16,694 research outputs found
Stirring apparatus for plural test tubes Patent
Design of mechanical device for stirring several test tubes simultaneousl
Studies on the Localization and Mechanism of Alkaline Metal Activation of Protein Synthesis
Localization and mechanism of rat liver protein synthesis by alkali metals and ammonium ion
Reducing bias and quantifying uncertainty in watershed flux estimates: the R package loadflex
Many ecological insights into the function of rivers and watersheds emerge from quantifying the flux of solutes or suspended materials in rivers. Numerous methods for flux estimation have been described, and each has its strengths and weaknesses. Currently, the largest practical challenges in flux estimation are to select among these methods and to implement or apply whichever method is chosen. To ease this process of method selection and application, we have written an R software package called loadflex that implements several of the most popular methods for flux estimation, including regressions, interpolations, and the special case of interpolation known as the period-weighted approach. Our package also implements a lesser-known and empirically promising approach called the “composite method,” to which we have added an algorithm for estimating prediction uncertainty. Here we describe the structure and key features of loadflex, with a special emphasis on the rationale and details of our composite method implementation. We then demonstrate the use of loadflex by fitting four different models to nitrate data from the Lamprey River in southeastern New Hampshire, where two large floods in 2006–2007 are hypothesized to have driven a long-term shift in nitrate concentrations and fluxes from the watershed. The models each give believable estimates, and yet they yield different answers for whether and how the floods altered nitrate loads. In general, the best modeling approach for each new dataset will depend on the specific site and solute of interest, and researchers need to make an informed choice among the many possible models. Our package addresses this need by making it simple to apply and compare multiple load estimation models, ultimately allowing researchers to estimate riverine concentrations and fluxes with greater ease and accuracy
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The uses of process modeling : a framework for understanding modeling formalisms
There is wide-spread recognition of the urgent need to improve software processes in order to improve the performance of software organizations. Process models are essential in achieving understanding and visibility of processes and are important for other uses including the analysis of processes for improvement. It has been increasingly difficult to compare and evaluate the variety of process modeling formalisms that have appeared in recent years without a clear understanding of precisely for what they will be used. The contribution of this paper is to provide an understanding and a fairly comprehensive catalog of the applications of process modeling for which formalisms may be used. The primary mechanism for doing this is a guided tour of the literature on process modeling supplemented by recent industrial experience. In the paper, basic definitions concerning processes, process descriptions and process modeling are reviewed and then uses of process modeling are surveyed under the following headings: communication among process participants, construction of new processes, control of processes, process· analysis, and process support by automation. Comments are offered on paradigms for process modeling formalisms and directions for future work to permit evolution of a discipline of process engineering are given
Brane classical and quantum cosmology from an effective action
Motivated by the Randall-Sundrum brane-world scenario, we discuss the
classical and quantum dynamics of a (d+1)-dimensional boundary wall between a
pair of (d+2)-dimensional topological Schwarzschild-AdS black holes. We assume
there are quite general -- but not completely arbitrary -- matter fields living
on the boundary ``brane universe'' and its geometry is that of an
Friedmann-Lemaitre-Robertson-Walker (FLRW) model. The effective action
governing the model in the mini-superspace approximation is derived. We find
that the presence of black hole horizons in the bulk gives rise to a complex
action for certain classically allowed brane configurations, but that the
imaginary contribution plays no role in the equations of motion. Classical and
instanton brane trajectories are examined in general and for special cases, and
we find a subset of configuration space that is not allowed at the classical or
semi-classical level; these correspond to spacelike branes carrying tachyonic
matter. The Hamiltonization and Dirac quantization of the model is then
performed for the general case; the latter involves the manipulation of the
Hamiltonian constraint before it is transformed into an operator that
annihilates physical state vectors. The ensuing covariant Wheeler-DeWitt
equation is examined at the semi-classical level, and we consider the possible
localization of the brane universe's wavefunction away from the cosmological
singularity. This is easier to achieve for branes with low density and/or
spherical spatial sections.Comment: Shortened to match version accepted by Phys. Rev. D (unabridged text
found in version 2), 42 pages, 9 figures, Rextex
Weyl Semimetal in a Topological Insulator Multilayer
We propose a simple realization of the three-dimensional (3D) Weyl semimetal
phase, utilizing a multilayer structure, composed of identical thin films of a
magnetically-doped 3D topological insulator (TI), separated by
ordinary-insulator spacer layers. We show that the phase diagram of this system
contains a Weyl semimetal phase of the simplest possible kind, with only two
Dirac nodes of opposite chirality, separated in momentum space, in its
bandstructure. This particular type of Weyl semimetal has a finite anomalous
Hall conductivity, chiral edge states, and occurs as an intermediate phase
between an ordinary insulator and a 3D quantum anomalous Hall insulator with a
quantized Hall conductivity, equal to per TI layer. We find that the
Weyl semimetal has a nonzero DC conductivity at zero temperature and is thus an
unusual metallic phase, characterized by a finite anomalous Hall conductivity
and topologically-protected edge states.Comment: 4 pages, 3 figures, published versio
Position Measurements Obeying Momentum Conservation
We present a hitherto unknown fundamental limitation to a basic measurement:
that of the position of a quantum object when the total momentum of the object
and apparatus is conserved. This result extends the famous Wigner-Araki-Yanase
(WAY) theorem, and shows that accurate position measurements are only
practically feasible if there is a large momentum uncertainty in the apparatus
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