10,971 research outputs found
Coronal loop oscillations and diagnostics with Hinode/EIS
Context.Standing slow (acoustic) waves commonly observed in hot coronal loops offer a unique opportunity to understand the properties of the coronal plasma. The lack of evidence for similar oscillations in cooler loops is still a puzzle.
Aims.The high cadence EIS instrument on board recently launched Hinode has the capability to detect wave motion in EUV lines both in the imaging and spectroscopy modes. The paper aims to establish the distinct characteristics of standing and propagating acoustic waves and to predict their footprints in EIS data.
Methods.A 1D hydrodynamic loop model is used and the consequences of various types of heating pulses are examined. In each case, the resulting hydrodynamic evolution of the loop is converted into observables using a selection of available EIS spectral lines and windows.
Results.Propagating/standing acoustic waves are a natural response of the loop plasma to impulsive heating. Synthetic EIS observations of such waves are presented both in the imaging and spectroscopy modes. The waves are best seen and identified in spectroscopy mode observations. It is shown that the intensity oscillations, unlike the Doppler shift oscillations, continuously suffer phase shifts due to heating and cooling of the plasma. It is therefore important to beware of this effect when interpreting the nature of the observed waves
Gendered poverties and power relations: looking inside communities and households.
The study focuses on four communities in Nicaragua including one that was constructed to house those displaced by Hurricane Mitch. The aim of the study was to better understand how women and men experience poverty. It considers poverty within wider notions of well being and also works within a vulnerability framework to consider how women use different assets to respond to crisis situations and the utility of these. It demonstrates that while income poverty and low consumption are immediate concerns, issues such as insecurity and violence are also of great concern to the women interviewed. This includes the concern over localised and re-current disasters, such as drought, and continued insecurity in the face of a larger scale event. The study notes how little advancement has been made in disaster mitigation since Mitch and how this can influence the well being of communities. The study also highlights that reducing one type of vulnerability may increase another, noting a trade -off between reducing physical vulnerability to hazards and increasing social and economic vulnerability. Language: English and Spanish
Sex disaggregation alone will not energize equality
The need to include gender in energy policy, practice and research is largely accepted. However, when research that merely disaggregates by sex is used to inform energy efficiency initiatives, it often reproduces stereotypical understandings of sex differences, which can harm rather than promote gender equality
Extractivism and the engendering of disasters: disaster risk creation in the era of the Anthropocene
This paper argues that extractivist logic creates the environmental conditions that produce ‘natural’ hazards and also the human conditions that produce vulnerability, which combined create disasters. Disaster Risk Creation is then built into the current global socio-economic system, as an integral component not accidental by-product.
As part of the movement to liberate disasters as discipline, practice and field of enquiry, this paper does not talk disasters per se, but rather its focus is on ‘extractivism’ as a fundamental explanator for the anthropogenic disaster landscape that now confronts us.
Applying a gender lens to extractivism as it relates to disaster, further highlights that Disaster Risk Management rather than alleviating, creates the problems it seeks to solve, suggesting the need to liberate gender from Disaster Risk Management, and the need to liberate us all from the notion of managing disasters. Since to ‘manage’ disaster risk is to accept uncritically the structures and systems that create that risk, then if we truly want to address disasters, our focus needs to be on the extractive practices, not the disastrous outcomes.
The fundamental argument is that through privileging the notion of ‘disaster’ we create it, bring it into existence, as something that exists in and of itself, apart from wider socio-economic structures and systems of extraction and exploitation, rather than recognising it for what it is, an outcome/end product of those wider structures and systems. Our focus on disaster is then misplaced, and perhaps what disaster studies needs to be liberated from, is itself
All-optical control of molecular fluorescence
We present a quantum electrodynamical procedure to demonstrate the all-optical control of molecular fluorescence. The effect is achieved on passage of an off-resonant laser beam through an optically activated system; the presence of a surface is not required. Following the derivation and analysis of the all-optical control mechanism, calculations are given to quantify the significant modification of spontaneous fluorescent emission with input laser irradiance. Specific results are given for molecules whose electronic spectra are dominated by transitions between three electronic levels, and suitable laser experimental methods are proposed. It is also shown that the phenomenon is sensitive to the handedness of circularly polarized throughput, producing a conferred form of optical activity
Near-field manipulation of interparticle forces through resonant absorption, optical binding, and dispersion forces
