540 research outputs found
Geomorphological control on boulder transport and coastal erosion before, during and after an extreme extra-tropical cyclone
Extreme wave events in coastal zones are principal drivers of geomorphic change. Evidence of boulder entrainment and erosional impact during storms is increasing. However, there is currently poor time coupling between pre- and post-storm measurements of coastal boulder deposits. Importantly there are no data reporting shore platform erosion, boulder entrainment and/or boulder transport during storm events – rock coast dynamics during storm events are currently unexplored. Here, we use high-resolution (daily) field data to measure and characterise coastal boulder transport before, during and after the extreme Northeast Atlantic extra-tropical cyclone Johanna in March 2008. Forty-eight limestone fine-medium boulders (n = 46) and coarse cobbles (n = 2) were tracked daily over a 0.1 km2 intertidal area during this multi-day storm. Boulders were repeatedly entrained, transported and deposited, and in some cases broken down (n = 1) or quarried (n = 3), during the most intense days of the storm. Eighty-one percent (n = 39) of boulders were located at both the start and end of the storm. Of these, 92% were entrained where entrainment patterns were closely aligned to wave parameters. These data firmly demonstrate rock coasts are dynamic and vulnerable under storm conditions. No statistically significant relationship was found between boulder size (mass) and net transport distance. Graphical analyses suggest that boulder size limits the maximum longshore transport distance but that for the majority of boulders lying under this threshold, other factors influence transport distance. Paired analysis of 20 similar sized and shaped boulders in different morphogenic zones demonstrates that geomorphological control affects entrainment and transport distance – where net transport distances were up to 39 times less where geomorphological control was greatest. These results have important implications for understanding and for accurately measuring and modelling boulde
Mechanisms of Surviving Burial: Dune Grass Interspecific Differences Drive Resource Allocation After Sand Deposition
Sand dunes are important geomorphic formations of coastal ecosystems that are critical in protecting human populations that live in coastal areas. Dune formation is driven by ecomorphodynamic interactions between vegetation and sediment deposition. While there has been extensive research on responses of dune grasses to sand burial, there is a knowledge gap in understanding mechanisms of acclimation between similar, coexistent, dune-building grasses such as Ammophila breviligulata (C3), Spartina patens (C4), and Uniola paniculata (C4). Our goal was to determine how physiological mechanisms of acclimation to sand burial vary between species. We hypothesize that (1) in the presence of burial, resource allocation will be predicated on photosynthetic pathway and that we will be able to characterize the C3 species as a root allocator and the C4 species as leaf allocators. We also hypothesize that (2) despite similarities between these species in habitat, growth form, and life history, leaf, root, and whole plant traits will vary between species when burial is not present. Furthermore, when burial is present, the existing variability in physiological strategy will drive species-specific mechanisms of survival. In a greenhouse experiment, we exposed three dune grass species to different burial treatments: 0 cm (control) and a one-time 25-cm burial to mimic sediment deposition during a storm. At the conclusion of our study, we collected a suite of physiological and morphological functional traits. Results showed that Ammophila decreased allocation to aboveground biomass to maintain root biomass, preserving photosynthesis by allocating nitrogen (N) into light-exposed leaves. Conversely, Uniola and Spartina decreased allocation to belowground production to increase elongation and maintain aboveground biomass. Interestingly, we found that species were functionally distinct when burial was absent; however, all species became more similar when treated with burial. In the presence of burial, species utilized functional traits of rapid growth strategy, although mechanisms of change were interspecifically variable
Geomorphological control on boulder transport and coastal erosion before, during and after an extreme extra-tropical cyclone
This is the final version of the article. Available from Wiley via the DOI in this record.Extreme wave events in coastal zones are principal drivers of geomorphic change. Evidence of boulder entrainment and erosional impact during storms is increasing. However, there is currently poor time coupling between pre- and post-storm measurements of coastal boulder deposits. Importantly there are no data reporting shore platform erosion, boulder entrainment and/or boulder transport during storm events – rock coast dynamics during storm events are currently unexplored. Here, we use high-resolution (daily) field data to measure and characterize coastal boulder transport before, during and after the extreme Northeast Atlantic extra-tropical cyclone Johanna in March 2008. Forty-eight limestone fine-medium boulders (n = 46) and coarse cobbles (n = 2) were tracked daily over a 0.1 km2 intertidal area during this multi-day storm. Boulders were repeatedly entrained, transported and deposited, and in some cases broken down (n = 1) or quarried (n = 3), during the most intense days of the storm. Eighty-one percent (n = 39) of boulders were located at both the start and end of the storm. Of these, 92% were entrained where entrainment patterns were closely aligned to wave parameters. These data firmly demonstrate rock coasts are dynamic and vulnerable under storm conditions. No statistically significant relationship was found between boulder size (mass) and net transport distance. Graphical analyses suggest that boulder size limits the maximum longshore transport distance but that for the majority of boulders lying under this threshold, other factors influence transport distance. Paired analysis of 20 similar sized and shaped boulders in different morphogenic zones demonstrates that geomorphological control affects entrainment and transport distance – where net transport distances were up to 39 times less where geomorphological control was greatest. These results have important implications for understanding and for accurately measuring and modelling boulder entrainment and transport. Coastal managers require these data for assessing erosion risk.This paper benefitted from: comments from J.
