aggregates

Lipid rafts

AFM

0542

0494

Structure and Application of Photosensitive Self-assembled Pseudoisocyanine J-aggregates on Membrane Surfaces

Mo, Gary Chia Hao

31 August 2011

Understanding the assembly of monomeric components into specific molecular motifs is a central theme in materials and surface engineering. Motif designs, specifically using a controllable template, can yield materials with desired optical or electronic properties. The objective of this thesis is to understand the aggregate size, packing, and monomer orientation for the cationic dye, pseudoisocyanine. These organic molecules assemble into crystals in solution, on planar bilayer templates, and on the membranes of living cells. Pseudoisocyanine J-aggregates were found to form on top of the heterogeneous lipid domains in a phospholipid bilayer. This behaviour is limited to a few headgroup chemistries and lateral packing motifs, allowing one to control aggregation via a combination of these two factors. These aggregates are low-dimensional and display polymorphism. Using atomic force microscopy and visible-light spectroscopy, distinct optical characteristics can be correlated to different bilayer templated J-aggregate morphologies. The molecular packing of a similar J-aggregate crystal was resolved using both atomic force microscopy and selected area electron diffraction. The infrared absorption spectra of different polymorphs also displayed distinct differences. These separate examinations enabled a perspective that clarifies the geometry, packing, orientation, and size of templated J-aggregates. Insights into the templating of J-aggregates on the molecular scale reveals that they are sensitive reporters of membrane phase in adherent cells, and are compatible with established cell biology techniques. Lipid domains in live mammalian cells were visualized using fluorescent J-aggregates in combination with endogenous marker proteins of the endocytic process. Analysis of live cell images and additional biophysical work revealed that pseudoisocyanine J-aggregates formed on domains of the anionic lipid bis(monoacylglycerol)phosphate. Only by using J-aggregates can this lipid be shown to form well-ordered domains during endosomal maturation, leading to multivesicular body formation. These data demonstrate that a correlated optical and topographical approach is necessary to understand the structure of fluorescent molecular assemblies, and form the basis for utilizing such aggregates in a biological context.

Membrane bilayers

J-aggregates

Lipid rafts

AFM

0542

0494

Development of Self-Vibration and -Detection AFM Probe by using Quartz Tuning Fork

Hida, H., Shikida, M., Fukuzawa, K., Ono, A., Sato, K., Asaumi, K., Iriye, Y., Muramatsu, T., Horikawa, Y., Sato, K.

January 2007

No description available.

Atomic Force Microscopy (AFM)

Quartz tuning-fork

Piezoelectric

Electrical Characterization of Biological Elements by Atomic Force Microscopy

Casuso Páramo, Ignacio

11 March 2008

The assessment of the electrical properties of biomolecules at the nanoscale becomes necessary for gathering previous basic knowledge and for the control of the biosensor fabrication. I developed instrumentation, protocols, and theoretical frameworks for the nanoscale electrical characterization of biomolecules by AFM. Two novel types of AFM electrical characterizations were developed: electron transport through the biomolecules and dielectric polarization of the biomolecules (each one requires different instrumentation, protocols and theory). I succeeded in obtaining important electrical information on individual biomolecules with implications in electrical biosensor fabrication.KEY WORDS: AFM, Protein, Electrical, Biosensor

Biosensors

Proteïna

AFM

Electrònica

Ciències Experimentals i Matemàtiques

53

Low noise electrical measurement setup for graphene and molecules in a gas atmosphere

Ly, Jimmy

January 2011

No description available.