The relative motions of two or more neutral particles, subject to optical trapping forces within a beam, are influenced by intrinsic inter-particle forces. The fundamental character of such forces is well-known and usually derives from dispersion interactions. However, the throughput of moderately intense (off-resonant) laser light can significantly modify the form and magnitude of these intrinsic forces. This optical binding effect is distinct from the optomechanical interactions involved in optical tweezers, and corresponds to a stimulated (pairwise) forward-scattering mechanism. In recent years, attention has begun to focus on optical binding effects at sub-micron and molecular dimensions. At this nanoscale, further manipulation of the interparticle forces is conceivable on the promotion of optically bound molecules to an electronic excited state. It is determined that such excitation may influence the intrinsic dispersion interaction without continued throughput of the laser beam, i.e. independent of any optical binding. Nevertheless, the forwardscattering mechanism is also affected by the initial excitation, so that both the optical binding and dispersion forces can be manipulated on input of the electromagnetic radiation. In addition, the rate of initial excitation of either molecule (or any energy transfer between them) may be influenced by an off-resonant input beam which, thus, acts as an additional actor in the modification of the interparticle force. A possible experimental set-up is proposed to enable the measurement of such changes in the interparticle coupling. © (2013) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE)
Engaging new dimensions in nonlinear optical spectroscopy using auxiliary beams of light
By applying a sufficiently intense beam of off-resonant light, simultaneously with a conventional excitation source beam, the efficiencies of one- and two-photon absorption processes may be significantly modified. The nonlinear mechanism that is responsible, known as laser modified absorption, is fully described by a quantum electrodynamical analysis. The origin of the process, which involves stimulated forward Rayleigh-scattering of the auxiliary beam, relates to higher order terms which are secured by a time-dependent perturbation treatment. These terms, usually inconsequential when a single beam of light is present, become prominent under the secondary optical stimulus – even with levels of intensity that are moderate by today’s standards. Distinctive kinds of behaviour may be observed for chromophores fixed in a static arrangement, or for solution- or gas-phase molecules whose response is tempered by a rotational average of orientations. In each case the results exhibit an interplay of factors involving the beam polarisations and the molecular electronic response. Special attention is given to interesting metastable states that are symmetry forbidden by one- or two-photon absorption. Such states may be accessible, and thus become populated, on input of the auxiliary beam. For example, in the one-photon absorption case, terms arise that are more usually associated with three-photon processes, corresponding to very different selection rules. Other kinds of metastable state also arise in the two-photon process, and measuring the effect of applying the stimulus beam to absorbances of such character adds a new dimension to the information content of the associated spectroscopy. Finally, based on these novel forms of optical nonlinearity, there may be new possibilities for quantum non-demolition measurements
Are Chromospheric Nanoflares a Primary Source of Coronal Plasma?
It has been suggested that the hot plasma of the solar corona comes primarily
from impulsive heating events, or nanoflares, that occur in the lower
atmosphere, either in the upper part of the ordinary chromosphere or at the
tips of type II spicules. We test this idea with a series of hydrodynamic
simulations. We find that synthetic Fe XII (195) and Fe XIV (274) line profiles
generated from the simulations disagree dramatically with actual observations.
The integrated line intensities are much too faint; the blue shifts are much
too fast; the blue-red asymmetries are much too large; and the emission is
confined to low altitudes. We conclude that chromospheric nanoflares are not a
primary source of hot coronal plasma. Such events may play an important role in
producing the chromosphere and powering its intense radiation, but they do not,
in general, raise the temperature of the plasma to coronal values. Those cases
where coronal temperatures are reached must be relatively uncommon. The
observed profiles of Fe XII and Fe XIV come primarily from plasma that is
heated in the corona itself, either by coronal nanoflares or a quasi-steady
coronal heating process. Chromospheric nanoflares might play a role in
generating waves that provide this coronal heating.Comment: 14 pages, 6 figures, accepted by Astrophysical Journa
Nonlinear energy pooling in nanophotonic materials
Recently there has been considerable interest in the construction of photoactive organic materials designed to exhibit novel forms of optical nonlinearity. By exploiting the unique properties of these nanomaterials at high levels of photon flux, new possibilities emerge for applications in energy harvesting, low-threshold lasing, quantum logic devices, photodynamic therapy, etc. In particular, a detailed appraisal of the theory spotlights novel mechanisms for directed energy transfer and energy pooling in nanophotonic dendrimers. Characterized by a nonlinear dependence on the optical irradiance, these mechanisms fall into two classes: (a) those where two-photon absorption by individual donors is followed by transfer of the sum energy to the acceptor; (b) where the excitation of two electronically distinct but neighbouring donor groups is followed by a collective migration of their energy to a suitable acceptor. In each case these transfer processes are subject to minor dissipative losses, associated with intramolecular vibrational relaxation in the donor species. In this paper we describe in detail the balance of factors and the constraints that determines the favored mechanism, which include the excitation statistics, structure of the energy levels, selection rules, molecular architecture, the distribution of donors and acceptors, spectral overlap and coherence factors. Knowledge of these factors and the means for their optimization offers fresh insights into nanophotonic characteristics, and informs strategies for the design of new photoactive materials
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