Hansom, S. Etienne and anonymous reviewers; student volunteers at
Atlantic United World College; cartography from Sue Rouillard and
Mike Shand; funding from a Royal Geographical Society EPSRC small
grant and a NERC grant NE/M010546/1 (Dr Naylor) and an Australian
Research Council Discovery grant DP0557205 (Dr Stephenson);
permission from the Countryside Council for Wales
Spring Song
[Verse 1] In the gentle springtime when the birds and flowers, make love with you in natures fairest bowers Then you and I as in the days gone by will dream love’s dream while fleet the sunny hours. In dale or dell, in forests fair to see where tower the mountain heights in all their majesty, By ocean’s shore, or wooded grove, I’ll sigh to thee, I’ll sigh to thee of my true love. The worlds delight we two will prove Then come with me my love! Then come with me my own true love Then come with me my own true love In ecstasy Oh come with me!
[Verse 2] Hark! The winds are sighing and the nightingale, Is telling sweetest music in the enchanted dale, And see the golden moon dawns fair on high to glorify, And tell us love can never die. No! love can never die; For nature lives alone thro’ love, Then why not you and I? So lift our hearts to heaven above O come with me, My own true love! O come with me my own true love! In ecstasy my own true love In ecstasy O come with me! O come with me
A practice-related risk score (PRS): a DOPPS-derived aggregate quality index for haemodialysis facilities
Background. The Dialysis Outcomes and Practice Patterns Study (DOPPS) database was used to develop and validate a practice-related risk score (PRS) based on modifiable practices to help facilities assess potential areas for improving patient care.
Methods. Relative risks (RRs) from a multivariable Cox mortality model, based on observational haemodialysis (HD) patient data from DOPPS I (1996-2001, seven countries), were used. The four practices were the percent of patients with Kt/V >= 1.2, haemoglobin >= 11 g/dl (110 g/l), albumin >= 4.0 g/dl (40g/l) and catheter use, and were significantly related to mortality when modelled together. DOPPS II data (2002-2004, 12 countries) were used to evaluate the relationship between PRS and mortality risk using Cox regression.
Results. For facilities in DOPPS I and II, changes in PRS over time were significantly correlated with changes in the standardized mortality ratio (SMR). The PRS ranged from 1.0 to 2.1. Overall, the adjusted RR of death was 1.05 per 0.1 points higher PRS (P < 0.0001). For facilities in both DOPPS I and II (N = 119), a 0.2 decrease in PRS was associated with a 0.19 decrease in SMR (P = 0.005). On average, facilities that improved PRS practices showed significantly reduced mortality over the same time frame.
Conclusions. The PRS assesses modifiable HD practices that are linked to improved patient survival. Further refinements might lead to improvements in the PRS and will address regional variations in the PRS/mortality relationship
Correcting 100 years of misunderstanding: electric fields in superconductors, hole superconductivity, and the Meissner effect
From the outset of superconductivity research it was assumed that no
electrostatic fields could exist inside superconductors, and this assumption
was incorporated into conventional London electrodynamics. Yet the London
brothers themselves initially (in 1935) had proposed an electrodynamic theory
of superconductors that allowed for static electric fields in their interior,
which they unfortunately discarded a year later. I argue that the Meissner
effect in superconductors necessitates the existence of an electrostatic field
in their interior, originating in the expulsion of negative charge from the
interior to the surface when a metal becomes superconducting. The theory of
hole superconductivity predicts this physics, and associated with it a
macroscopic spin current in the ground state of superconductors ("Spin Meissner
effect"), qualitatively different from what is predicted by conventional
BCS-London theory. A new London-like electrodynamic description of
superconductors is proposed to describe this physics. Within this theory
superconductivity is driven by lowering of quantum kinetic energy, the fact
that the Coulomb repulsion strongly depends on the character of the charge
carriers, namely whether electron- or hole-like, and the spin-orbit
interaction. The electron-phonon interaction does not play a significant role,
yet the existence of an isotope effect in many superconductors is easily
understood. In the strong coupling regime the theory appears to favor local
charge inhomogeneity. The theory is proposed to apply to all superconducting
materials, from the elements to the high cuprates and pnictides, is
highly falsifiable, and explains a wide variety of experimental observations.Comment: Proceedings of the conference "Quantum phenomena in complex matter
2011 - Stripes 2011", Rome, 10 July -16 July 2011, to be published in J.
