2,277 research outputs found
Photonic monitoring of atmospheric fauna
Insects play a quintessential role in the Earth’s ecosystems and their recent decline in abundance and diversity is alarming. Monitoring their population is paramount to understand the causes of their decline, as well as to guide and evaluate the efficiency of conservation policies. Monitoring populations of flying insects is generally done using physical traps, but this method requires long and expensive laboratory analysis where each insect must be identified by qualified personnel. Lack of reliable data on insect populations is now considered a significant issue in the field of entomology, often referred to as a “data crisis” in the field. This doctoral work explores the potential of entomological photonic sensors to unlock some of the limitations of traditional methods. This work focuses on the development of optical instruments similar in essence to lidar systems, with the goal of counting and identifying flying insects from a distance in their natural habitat. Those systems rely on the interactions between the near-infrared laser light and insects flying through the laser beam. Each insect is characterized by retrieving its optical and morphological properties, such as wingbeat frequency, optical cross sections, or depolarization ratios. This project ran in parallel a series of laboratory and field experiments. In the laboratory, prototypes were tested and used to create a database of insects’ properties. The data were used to train machine learning classifiers aiming at identifying insects from optical signals. In the case of mosquitoes, the sex and species of an unknown specimen was predicted with a 99% and 80% accuracy respectively. It also showed that the presence of eggs within the abdomen of a female mosquito could be detected from several meters away with 87% accuracy. In the field, instruments were deployed in real-world conditions for a total of 520 days over three years. More than a million insects were observed, allowing to continuously monitor their aerial density over months with a temporal resolution down to the minute. While this approach remains very new, this work demonstrated that photonic sensors could become a powerful tool to tackle the current lack of data in the field of entomology
Why vocal production of atypical sounds in apes and its cerebral correlates have a lot to say about the origin of language
Ackermann et al. mentioned the "acquisition of species-atypical sounds" in apes without any discussions. In our commentary, we demonstrate that these atypical sounds in chimpanzees not only include laryngeal sounds but also have a major significance regarding the origins of language, if we consider looking at their context of use, their social properties, their relations with gestures, their lateralization and their neurofunctional correlates as well
No toilet at home: implementation, usage and acceptability of shared toilets in urban Ghana
In Ghana, over 70% of urban dwellers do not have private sanitation facilities in their home and rely instead on an informal network of shared toilets. The predominance of shared toilets in Ghana is the result of unplanned urbanization, specific features of housing, socio-economic characteristics of the population and political orientations.
Shared sanitation includes a whole range of models from large toilets blocks owned by the municipality to toilet cubicles shared by tenants of the same house. Shared toilets are not considered as improved sanitation facilities as access for vulnerable groups, maintenance, hygiene, privacy and safety of the users are not always guaranteed. However, for millions of urban dwellers, shared toilets are the only alternative to open defecation and are used daily. Some of these facilities, through better management models and through better standards, provide services appreciated by the users.
The aim of this research is to determine which models of shared facilities are acceptable sanitation solutions for urban dwellers, depending on the local circumstances. To do so, the research framework compares the perspectives of dwellers and sanitation providers, acknowledges the characteristics of the specific urban context and considers the relationships between the key stakeholders. In a fast growing city in Ghana, Ashaiman, 432 house units representing over 8000 residents were surveyed, over 40 participatory exercises and 38 interviews with a range of stakeholders were conducted.
This research concludes on four main points. Firstly, many apparently similar areas are actually not uniform; the heterogeneity of urban planning and housing influences any past and future sanitation developments. Urban planners need to integrate sanitation in their future decisions but base these on appropriate solutions. The second finding is that some models of shared sanitation can be considered as adequate given the particular context and its likely evolution. The different models have legitimacy at different stages of urban development and their successful selection depends on the quality of the contextual understanding. Thirdly, cleanliness and affordability are key determinants when the dwellers select shared toilets. Given the toilet options available, these determinants are often mutually exclusive and are a dilemma for the users. This dilemmas result in variations in use of shared toilets within a neighbourhood, and at intra household and individual levels. The final point is that choice and then acceptability of a facility depends on the options available. Therefore deciding which facilities are best adapted to the local context should be in the hands of both local providers and dwellers, supported by other local stakeholders who enable relationships through adapted policies and facilitated dialogues
Buoyancy-driven exchange flows in inclined ducts
Buoyancy-driven exchange flows arise in the natural and built environment
wherever bodies of fluids at different densities are connected by a narrow
constriction. In this paper we study these flows in the laboratory using the
canonical stratified inclined duct experiment, which sustains an exchange flow
in an inclined duct of rectangular cross-section over long time periods (Meyer
& Linden, J. Fluid Mech., vol. 753, 2014). We study the behaviour of these
sustained stratified shear flows by focusing on three dependent variables of
particular interest: the qualitative flow regime (laminar, wavy, intermittently
turbulent, or fully turbulent), the mass flux (net transport of buoyancy
between reservoirs), and the interfacial thickness (thickness of the layer of
intermediate density between the two counter-flowing layers). Dimensional
analysis reveals five non-dimensional independent input parameters: the duct
aspect ratios in the longitudinal direction and spanwise direction , the
tilt angle , the Reynolds number (based on the initial buoyancy
difference driving the flow), and the Prandtl number (we consider both
salt and temperature stratifications). After reviewing the literature and open
questions on the scaling of regimes, mass flux, and interfacial thickness with
, we present the first extensive, unified set of experimental
data where we varied systematically all five input parameters and measured all
three output variables with the same methodology. Our results in the
plane for five sets of reveal a variety of scaling
laws, and a non-trivial dependence of all three variables on all five
parameters, in addition to a sixth elusive parameter. We further develop three
classes of candidate models to explain the observed scaling laws: ..
