1,364 research outputs found
Particle-in-cell simulation of a mildly relativistic collision of an electron-ion plasma carrying a quasi-parallel magnetic field: Electron acceleration and magnetic field amplification at supernova shocks
Plasma processes close to SNR shocks result in the amplification of magnetic
fields and in the acceleration of electrons, injecting them into the diffusive
acceleration mechanism. The acceleration of electrons and the B field
amplification by the collision of two plasma clouds, each consisting of
electrons and ions, at a speed of 0.5c is investigated. A quasi-parallel
guiding magnetic field, a cloud density ratio of 10 and a plasma temperature of
25 keV are considered. A quasi-planar shock forms at the front of the dense
plasma cloud. It is mediated by a circularly left-hand polarized
electromagnetic wave with an electric field component along the guiding
magnetic field. Its propagation direction is close to that of the guiding field
and orthogonal to the collision boundary. It has a low frequency and a
wavelength that equals several times the ion inertial length, which would be
indicative of a dispersive Alfven wave close to the ion cyclotron resonance
frequency of the left-handed mode (ion whistler), provided that the frequency
is appropriate. However, it moves with the super-alfvenic plasma collision
speed, suggesting that it is an Alfven precursor or a nonlinear MHD wave such
as a Short Large-Amplitude Magnetic Structure (SLAMS). The growth of the
magnetic amplitude of this wave to values well in excess of those of the
quasi-parallel guiding field and of the filamentation modes results in a
quasi-perpendicular shock. We present evidence for the instability of this mode
to a four wave interaction. The waves developing upstream of the dense cloud
give rise to electron acceleration ahead of the collision boundary. Energy
equipartition between the ions and the electrons is established at the shock
and the electrons are accelerated to relativistic speeds.Comment: 16 pages, 18 figures, Accepted for publication by Astron & Astrophy
Energy storage systems to exploit regenerative braking in DC railway systems: Different approaches to improve efficiency of modern high-speed trains
The growing attention to environmental sustainability of transport systems made necessary to investigate the possibility of energy optimization even in sectors typically characterised by an already high level of sustainability, as in particular the railway system. One of the most promising opportunity is the optimization of the braking energy recovery, which has been already considered in tramway systems, while it is traditionally overlooked for high-speed railway systems. In this research work, the authors have developed two simulation models able to reproduce the behavior of high-speed trains when entering in a railway node, and to analyze the impact of regenerative braking in DC railway systems, including usage of energy storage systems. These models, developed respectively in the Matlab-Simscape environment and in the open source Modelica language, have been experimentally validated considering an Italian high-speed train. After validation, the authors have performed a feasibility analysis considering the use of stationary and on-board storage systems, also by taking into account capital costs of the investment and annual energy saving, to evaluate cost-effectiveness of the different solutions. The analysis has shown the possibility to improve the efficiency of high-speed railway systems, by improving braking energy recovery through the installation of such storage systems
Rendering of Pressure and Textures Using Wearable Haptics in Immersive VR Environments
Haptic systems have only recently started to be designed with wearability
in mind. Compact, unobtrusive, inexpensive, easy-to-wear, and
lightweight haptic devices enable researchers to provide compelling
touch sensations to multiple parts of the body, significantly increasing
the applicability of haptics in many fields, such as robotics, rehabilitation,
gaming, and immersive systems. In this respect, wearable
haptics has a great potential in the fields of virtual and augmented
reality. Being able to touch virtual objects in a wearable and unobtrusive
way may indeed open new exciting avenues for the fields of
haptics and VR. This work presents a novel wearable haptic system
for immersive virtual reality experiences. It conveys the sensation
of touching objects made of different materials, rendering pressure
and texture stimuli through a moving platform and a vibrotactile
abbrv-doi-hyperref-narrowmotor. The device is composed of two
platforms: one placed on the nail side of the finger and one in contact
with the finger pad, connected by three cables. One small servomotor
controls the length of the cables, moving the platform towards or
away from the fingertip. One voice coil actuator, embedded in the
platform, provides vibrotactile stimuli to the user
Unsaturated sand in the stability of the cuesta of the Temple of Hera (Agrigento)
In the Valle dei Templi in Agrigento seven Doric temples stand lengthwise the crest of a rigid calcarenite cuesta
over a layer of carbonate sand which lies along a thick stratum of clays. The environment is highly prone to landslides since topplings
of calcarenite blocks often occur. The rock slopes are moving back and the slope edge draw near to the foundation of the
Temple of Hera Lacinia contributing to increase their perilous condition. To assess the role of unsaturated sands in the instability
processes, after the compositional and textural analysis of the material, direct shear tests and oedometer tests have been carried out
on sand samples initially at the natural state, with low or very low values of natural water content, and finally at full saturation.
The mechanical behaviour of sands seems one of the main causes of the instability influenced by the presence of an open metastable
structure, which develops through bonding mechanisms generated via suctions and/or through cementing material such as clay
or salts
A landscape approach in the isotopic modeling of natural precipitations: two cases in Mediterranean mountain areas
The present paper proposes a method to simplify the very complex isotopic fractionation processes occurring during the water cycle. The method is constrained by a relatively small number of variables, with the precision needed in hydrological applications. After a theoretical
introduction on the adopted interpolation criteria, two cases in the Mediterranean are presented.
In both cases the evaluation of the “geometric
complexity” of the systems appears to be the
best tool to produce reliable isotopic models. If
the complexity is low, it is apparently easier to
fit different models; on the contrary the higher
the complexity is, more difficult it is to find a
reliable model but, at the same time, more difficult it is to find effective alternative models
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