Supercond. Nov. Mag
Condensate and superfluid fractions for varying interactions and temperature
A system with Bose-Einstein condensate is considered in the frame of the
self-consistent mean-field approximation, which is conserving, gapless, and
applicable for arbitrary interaction strengths and temperatures. The main
attention is paid to the thorough analysis of the condensate and superfluid
fractions in a wide region of interaction strengths and for all temperatures
between zero and the critical point T_c. The normal and anomalous averages are
shown to be of the same order for almost all interactions and temperatures,
except the close vicinity of T_c. But even in the vicinity of the critical
temperature, the anomalous average cannot be neglected, since only in the
presence of the latter the phase transition at T_c becomes of second order, as
it should be. Increasing temperature influences the condensate and superfluid
fractions in a similar way, by diminishing them. But their behavior with
respect to the interaction strength is very different. For all temperatures,
the superfluid fraction is larger than the condensate fraction. These coincide
only at T_c or under zero interactions. For asymptotically strong interactions,
the condensate is almost completely depleted, even at low temperatures, while
the superfluid fraction can be close to one.Comment: Latex file, 22 pages, 5 figure
The nonlinear anomalous lattice elasticity associated with the high-pressure phase transition in spodumene: A high precission static compression study
The high-pressure behavior of the lattice elasticity of spodumene, LiAlSi2O6,
was studied by static compression in a diamond-anvil cell up to 9.3 GPa.
Investigations by means of single-crystal XRD and Raman spectroscopy within the
hydrostatic limits of the pressure medium focus on the pressure ranges around
similar to 3.2 and similar to 7.7 GPa, which have been reported previously to
comprise two independent structural phase transitions. While our measurements
confirm the well-established first-order C2/c-P2(1)/c transformation at 3.19
GPa (with 1.2% volume discontinuity and a hysteresis between 0.02 and 0.06
GPa), both unit-cell dimensions and the spectral changes observed in
high-pressure Raman spectra give no evidence for structural changes related to
a second phase transition. Monoclinic lattice parameters and unit-cell volumes
at in total 59 different pressure points have been used to re-calculate the
lattice-related properties of spontaneous strain, volume strain, and the bulk
moduli as a function of pressure across the transition. A modified Landau free
energy expansion in terms of a one component order parameter has been developed
and tested against these experimentally determined data. The Landau solution
provides a much better reproduction of the observed anomalies than any
equation-of-state fit to data sets truncated below and above P (tr), thus
giving Landau parameters of K (0) = 138.3(2) GPa, K' = 7.46(5), lambda (V) =
33.6(2) GPa, a = 0.486(3), b = -29.4(6) GPa and c = 551(11) GPa
Kinetic energy driven superconductivity and superfluidity
The theory of hole superconductivity proposes that superconductivity is
driven by lowering of quantum kinetic energy and is associated with expansion
of electronic orbits and expulsion of negative charge from the interior to the
surface of superconductors and beyond. This physics provides a dynamical
explanation of the Meissner effect. Here we propose that similar physics takes
place in superfluid helium 4. Experimental manifestations of this physics in
are the negative thermal expansion of below the point
and the "Onnes effect", the fact that superfluid helium will creep up the walls
of the container and escape to the exterior. The Onnes effect and the Meissner
effect are proposed to originate in macroscopic zero point rotational motion of
the superfluids. It is proposed that this physics indicates a fundamental
inadequacy of conventional quantum mechanics
Aggregation — Disaggregation Algorithms for Discrete Stochastic Systems
In this paper an aggregation — disaggregation method is formulated for a finite horizon Markov decision process with two-dimensional state and action spaces. This second dimension of the state and the action contains a similar type of information in which aggregation is both natural and simple. The quality of the approach is illustrated by an example
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