759 research outputs found
Practical expressions for the internal energy and pressure of Yukawa fluids
Simple practical expressions are put forward, which allow to estimate
thermodynamic properties of Yukawa fluids in a wide range of coupling, up to
the fluid-solid phase transition. These expressions demonstrate excellent
agreement with the available results from numerical simulations. The approach
provides simple and accurate tool to estimate thermodynamic properties of
Yukawa fluids and related systems in a broad range of parameters.Comment: To be published in Phys. Rev.
Fluid approach to evaluate sound velocity in Yukawa systems (complex plasmas)
The conventional fluid description of multi-component plasma, supplemented by
an appropriate equation of state for the macroparticle component, is used to
evaluate the longitudinal sound velocity of Yukawa fluids. The obtained results
are in very good agreement with those obtained earlier employing the
quasi-localized charge approximation and molecular dynamics simulations in a
rather broad parameter regime. Thus, a simple yet accurate tool to estimate the
sound velocity across coupling regimes is proposed, which can be particularly
helpful in estimating the dust-acoustic velocity in strongly coupled dusty
(complex) plasmas. It is shown that, within the present approach, the sound
velocity is completely determined by particle-particle correlations and the
neutralizing medium (plasma), apart from providing screening of the Coulomb
interaction, has no other effect on the sound propagation. The ratio of the
actual sound velocity to its "ideal gas" (weak coupling) scale only weakly
depends on the coupling strength in the fluid regime, but exhibits a pronounced
decrease with the increase of the screening strength. The limitations of the
present approach in applications to real complex plasmas are briefly discussed.Comment: Physical Review E (in press
The Bohm sheath criterion in strongly coupled complex plasmas
A modification of the classical Bohm sheath criterion is investigated in complex plasmas containing Boltzmann electrons, cold fluid ions and strongly coupled microparticles. Equilibrium is provided by an effective 'temperature' associated with electrostatic interactions between charged grains. Using the small-potential expansion approach of the Sagdeev potential, a significant reduction of the ion Bohm velocity is obtained for complex plasma parameters relevant for experiments. The result is of consequence for all problems involving ion drag on microparticles, including parametric instability, structure formation, wave propagation, etc
Shocks in economic growth = shocking effects on agricultural markets?
Projections on the development of agricultural commodity markets underlie a given set of assumptions on economic growth. However, recent economic and financial crisis, as well as signs of quicker recovery in emerging economies, increase uncertainty in the forecasts of macroeconomic developments. This paper analyses the effects of different economic growth scenarios on agricultural commodity markets. In particular we assess the potential impacts of a faster economic growth in emerging economies on the one hand and of a replication of the recent economic downturn on the other hand. The empirical analysis uses the AGLINKCOSIMO model and builds upon the recently published European agricultural outlook of the EU Commission. The simulation results demonstrate that higher economic growth influences demand more than supply, resulting in higher world market prices. Emerging economies tend to import more and stock less in order to cover their demand needs, while the rest of the world increases its exports. In total the ending stocks decrease and combined with the increased consumption, the stock-to-use ratio decreases. Replication of an economic downturn affects the markets differently, depending on how elastic or inelastic the markets react to price signals. Livestock markets appear more stable and do not regain their baseline levels within a 5-year period. The magnitude of the effects is smaller the longer the simulated time path is and certainly depends on the introduced shock.economic growth, agricultural commodity markets, AGLINK-COSIMO, International Relations/Trade,
Is Newer Always Better? Assessing Recombination Types of Digital Services
Organizations rely on recombination to develop new innovative services. However, a comprehensive understanding of the influence of different recombination types on user perceptions of such services is missing. Based on theory from service science and the concept of recombinant digital innovation, we derived a TAM-based research model to study how associative and additive recombination types influence user perceptions of services and tested it in an online experiment with 362 participants. Our results show that additive recombination types are more capable of positively affecting perceived novelty, perceived value, and adoption intention than associative types, which is dependent on the respective setting of the service. We contribute to research by shedding light on the influence of different recombination types on user perceptions of services and the need for operand-specific digital innovation in service systems. Practitioners can use our findings to improve the configuration of service systems
Agglomeration of microparticles in complex plasmas
Agglomeration of highly charged microparticles was observed and studied in
complex plasma experiments carried out in a capacitively coupled rf discharge.
