Topographical and mechanical characterization of living eukaryotic cells on opaque substrates: development of a general procedure and its application to the study of non-adherent lymphocytes

The mechanical behavior of living murine T-lymphocytes was assessed by atomic force microscopy (AFM). A robust experimental procedure was developed to overcome some features of lymphocytes, in particular their spherical shape and non-adherent character. The procedure included the immobilization of the lymphocytes on amine-functionalized substrates, the use of hydrodynamic effects on the deflection of the AFM cantilever to monitor the approaching, and the use of the jumping mode for obtaining the images. Indentation curves were analyzed according to Hertz's model for contact mechanics. The calculated values of the elastic modulus are consistent both when considering the results obtained from a single lymphocyte and when comparing the curves recorded from cells of different specimens

Internal quantum efficiency of III-nitride quantum dot superlattices grown by plasma-assisted molecular-beam epitaxy

We present a study of the optical properties of GaN/AlN and InGaN/GaN quantum dot (QD) superlattices grown via plasma-assisted molecular-beam epitaxy, as compared to their quantum well (QW) counterparts. The three-dimensional/two-dimensional nature of the structures has been verified using atomic force microscopy and transmission electron microscopy. The QD superlattices present higher internal quantum efficiency as compared to the respective QWs as a result of the three-dimensional carrier localization in the islands. In the QW samples, photoluminescence (PL) measurements point out a certain degree of carrier localization due to structural defects or thickness fluctuations, which is more pronounced in InGaN/GaN QWs due to alloy inhomogeneity. In the case of the QD stacks, carrier localization on potential fluctuations with a spatial extension smaller than the QD size is observed only for the InGaN QD-sample with the highest In content (peak emission around 2.76 eV). These results confirm the efficiency of the QD three-dimensional confinement in circumventing the potential fluctuations related to structural defects or alloy inhomogeneity. PL excitation measurements demonstrate efficient carrier transfer from the wetting layer to the QDs in the GaN/AlN system, even for low QD densities (~1010 cm-3). In the case of InGaN/GaN QDs, transport losses in the GaN barriers cannot be discarded, but an upper limit to these losses of 15% is deduced from PL measurements as a function of the excitation wavelength.

High quality InAlN single layers lattice-matched to GaN grown by molecular beam epitaxy

We report on properties of high quality ~60 nm thick InAlN layers nearly in-plane lattice-matched to GaN, grown on c-plane GaN-on-sapphire templates by plasma-assisted molecular beam epitaxy. Excellent crystalline quality and low surface roughness are confirmed by X-ray diffraction, transmission electron microscopy, and atomic force microscopy. High annular dark field observations reveal a periodic in-plane indium content variation (8 nm period), whereas optical measurements evidence certain residual absorption below the band-gap. The indium fluctuation is estimated to be +/- 1.2% around the nominal 17% indium content via plasmon energy oscillations assessed by electron energy loss spectroscopy with sub-nanometric spatial resolution.

Nanocrack-induced leakage current in AlInN/AlN/GaN

Here we report on the study of nano-crack formation in Al1−xInxN/AlN/GaN heterostructures, on its association with composition fluctuation and on its local electrical properties. It is shown here that indium segregation at nano-cracks and threading dislocations originating from the non-pseudomorphic AlN interlayer could be the cause of the high reverse-bias gate leakage current of Ni/Au Schottky contacts on Al1−xInxN/AlN/GaN heterostructures and significantly affects the contact rectifying behavior. Segregation of indium around crack tips in Al1−xInxN acting as conductive paths was assessed with conductive atomic force microscopy.

Desarrollo de un procedimiento para la observación y caracterización mecánica de células sobre sustratos opacos mediante microscopía de fuerzas atómicas : aplicación al estudio de linfocitos

