First principles study of nano-scale materials : quantum dots and nanowires / Étude des première principes de matériaux a l'échelle nanométrique : boîtes quantiques et nanofils

Vilhena Albuquerque d'Orey, José Guilherme

19 September 2011

Au cours de cette thèse on étude deux des plus populaires systèmes de nano-échelle, nano fil et points quantiques (quantum dots), dans le cadre d'une approximation basé sur des premiers principes. Afin d'atteindre cet objectif, nous avons utilisé et développé des théories plus sophistiquées qui nous ont permis d'avoir un meilleur aperçu de la façon dont les systèmes se comportent. Un aspect commun qui limite ces deux types de systèmes (nano fil et points quantiques) est la souplesse de contrôler les propriétés électroniques et optiques. Cette accordabilité des propriétés électroniques et optiques les dote d'un grand intérêt technologique, et elle est la raison de sa popularité / In this thesis we studied two of the most popular nano-scale systems, nano-wires and quantum dots, via a first-principles approach. In order to achieve this objective we have used and developed state-of-the-art theories that allowed us to have a greater insight into the the way this systems behave. One common aspect that bounds this two class of systems (nano-wires and quantum dots) is the flexibility to control their electronic and optical properties. This tunability of their electronic and optical properties, endows them of great technological interest, and is the reason behind their popularity

Premiers principes

Gaz d'électrons en deux dimensions

Nano-échelle

Points quantiques

GW

BSE

DFT

TDDFT

First-principles

2D electron gas

Nano-wires

Quantum-dots

GW

BSE

DFT

TDDFT

530.81

Développement et caractérisation avancée de matériaux magnétiques durs de haute performance / Development and advanced characterization of high performance hard magnetic materials

Ponomareva, Svetlana

30 May 2017

L'auteur n'a pas fourni de résumé en français / Nowadays in medicine and biotechnology a wide range of applications involves magnetic micro/nano-object manipulation including remote control of magnetic beads, trapping of drug vectors, magnetic separation of labelled cells and so on. Handling and positioning magnetic particles and elements functionalized with these particles has greatly benefited from advances in microfabrication. Indeed reduction in size of the magnet while maintaining its field strength increases the field gradient. In this context, arrays made of permanent micromagnets are good candidates for magnetic handling devices. They are autonomous, suitable for integration into complex systems and their magnetic action is restricted to the region of interest.In this thesis we have elaborated an original approach based on AFM and MFM for quantitative study of the magnetic force and associated force gradients induced by TMP micromagnet array on an individual magnetic micro/nano-object. For this purpose, we have fabricated smart MFM probes where a single magnetic (sub)micronic sphere was fixed at the tip apex of a non-magnetic probe thanks to a dual beam FIB/SEM machine equipped with a micromanipulator.Scanning Force Microscopy conducted with such probes, the so-called Magnetic Particle Scanning Force Microscopy (MPSFM) was employed for 3D mapping of TMP micromagnets. This procedure involves two main aspects: (i) the quantification of magnetic interaction between micromagnet array and attached microsphere according to the distance between them and (ii) the complementary information about micromagnet array structure. The main advantage of MPSFM is the use of a probe with known magnetization and magnetic volume that in combination with modelling allows interpreting the results ably.We conducted MPSFM on TMP sample with two types of microparticle probes: with superparamagnetic and NdFeB microspheres. The measurements carried out with superparamagnetic microsphere probes reveal attractive forces (up to few tens of nN) while MFM maps obtained with NdFeB microsphere probes reveal attractive and repulsive forces (up to one hundred of nN) for which the nature of interaction is defined by superposition of microsphere and micromagnet array magnetizations. The derived force and its gradient from MFM measurements are in agreement with experiments on microparticle trapping confirming that the strongest magnetic interaction is observed above the TMP sample interfaces, between the areas with opposite magnetization. Thanks to 3D MFM maps, we demonstrated that intensity of magnetic signal decays fast with the distance and depends on micromagnet array and microsphere properties.Besides the magnetic interaction quantification, we obtained new information relevant to TMP sample structure: we observed and quantified the local magnetic roughness and associated fluctuations, in particular in zones of reversed magnetization. The variation of detected signal can reach the same order of magnitude as the signal above the micromagnet interfaces. These results complete the experiments on particle trapping explaining why magnetic microparticles are captured not only above the interfaces, but also inside the zones of reversed magnetization.Quantitative measurements of the force acting on a single (sub)microsphere associated to the modelling approach improve the understanding of processes involved in handling of magnetic objects in microfluidic devices. This could be employed to optimize the parameters of sorting devices and to define the quantity of magnetic nanoparticles required for labelling of biological cells according to their size. More generally these experimental and modelling approaches of magnetic interaction can meet a high interest in all sorts of applications where a well-known and controlled non-contact interaction is required at micro and nano-scale.

Réseau de micro-aimants permanents

Modélisation micromagnétique

Micromagnétisme

Permanent micromagnet array

Atomic and Magnetic Force Microscopy

Microparticle probe fabrication

Micromagnetic modelling

Micromagnetism

530