The agglomeration was caused by strong dust density waves triggered in a
particle cloud by decreasing neutral gas pressure. Using a high-speed camera
during this unstable regime, it was possible to resolve the motion of
individual microparticles and to show that the relative velocities of some
particles were sufficiently high to overcome the mutual Coulomb repulsion and
hence to result in agglomeration. After stabilising the cloud again through the
increase of the pressure, we were able to observe the aggregates directly with
a long-distance microscope. We show that the agglomeration rate deduced from
our experiments is in good agreement with theoretical estimates. In addition,
we briefly discuss the mechanisms that can provide binding of highly charged
microparticles in a plasma.Comment: submitted to Phys. Plasm
Theory of a cavity around a large floating sphere in complex (dusty) plasma
In the last experiment with the PK-3 Plus laboratory onboard the
International Space Station, interactions of millimeter-size metallic spheres
with a complex plasma were studied~[M. Schwabe {\it et al.}, New J. Phys. {\bf
19}, 103019 (2017)]. Among the phenomena observed was the formation of cavities
(regions free of microparticles forming a complex plasma) surrounding the
spheres. The size of the cavity is governed by the balance of forces
experienced by the microparticles at the cavity edge. In this article we
develop a detailed theoretical model describing the cavity size and demonstrate
that it agrees well with sizes measured experimentally. The model is based on a
simple practical expression for the ion drag force, which is constructed to
take into account simultaneously the effects of non-linear ion-particle
coupling and ion-neutral collisions. The developed model can be useful for
describing interactions between a massive body and surrounding complex plasma
in a rather wide parameter regime.Comment: 9 pages, 4 figures; to be published (2019
Channeling of particles and associated anomalous transport in a 2D complex plasma crystal
Implications of recently discovered effect of channeling of upstream extra
particles for transport phenomena in a two-dimensional plasma crystal are
discussed. Upstream particles levitated above the lattice layer and tended to
move between the rows of lattice particles. An example of heat transport is
considered, where upstream particles act as moving heat sources, which may lead
to anomalous heat transport. The average channeling length observed was 15 - 20
interparticle distances. New features of the channeling process are also
reported
Thermodynamics of Yukawa fluids near the one-component-plasma limit
Thermodynamics of weakly screened (near the one-component-plasma limit)
Yukawa fluids in two and three dimensions is analyzed in detail. It is shown
that the thermal component of the excess internal energy of these fluids, when
expressed in terms of the properly normalized coupling strength, exhibits the
scaling pertinent to the corresponding one-component-plasma limit (the scalings
differ considerably between the two- and three-dimensional situations). This
provides us with a simple and accurate practical tool to estimate thermodynamic
properties of weakly screened Yukawa fluids. Particular attention is paid to
the two-dimensional fluids, for which several important thermodynamic
quantities are calculated to illustrate the application of the approach.Comment: Submitted to Phys. Plasma
Wake-mediated propulsion of an upstream particle in two-dimensional plasma crystals
The wake-mediated propulsion of an "extra" particle in a channel of two
neighboring rows of a two-dimensional plasma crystal, observed experimentally
by Du et al. [Phys. Rev. E 89, 021101(R) (2014)], is explained in simulations
and theory. We use the simple model of a pointlike ion wake charge to reproduce
this intriguing effect in simulations, allowing for a detailed investigation
and a deeper understanding of the underlying dynamics. We show that the
nonreciprocity of the particle interaction, owing to the wake charges, is
responsible for a broken symmetry of the channel that enables a persistent
self-propelled motion of the extra particle. We find good agreement of the
terminal extra-particle velocity with our theoretical considerations and with
experiments.Comment: 7 pages, 4 figures, PRL (https://journals.aps.org/prl/), updated
version with correct author affiliation
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