2,494 research outputs found
A Low Mach Number Model for Moist Atmospheric Flows
We introduce a low Mach number model for moist atmospheric flows that
accurately incorporates reversible moist processes in flows whose features of
interest occur on advective rather than acoustic time scales. Total water is
used as a prognostic variable, so that water vapor and liquid water are
diagnostically recovered as needed from an exact Clausius--Clapeyron formula
for moist thermodynamics. Low Mach number models can be computationally more
efficient than a fully compressible model, but the low Mach number formulation
introduces additional mathematical and computational complexity because of the
divergence constraint imposed on the velocity field. Here, latent heat release
is accounted for in the source term of the constraint by estimating the rate of
phase change based on the time variation of saturated water vapor subject to
the thermodynamic equilibrium constraint. We numerically assess the validity of
the low Mach number approximation for moist atmospheric flows by contrasting
the low Mach number solution to reference solutions computed with a fully
compressible formulation for a variety of test problems
A Hybrid Adaptive Low-Mach-Number/Compressible Method: Euler Equations
Flows in which the primary features of interest do not rely on high-frequency
acoustic effects, but in which long-wavelength acoustics play a nontrivial
role, present a computational challenge. Integrating the entire domain with
low-Mach-number methods would remove all acoustic wave propagation, while
integrating the entire domain with the fully compressible equations can in some
cases be prohibitively expensive due to the CFL time step constraint. For
example, simulation of thermoacoustic instabilities might require fine
resolution of the fluid/chemistry interaction but not require fine resolution
of acoustic effects, yet one does not want to neglect the long-wavelength wave
propagation and its interaction with the larger domain. The present paper
introduces a new multi-level hybrid algorithm to address these types of
phenomena. In this new approach, the fully compressible Euler equations are
solved on the entire domain, potentially with local refinement, while their
low-Mach-number counterparts are solved on subregions of the domain with higher
spatial resolution. The finest of the compressible levels communicates
inhomogeneous divergence constraints to the coarsest of the low-Mach-number
levels, allowing the low-Mach-number levels to retain the long-wavelength
acoustics. The performance of the hybrid method is shown for a series of test
cases, including results from a simulation of the aeroacoustic propagation
generated from a Kelvin-Helmholtz instability in low-Mach-number mixing layers.
It is demonstrated that compared to a purely compressible approach, the hybrid
method allows time-steps two orders of magnitude larger at the finest level,
leading to an overall reduction of the computational time by a factor of 8
Betting On Gambling: How Professional Sports Leagues Could Increase Revenues Following Murphy v. NCAA
This comment explores the avenues professional sports leagues are taking to profit from legalized sports gambling following the Murphy decision. Part II provides the modern historical legal background of sports gambling in America, discussing the Professional and Amateur Sports Protection Act and the reasoning for and the effects following the Act’s falling in Murphy. Part III analyzes the current sports gambling landscape, including the current federal and state legal landscape; society’s ever-revolving views on sports gambling; the American sports gambling industry, the offshore industry, and the growth of the industry as a whole; and the stances of sports leagues before and after Murphy. Part IV discusses the several ways in which the major sports leagues are attempting to capitalize on the potential new revenue streams and identifies which strategies will be the most successful
A Numerical Study of Methods for Moist Atmospheric Flows: Compressible Equations
We investigate two common numerical techniques for integrating reversible
moist processes in atmospheric flows in the context of solving the fully
compressible Euler equations. The first is a one-step, coupled technique based
on using appropriate invariant variables such that terms resulting from phase
change are eliminated in the governing equations. In the second approach, which
is a two-step scheme, separate transport equations for liquid water and vapor
water are used, and no conversion between water vapor and liquid water is
allowed in the first step, while in the second step a saturation adjustment
procedure is performed that correctly allocates the water into its two phases
based on the Clausius-Clapeyron formula. The numerical techniques we describe
are first validated by comparing to a well-established benchmark problem.
