Fabrication and Properties of Polypyrrole Nanocylinders

Mativetsky, Jeffrey

08 1900

Polypyrrole nanocylinders were fabricated by chemically synthesizing polypyrrole within the pores of nanoporous polycarbonate particle track-etched membranes and alumina membranes. The morphology of the nanostructures was characterized by transmission electron microscopy and scanning electron microscopy. The polycarbonate membrane-templated nanocylinders were cigar-shaped, with the diameter at the center being up to 2.5 times the diameter at the ends. The nanostructures produced in alumina membranes were linear aggregates of blobs. The electrical conductivity of the nanocylinders was measured by leaving the nanocylinders embedded in the insulating template membrane and measuring the trans-membrane resistance. The smallest diameter polycarbonate membrane-templated nanocylinders exhibited a slightly lower conductivity relative to the larger diameter nanocylinders. The temperature dependence of the resistance with and without the application of a magnetic field was in accordance with Mott variable range hopping at temperatures above 5 ± 1 K and Efros-Shklovskii variable range hopping at temperatures below 5 ± 1 K. Based on the measurements in the Mott regime, the localization length, the density of states at the Fermi energy, and the temperature dependence of the average hopping distance were calculated. / Thesis / Master of Science (MS)

fabrication

properties

polypyrrole

nanocylinders

Propriétés optiques et thermoplasmoniques de réseaux de nanocylindres : applications à la détection de molécules et de micro-objets / Optical and thermoplasmonic properties of arrays of nanocylinders : Applications to the detection of molecules and micron-sized objects

Colas, Florent

03 July 2017

La spectroscopie Raman est une technique non-invasive, non-destructrice, permettant l’identificationdes molécules contenues dans un échantillon solide, liquide ou gazeux. Toutefois elle souffre d’un inconvénient majeur : une faible sensibilité. Cette limite est maintenant sur le point d’être repoussée grâce à l’essor du SERS (Surface Enhanced Raman Scattering, acronyme anglais de diffusion Raman exaltée de surface). Ce phénomène a été déjà mis en œuvre avec succès dans diverses applications : biomédicale, biologie, chimie analytique, science environnementale... Toutefois, malgré un nombre croissant de travaux scientifiques, certains aspects des capteurs SERS restent à étudier. Ce travail s’est focalisé sur l’étude des propriétés optiques en champs proche et lointain de réseaux de nanocylindres pour la détection de composés organiques. Les paramètres étudiés sont la période du réseau, le diamètre des cylindres, mais également le matériau constituant la nanoparticule tout comme la couche d’accroche. L’´étude des propriétés optiques nous a naturellement amené à investiguer le phénomène d’absorption. L’´énergie lumineuse incidente est convertie en chaleur. Les nanocylindres se comportent alors comme des nanosources de chaleur. Ainsi, une partie de ce travail a porté sur les effets dits de thermoplasmoniques. Une des applications que nous avons démontrée est la capacité à manipuler des micro-objets, grâce au contrôle des phénomènes d’advections. / Raman spectroscopy is a technique that is non-invasive, non-destructive, allowing the identification of the molecules contained in a solid, liquid or gaseous sample. However it suffers from one major drawback : low sensitivity. This limit is now about to be pushed through the fast growth of SERS (Surface Enhanced Raman Scattering). This phenomenon has been already implemented successfully in various applications : biomedical, biology, analytical chemistry,environmental science... However, despite a growing number of scientific works, some aspects of the SERS sensors still need to be studied. This work focused on the study of the near-field and the far-field properties of arrays of nanocylinders for the detection of organic compounds. The studied parameters are the period of the array, the diameter of the cylinders, but also the material constituting the nanoparticle as the adhesion layer. The study of optical properties naturally led us to investigate the phenomenon of absorption. The incident light energy is converted into heat. The nanocylindres then behave like nanosources of heat. Thus, part of this work focused on the effects of thermoplasmonics. One of the applications that we demonstrated is the ability to manipulate the micro-objets, thanks to the control of the phenomena of advections.

Champ lointain

Nanocylindres

Thermoplasmonique

Far-field

Nanocylinders

Thermoplasmonic

Probing Magnetic And Structural Properties Of Metallic Nanowires Using Resistivity Noise