Las células en los tejidos biológicos están continuamente sometidas a estímulos físicos tales como la presión hidrostática y esfuerzos de tracción, compresión o cortante, entre otros. La importancia de los estímulos mecánicos en el comportamiento de las células se ha reconocido recientemente al comprobarse cómo la naturaleza de estas fuerzas puede cambiar en patologías tales como las enfermedades vasculares o el cáncer. En respuesta a estos cambios, las células reaccionan modificando desde su forma o aspecto hasta su ciclo celular. Consecuentemente, el interés por el comportamiento mecánico de las células ha experimentado un auge creciente que ha requerido el desarrollo de varias técnicas de caracterización. En este contexto, se puede afirmar que una de las técnicas que ha irrumpido con más fuerza en esta nueva área, situada entre el mundo biológico y el físico, es la microscopía de fuerza atómica. En esta Tesis se ha abordado el estudio mediante microscopía de fuerza atómica de linfocitos de ratón que constituyen un linaje celular especialmente difícil de caracterizar mediante esta técnica por su tamaño y naturaleza no adherente. Los linfocitos, como actores fundamentales del sistema inmune, tienen gran importancia en la determinación de la respuesta que un organismo desencadena ante la presencia de un biomaterial. Bajo esta premisa, y como condición previa a la caracterización de los linfocitos, ha sido necesario el desarrollo de una metodología robusta y de amplia aplicabilidad que permita el estudio de células sobre biomateriales. Finalmente y con el objetivo de correlacionar el comportamiento mecánico de los linfocitos con alguna característica fisiológica relevante, se ha analizado la hipótesis de que el comportamiento mecánico pueda ser utilizado como marcador de la edad biológica. Consecuentemente se ha abordado el estudio del comportamiento mecánico de los linfocitos clasificados por grupos de edad, de manera que se han obtenido los primeros resultados que indican cómo puede manifestarse el proceso de inmunosenescencia -depresión del sistema inmune relacionada con el envejecimiento- en el comportamiento mecánico de las células del sistema inmune. Cells within tissues are continuously exposed to physical forces including hydrostatic pressure, shear stress, and compression and tension forces. The relevance of these mechanical stimuli has recently been recognised by different works in which significant changes were observed in these forces when they were measued in individuals affected by cardiovasvular diseases or cancer. Cells may alter their orientation, shape, internal constitution, contract, migrate, adhere, modify the synthesis and degradation of extracellular constituents, or even their life cycle in response to perturbations in their mechanical environment. As a consequence of this, the attention in cell mechanical behavior has undergone a significant thrust and novel techniques have been developed. In this context, atomic force microscopy has become a basic tool for the progress of this field. In this Thesis, the mechanical behavior of living murine T-lymphocytes was assessed by atomic force microscopy. Lymphocytes play a main role in the immune system of the individual and, consequently, in the immune response triggered by the presence of a biomaterial. The observation and characterization of the lymphocytes required the development of a robust experimental procedure that allowed overcoming the difficulties related to the analysis of this cell lineage, in particular their relatively large size and non-adherent character. These procedures could be easily transferred to other non-adherent cell lineages. Finally, to check the viability of developed method, we study the lymphocyte mechanical behavior as a function of the murine ageing. The obtained data represent a first step in the knowledge about how mechanical stimuli can affect the age-dependent decrease in immunological competence, i.e., the immunosenescence.

Non contact inspection of the fatigue damage state of carbon fiber reinforced polymer by optical surface roughness measurements

This work presents the evaluation of a new non-contact technique to assess the fatigue damage state of CFRP structures by measuring surface roughness parameters. Surface roughness and stiffness degradation have been measured in CFRP coupons cycled with constant amplitude loads, and a Pearson?s correlation of 0.79 was obtained between both variables. Results suggest that changes on the surface roughness measured in strategic zones of components made of the evaluated CFRP, could be indicative of the level of damage due to fatigue loads. This methodology could be useful for other FRP due to similarities in the fatigue damage process.

Stranski-Krastanov InN/InGaN quantum dots grown directly on Si(111)

The authors discuss and demonstrate the growth of InN surface quantum dots on a high-In-content In0.73Ga0.27N layer, directly on a Si(111) substrate by plasma-assisted molecular beam epitaxy. Atomic force microscopy and transmission electron microscopy reveal uniformly distributed quantum dots with diameters of 10–40 nm, heights of 2–4 nm, and a relatively low density of ∼7 × 109 cm−2. A thin InN wetting layer below the quantum dots proves the Stranski-Krastanov growth mode. Near-field scanning optical microscopy shows distinct and spatially well localized near-infrared emission from single surface quantum dots. This holds promise for future telecommunication and sensing devices.