Features relaxation grain and defect structure of nanostructured alloy V-Cr-ZrO2 alloy

The study of parameters of the defect structure near the recrystallization temperature of the dispersion-strengthened alloy V-Cr-ZrO2 after deformation by torsion under pressure is presented

The 'indigenous native peasant' trinity: imagining a plurinational community in Evo Morales's Bolivia

Over the last two decades Latin America has been a laboratory for the implementation of new models of state and citizenship. In Bolivia the (neo)liberal multicultural paradigm dominant in the 1990s has recently been replaced by a plurinational paradigm, which implies a deepening of the decentralization process and the strengthening of rights for traditionally marginalized social sectors. This paper describes the process of construction of a plurinational ‘imagined community’ and, in particular, of one of its core narratives: The ‘indigenous native peasant’. I argue that the negotiation of this collective identity and its inclusion as one of the core ideas in the new constitution is the result of a contingent strategy in response to a highly conflictive scenario, which has not been, however, able to trigger a change in the way people identify themselves. Yet in recent years, social movements’ identities have been shaped by centrifugal forces. These forces should be understood as the result of a process of collective actors’ adaptation to institutional and regulatory reforms and contribute to explaining the increase of new intrasocietal conflicts linked to the redefinition of citizenship and territorial boundaries

A unique approach to reveal the nanocomposite nc-MN/SiN-layer architecture of thin films via electrical measurements

By addition of Si to a binary transition metal nitride MN (e.g. TiN, ZrN, NbN, CrN), the hardness, thermal stability and chemical inertness of films have been considerably improved. The formation of a ternary M–Si–N ternary phase is possible under specific conditions such as low temperature, high deposition rate and low nitrogen pressure. The formation of nanocomposite materials (e.g. crystallites of MN + a thin layer of SiNx) is also possible under a wide range of deposition conditions. In such nanocomposite thin films the crystallite sizes are on the order of a few nanometers. The grain surfaces and boundaries have an important effect on the physical properties. The arrangement and chemical composition of the so-called “amorphous” minority phase (SiNx) are crucial for electrical and mechanical properties. The location, composition and thickness of the amorphous phase must therefore be known precisely. Their experimental determination is challenging due to the small concentration and in particular the geometry of the “amorphous” phase: approximately one monolayer either completely or partially covering the MN nanocrystallites. TEM investigations on such composites are known to have their limitations. It will be shown that the electrical resistivity, measured as a function of temperature, provides an experimental means for following the thickness evolution of the SiNx coverage layer, in such nanocomposite films

Influence of bias voltage on the microstructure and physical properties of magnetron sputtered Zr–Si–N nanocomposite thin films

e report an investigation concerning the influence of ion bombardment on the nanostructure and physical properties of Zr–Si–N nanocomposite thin films. The films were deposited by reactive magnetron sputtering from individual Zr and Si targets. The Si content was varied by changing the power applied to the Si target. The increase of ion bombardment energy was obtained by applying a negative potential Ub = − 150 V to the substrate. The evolution of the film texture, grain size and lattice constant was mapped out using X-ray diffraction measurements. Zr–Si–N films deposited at a substrate temperature Ts = 510 K with a bias voltage of Ub = − 150 V exhibit less pronounced columnar structure with small crystallites having various orientations. The maximum nanohardness of 39 GPa is reached for the films at about 2.5 at.% Si, 8 nm grain size and 0.3 Si surface coverage. The increased energy of ionic species reaching the substrate when a negative bias voltage is applied seems to have the opposite effect to that of increasing substrate temperature: reduced SiNx coverage on the ZrN nanocrystallites