Singh, Amrita

09 1900

The main focus of this thesis work has been the study of domain wall (DW) dynamics in disordered cylindrical nanomagnets. The study attempts to accurately quantify the stochasticity associated with driven (temperature/magnetic field/spin-torque) DW kinetics. Our results as summarized below, are particularly relevant with regard to the technological advancement of DW based magnetoelectronic devices. 1. Temperature dependent noise measurements showed an exponential increase in noise mag-nitude, which was explained in terms of thermally activated DW depinning within the Neel-Brown framework. The frequency-dependence of noise also indicated a crossover from nondiffusive kinetics to long-range diffusion of DWs at higher temperatures. We also observed strong collective depinning, which must be considered when implementing these nanowires in magnetoelectronic devices. 2. Our noise measurements were sensitive enough to detect not only the stochasticity in DW propagation (diffusive random walk) but also their nucleation in the presence of magnetic field down to a single DW unit inside an isolated single Ni nanowire. Controlled injection and detection of individual DWs is critical in designing DW based memory devices. 3. The spectral slope of noise was observed to be sensitive to DWkinetics that reveals a creep-like behavior of the DWs at the depinning threshold, and diffusive DW motion at higher spin torque drive. Different regimes of DW kinetics were characterized by universal kinetic exponents. Noise measurements also revealed that the critical current density and DW pinning energy can be significantly reduced in a magnetically coupled vertical ensemble of nanowires. This was attributed to strong dipolar interaction between the nanowires. Our results are particularly important in view of recent proposals for low power consumption magnetic storage devices that rely on DW motion. In all our experiments, the critical magnetic field/current density, required to set the DWs in duffusive kinetics, were found to be much smaller than the reported values for nanostrips. This could be attributed to the circular cross section of nanowires, where massless DWs results in the absence of Walker breakdown and hence in zero critical current density. At present the contribution from the non-adiabaticity, which acts as an effective field and can reduce the crit- ical current density, can not be denied. The main di±culty in quantifying the non-adiabatic spin-torque is that not only does it contain contributions due to non-adiabatic transport but also due to spin-relaxation provided by magnetic impurities or the sources for spin-orbit scattering. Fortunately, in cylindrical nanomagnet, non-adiabaticity does not affect the DW motion. There- fore, cylindrical NWs may be promising candidate for future magnetic storage devices. However, a systematic experimental study of DW dynamics in cylindrical nanomagnets is lacking. In chapter 7, silver nanowires (AgNWs) are shown to be stabilized in fcc or hcp crystal structure, depending on the electrochemical growth conditions. The AgNWs stabilized in hcp crystal structure are shown to exhibit exotic structural properties i.e. ultra low noise level, thermally driven unconventional structural phase transformation, and time dependent structural relaxation. Ultra noise level makes hcp AgNWs suitable for application in nanoelectronics and the structural transformation may be exploited for use in smart materials. Though time resolved transmission electron microscopy and noise measurements provide some understanding of the hcp AgNWs formation, the precise growth mechanism is still not clear. Future scope of the work The results in this thesis provide the groundwork for a good understanding of stochastic DW kinetics in isolated as well as ensemble of magnetic nanocylinders. Some extensions to this work that would help expand and strengthen the results, are listed below; 1. In all the nanocylinders used for our experiments the source of stochasticity in DWkinetics were randomly distributed structural defects. For a controlled injection and detection of DWs between the voltage probes, it would be of great importance to fabricate artificial notches (pinning centers) in the NW. These notches can be fabricated either by using nano-indentation or by a focussed ion beam. 2. To investigate whether DWs in different parts of the nanowire exhibit spatio-temporal correlation, a simultaneous detection of DWkinetics (through noise measurement) between different volage probes needs to be done. If the propagation time of DWs scales with the distance between the voltage probes, we can be confident of our velocity measurement. Then, by recording the DWvelocity as function of eld/current for nanowire (or nanostrip) absence (or presence) of the Walker breakdown can be probed. This would be a significant result for future spintronic devices. With an accurate determination of velocity even non- adiabaticity parameter may be calculated and one can see its effect on DW dynamics. 3. A complete understanding of sustained avalanches at finite magnetic fields, characterized by a high spectral exponent (a>¸ 2:5) in an ensemble of nanowires is still lacking. Per- forming a controlled experiment on a single nanowire, by varying the number of nanowires in the alumina matrix, one can study the chaotic dynamics of DWs in the ensemble in very accurate manner. All the experiments on AgNWs were performed on ensembles. The large change in a as well as noise magnitude in hcp AgNWs could arise from stress relaxation due to the presence of an insulating matrix or structural relaxation, determined by the nanowire growth kinetics. To resolve this issue, time and temperature dependent noise measurements should be performed on single nanowire stabilized in both hcp and fcc crystal structure.

Metallic Nanowires

Nickel Nanowires (NiNWs)

Silver Nanowires (AgNWs)

Nanowires - Magnetic Properties

Resistivity Noise

Nanowires - Resistivity Noise

Domain Wall Depinning Kinetics

Nickel Nanowires - Domain Wall Kinetics

Magnetoresistance

Nanoscale

Nanostrips

Resistant Noise

Nanomagnet

Ferromagnetic Nanocylinders

Nanotechnology