Large second harmonic generation enhancement in SiN waveguides by all-optically induced quasi phase matching
Integrated waveguides exhibiting efficient second-order nonlinearities are
crucial to obtain compact and low power optical signal processing devices.
Silicon nitride (SiN) has shown second harmonic generation (SHG) capabilities
in resonant structures and single-pass devices leveraging intermodal phase
matching, which is defined by waveguide design. Lithium niobate allows
compensating for the phase mismatch using periodically poled waveguides,
however the latter are not reconfigurable and remain difficult to integrate
with SiN or silicon (Si) circuits. Here we show the all-optical enhancement of
SHG in SiN waveguides by more than 30 dB. We demonstrate that a Watt-level
laser causes a periodic modification of the waveguide second-order
susceptibility. The resulting second order nonlinear grating has a periodicity
allowing for quasi phase matching (QPM) between the pump and SH mode. Moreover,
changing the pump wavelength or polarization updates the period, relaxing phase
matching constraints imposed by the waveguide geometry. We show that the
grating is long term inscribed in the waveguides, and we estimate a second
order nonlinearity of the order of 0.3 pm/V, while a maximum conversion
efficiency (CE) of 1.8x10-6 W-1 cm-2 is reached
An Agenda for the Obama Administration on Gender Equality: Lessons from Abroad
President Barack Obama came into office with a wealth of good will after winning the historic 2008 presidential election to become the first African-American commander-in-chief. Among the many daunting issues we hope he will tackle is one that Abigail Adams mentioned to her husband John in 1776: remember the ladies. How should our President and his new administration affect social justice for women
Traffic jams and intermittent flows in microfluidic networks
We investigate both experimentally and theoretically the traffic of particles
flowing in microfluidic obstacle networks. We show that the traffic dynamics is
a non-linear process: the particle current does not scale with the particle
density even in the dilute limit where no particle collision occurs. We
demonstrate that this non-linear behavior stems from long range hydrodynamic
interactions. Importantly, we also establish that there exists a maximal
current above which no stationary particle flow can be sustained. For higher
current values, intermittent traffic jams form thereby inducing the ejection of
the particles from the initial path and the subsequent invasion of the network.
Eventually, we put our findings in the broader context of the transport
proccesses of driven particles in low dimension
Exogenous application of platelet-leukocyte gel during open subacromial decompression contributes to improved patient outcome
Background: Platelet-leukocyte gel (PLG) is being used during various surgical procedures in an attempt to enhance the healing process. We studied the effects of PLG on postoperative recovery of patients undergoing open subacromial decompression (OSD). Methods: PLG was produced from platelet-leukocyte-rich plasma (P-LRP), prepared from a unit of whole blood. Forty patients were included in the study. Self-assessed evaluations, using the American Shoulder and Elbow Surgeons scoring system of activities of daily living (ADL), joint instability, pain levels, pain medications, and clinical evaluations for range of motion were conducted. Results: Platelet and leukocyte counts were significantly increased in the P-LRP compared to baseline counts. Treated patients demonstrated decreased visual analog scales for pain and used significantly less pain medication, had an improved range of motion during passive forward elevation, external rotation, external rotation with arm at 90 degrees abduction, internal rotation, and cross body adduction compared to control patients (p < 0.001). No differences in the instability score were observed between the groups. Furthermore, treated patients performed more ADL (p < 0.05). Conclusion: In the PLG-treated group, recovery was faster and patients returned earlier to daily activities and also took less pain medication than control subjects
Non-volatile spin wave majority gate at the nanoscale
A spin wave majority fork-like structure with feature size of 40\,nm, is
presented and investigated, through micromagnetic simulations. The structure
consists of three merging out-of-plane magnetization spin wave buses and four
magneto-electric cells serving as three inputs and an output. The information
of the logic signals is encoded in the phase of the transmitted spin waves and
subsequently stored as direction of magnetization of the magneto-electric cells
upon detection. The minimum dimensions of the structure that produce an
operational majority gate are identified. For all input combinations, the
detection scheme employed manages to capture the majority phase result of the
spin wave interference and ignore all reflection effects induced by the
geometry of the structure
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