graphene

gas

afm

atomic force microscopy

raman

noise

characterization

Enhanced Dynamics at the Free Surface of a Molecular Glass Film

Daley, Chad

January 2010

In this thesis we describe two separate experiments involving the use of gold nanoparticles. The first experiment looks at the use of gold nanoparticles as a localized heat source and the potential application as a cancer treatment. The second experiment, which is the real focus of this thesis, applies gold nanoparticles in the study of the free surface dynamics of glassy thin films. Gold nanoparticles have the ability to strongly absorb the energy in an incident laser beam and convert that energy into heat. Photothermal therapy is a proposed cancer treatment which exploits this ability to irreparably damage cancerous tissues surrounding gold nanoparticles. In the first chapter of this thesis we explain an experiment designed to probe the local temperatures achieved in such a process. Gold nanoparticles are used to stabilize the boundary of an inverse micelle system which contains an aqueous fluorescent dye solution on it's interior. A temperature dependent fluorescence intensity allows us to probe the temperature changes induced by laser irradiation. In the remainder of this thesis we describe a separate experiment involving the use of gold nanoparticles to study the free surface dynamics of thin glassy films. There is a growing body of evidence in the literature that thin polymer films in the glassy state exhibit heterogeneous dynamics; specifically that the first few nanometers from an air-polymer interface exhibit enhanced mobility relative to the interior of the film. The underlying mechanism responsible for this enhanced mobility remains elusive, however some believe it to be a direct consequence of the polymeric nature of these films. We describe in detail an experiment aimed at addressing this concern. We deposit gold nanoparticles onto the surface of a molecular (non-polymeric) glassy film and monitor their behaviour upon heating using atomic force microscopy. Our results clearly show the existence of enhanced surface mobility in the system studied and provide strong evidence that enhanced surface mobility should be expected in all glass forming systems.

Glass Transition

AFM

Surface Dynamics

Molecular Glass

Nanoparticle

Physics

The Study and Fabrication of Optical Thin Film on Cr4+:YAG Double-clad Crystal Fiber Amplifier and Laser Based Devices

Wang, Ding-Jie

27 July 2010

Recently, with the escalating demands for optical communications, the need for bandwidth in optical communication network has increased. The technology breakthrough indry fiber fabrication opens the possibility for fiber bandwidth form 1.3 to 1.6 £gm. Cr4+:YAG double-clad crystal fiber (DCF) grown by the co-drawing laser-heated pedestal growth method has a strong spontaneous emission spectum form 1.3 to 1.6 £gm. Such fiber is therefore, eminently suitable for optical coherence tomography (OCT), broadband optical amplifier, amplifier spontaneous emission (ASE) light source, and tunable solid-state laser applications. In this thesis, multilayer dielectric thin films were directly deposited by E-gun coating onto the end faces of the Cr4+:YAG DCF. To improve the thin-film quality, to increase transmittance of laser output, and to design for the high power laser. For broadband optical amplifier in dual-pump and double-pass scheme, a 3.0-dB gross gain, a 3.0-dB insertion loss, and a 0-dB net gain at 1.4-£gm signal wavelength have been successfully developed with HR coating onto one of the Cr4+:YAG DCF end faces. In addition, we have successfully developed the Cr4+:YAG DCF laser by direct HR coatings onto fiber end faces and increase transmittance of laser output. A record-low threshold of 31.2 mW with a slope efficiency of 7.5% was achieved at room temperature.

laser-heated pedestal growth

tooling factor

AFM

optical coherence tomography

Characterization and growth of M-plane GaN on LiGaO2 substrate by Plasma-Assisted Molecular Beam Epitaxy

You, Shuo-ting

18 July 2012

¡@In this thesis, we have studied the growth of M-plane GaN thin film on LiGaO2 (100) substrate by Plasma-Assisted Molecular Beam Epitaxy. We found that the growth of GaN thin films on as-received LiGaO2 substrates is poly-crystalline by analysis of X-ray diffraction, and these of GaN thin films were peeled off after thin film process. Using atomic force microscopy (AFM) to scan the surface of as-received LiGaO2 substrate, we found that many particles which are Ga2O3 existed on the surface of as-received LiGaO2. The annealing ambient for LiGaO2 substrates in vacuum and air ambient has been studied in order to improve the surface of LiGaO2. The scanning results of AFM shows that the crystal quality and stress of M-plane GaN grown on LiGaO2 (100) substrate pre-annealed in air ambient is significantly improved. We conclude that the reason of GaN peeling off from LiGaO2 substrate is attributed to stress between GaN/ LiGaO2. The measurement of polarization-dependent PL shows that the luminescence intensity of growing sample increases and reaches a maximum at £p = 90¢X (E¡æc), which indicates the growing samples is M-plane GaN as well. The microstructure of growing samples was characterized by transmission electron microscopy. We found that the formation of stacking fault in GaN is attributed to the growth of GaN on cubic-Ga2O3 nano-particles. The formation of Ga2O3 nano-particles can be suppressed by pre-annealing LiGaO2 substrate in air. It revealed that the thermal annealing LiGaO2 substrate in air ambient can improve the surface of LiGaO2 substrate effectively, and then one can grow a high quality M-plane GaN thin film on the LiGaO2 substrate.

AFM

Ga2O3

Molecular beam epitaxy

LiGaO2

Non-polar GaN