Particular attention is then paid to the effect of changing the time scale at
which the moist variables are adjusted to the saturation requirements in two
different variations of the two-step scheme. This study is motivated by the
fact that when acoustic modes are integrated separately in time (neglecting
phase change related phenomena), or when sound-proof equations are integrated,
the time scale for imposing saturation adjustment is typically much larger than
the numerical one related to the acoustics
J.S. Bell's Concept of Local Causality
John Stewart Bell's famous 1964 theorem is widely regarded as one of the most
important developments in the foundations of physics. It has even been
described as "the most profound discovery of science." Yet even as we approach
the 50th anniversary of Bell's discovery, its meaning and implications remain
controversial. Many textbooks and commentators report that Bell's theorem
refutes the possibility (suggested especially by Einstein, Podolsky, and Rosen
in 1935) of supplementing ordinary quantum theory with additional ("hidden")
variables that might restore determinism and/or some notion of an
observer-independent reality. On this view, Bell's theorem supports the
orthodox Copenhagen interpretation. Bell's own view of his theorem, however,
was quite different. He instead took the theorem as establishing an "essential
conflict" between the now well-tested empirical predictions of quantum theory
and relativistic \emph{local causality}. The goal of the present paper is, in
general, to make Bell's own views more widely known and, in particular, to
explain in detail Bell's little-known mathematical formulation of the concept
of relativistic local causality on which his theorem rests. We thus collect and
organize many of Bell's crucial statements on these topics, which are scattered
throughout his writings, into a self-contained, pedagogical discussion
including elaborations of the concepts "beable", "completeness", and
"causality" which figure in the formulation. We also show how local causality
(as formulated by Bell) can be used to derive an empirically testable Bell-type
inequality, and how it can be used to recapitulate the EPR argument.Comment: 19 pages, 4 figure
Coherent states and the classical-quantum limit considered from the point of view of entanglement
Three paradigms commonly used in classical, pre-quantum physics to describe
particles (that is: the material point, the test-particle and the diluted
particle (droplet model)) can be identified as limit-cases of a quantum regime
in which pairs of particles interact without getting entangled with each other.
This entanglement-free regime also provides a simplified model of what is
called in the decoherence approach "islands of classicality", that is,
preferred bases that would be selected through evolution by a Darwinist
mechanism that aims at optimising information. We show how, under very general
conditions, coherent states are natural candidates for classical pointer
states. This occurs essentially because, when a (supposedly bosonic) system
coherently exchanges only one quantum at a time with the (supposedly bosonic)
environment, coherent states of the system do not get entangled with the
environment, due to the bosonic symmetry.Comment: This is the definitive version of a paper entitled The
classical-quantum limit considered from the point of view of entanglement: a
survey (author T. Durt). The older version has been replaced by the
definitive on
An investigation into the production of glycerol biofuel from microalgae in South Africa.
M. Sc. University of KwaZulu-Natal, Durban 2013.Energy provision in South Africa is going through great changes in this first half of the 21ˢᵗ century. Ensuring delivery of electricity to all households within the country, along with continued industrial growth, has left the national electricity provider and distributor, Eskom, with insufficient capacity. Understanding of environmental and health issues related to traditional energy generation methods, along with local and international political pressure has moved the South African Government to commit to long-term energy-efficiency and renewable energy targets. In recent years the door has begun to open to foreign and private investment on the energy-supply side. At the same time, the efficiency and price of alternative renewable energy sources has significantly improved, as global investments continue to rise. Confidence in the reliability of these technologies has risen, as developed countries demonstrate greater dependence on them, and prove that they can compete with traditional fossil fuels. This is further improved as a financial cost looms on the existing environmental and health costs associated with carbon dioxide and other greenhouse gas emissions. The use of microalgae to produce stable, transportable liquid fuels at greater efficiencies than traditional biofuels, in open ponds is investigated here. For the purpose of this study the microalgae Dunaliella salina producing glycerol as a biofuel is used, but the results could apply universally to the use of open raceway ponds. Geographic Information System analysis of the maximum and minimum temperature ranges, rainfall and solar irradiance shows that 11.3% of South Africa is well suited to this technology. Mapping of the 59 biggest emitters of carbon dioxide in South Africa reveal that 5 are located within this area, and within 500 m of a major river. Despite the great variation of external factors across South Africa, the results of this study show great promise for this type of renewable technology.Dr Helen Watson is acknowledged for her her role in this project
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