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Solution synthesis and actuation of magnetic nanostructuresVach, Peter 18 February 2015 (has links)
Viele neue Technologien basieren auf Materialien die im Nanometerbereich strukturiert sind. Damit diese im großen Maßstab zur Anwendung gebracht werden können, werden Methoden benötigt solche nanostrukturierten Materialien kostengünstig zu produzieren. Magnetische Felder sind eine vielversprechende Möglichkeit die Anordnung von Nanostrukturen zu beeinflussen. In dieser Doktorarbeit wird eine Methode für die Herstellung magnetischer Nanostrukturen in Lösung präsentiert. Die Herstellungsmethode ist skalierbar und kostengünstig. Die synthetisierten Strukturen haben zufällige Formen und bewegen sich unter dem Einfluss eines externen rotierenden Magnetfelds im rechten Winkel zu der Ebene in der das Magnetfeld rotiert. Die dimensionslosen Geschwindigkeiten dieser zufällig geformten Propeller sind vergleichbar mit jenen früher publizierter helikaler Propeller. Das beobachtete Verhältnis zwischen Anregungsfrequenz und Propellergeschwindigkeit konnte mittels eines Drehmomentgleichgewichts verstanden werden. Dieses vertiefte Verständnis der Propellerbewegung ermöglichte eine theoretische Studie zur Kontrolle von Propellerschwärmen. Hierbei werden mehrere Propeller entlang frei wählbarer Bahnen gesteuert. Eine Kontrollstrategie wurde gefunden, welche die magnetische Feldstärke minimiert, die zum Erreichen einer vorgegebenen Genauigkeit nötig ist. Schließlich wurde das kollektive Verhalten von großen Mengen von magnetischen Propellern untersucht. Sowohl zufällig geformte als auch helikale Propeller bilden Zusammenballungen, die im dynamischen Gleichgewicht kreisförmig sind und langsam rotieren. Gleichförmig helikale Propeller ordnen sich in diesen Zusammenballungen hexagonal an. Der Vergleich zwischen Beobachtungen und Simulationen zeigte, dass hydrodynamische Interaktionen für die Bildung der Zusammenballungen nicht notwendig sind, aber dazu führen dass sich eine Randregion bildet, in der die Winkelgeschwindigkeit der Propeller erhöht ist. / New ways to cheaply produce and assemble useful micro- and nanostructures are needed to facilitate their deployment in novel technologies. Magnetic fields are a promising possibility to guide the assembly of nanostructures. This thesis presents a method to synthesize magnetic nanostructures in solution which can be actuated by external rotating magnetic fields. The synthesis method is scalable and can cheaply produce randomly shaped magnetic nanostructures in large quantities. The synthesized structures have random shapes and were observed to propel under the influence of an external magnetic field, perpendicular to the plane in which the external field is rotating. The random shapes move with dimensionless speeds that are comparable to those of previously published, nanofabricated propellers with controlled helical geometries. The observed relationship between actuating frequency and propulsion speed could be understood with a simple torque balance model. This improved understanding opened the door for a theoretical study on swarm control, i.e. the steering of several magnetic propellers along independent trajectories. A particular control strategy (critical control) was found, that minimizes the required magnetic field strength needed to achieve a certain control precision. Finally, the collective behavior of large numbers of propellers, moving upwards against gravity and towards a glass surface, was investigated. Both randomly shaped, as well as nanofabricated propellers were observed to form clusters which are circular and rotate slowly in dynamic equilibrium. The nanofabricated propellers displayed hexagonal ordering inside the clusters. Comparing the observed cluster dynamics to simulations revealed that hydrodynamic interactions between the propellers are not necessary for cluster formation, but lead to the formation of a boundary layer at the cluster edge, in which the angular velocity of the propellers is higher than in the rest of the rotating cluster.
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Dynamics, Fluctuations and Rheological Applications of Magnetic NanopropellersGhosh, Arijit January 2014 (has links) (PDF)
Micron scale robots going inside our body and curing various ailments is a technolog¬ical dream that easily captures our imagination. However, with the advent of novel nanofabrication and nanocharacterization tools there has been a surge in the research in this field over the last decade. In order to achieve locomotion (swim) at these small length scales, special strategies need to be adopted, that is able to overcome the large viscous damping that these microbots have to face while moving in the various bod¬ily fluids. Thus researchers have looked into the swimming strategies found in nature like that of bacteria like E.coli found in our gut or spermatozoa in the reproductive mucus. Biomimetic swimmers that replicate the motion of these small microorganisms hold tremendous promise in a host of biomedical applications like targeted drug delivery, microsurgery, biochemical sensing and disease diagnosis.
In one such method of swimming at very low Reynolds numbers, a micron scale helix has been fabricated and rendered magnetic by putting a magnetic material on it. Small rotating magnetic fields could be used then to rotate the helix, which translated as a result of the intrinsic translation rotation coupling in a helix. The present work focussed on the development of such a system of nanopropellers, a few microns in length, the characterization of its dynamics and velocity fluctuations originating from thermal noise. The work has also showed a possible application of the nanopropellers in microrheology where it could be used as a new tool to measure the rheological characteristics of a complex heterogeneous environment with very high spatial and temporal resolutions.
A generalized study of the dynamics of these propellers under a rotating field, has showed the existence of a variety of different dynamical configurations. Rigid body dynamics simulations have been carried out to understand the behaviour. Significant amount of insight has been gained by solving the equations of motion of the object analytically and it has helped to obtain a complete understanding, along with providing closed form expressions of the various characteristics frequencies and parameters that has defined the motion.
A study of the velocity fluctuations of these chiral nanopropellers has been carried out, where the nearby wall of the microfluidic cell was found to have a dominant effect on the fluctuations. The wall has been found to enhance the average level of fluctuations apart from bringing in significant non Gaussian effects. The experimentally obtained fluctuations has been corroborated by a simulation in which a time evolution study of the governing 3D Langevin dynamics equations has been done. A closer look at the various sources of velocity fluctuations and a causality study thereof has brought out a minimum length scale below which helical propulsion has become impractical to achieve because of the increased effect of the orientational fluctuations of the propeller at those small length scales.
An interesting bistable dynamics of the propeller has been observed under certain experimental conditions, in which the propeller randomly switched between the different dynamical states. This defied common sense because of the inherent deterministic nature of the governing Stokes equation. Rigid body dynamics simulations and stability analysis has shown the existence of time scales in which two different dynamical states of the propeller have become stable. Thus the intrinsic dynamics of the system has been found to be the reason behind the bistable behaviour, randomness being brought about by the thermal fluctuations present in the system.
Finally, in a novel application of the propellers, they have been demonstrated as a tool for microrheological mapping in a complex fluidic environment. The studies done in this work have helped to develop this method of active microrheology in which the measurement times are orders of magnitude smaller than its existing counterparts.
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