1,330 research outputs found

    Phenotypic Diversity as a Mechanism to Exit Cellular Dormancy

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    SummaryMicroorganisms can facilitate their survival in stressful environments by entering a state of metabolic inactivity or dormancy [1]. However, this state impairs the function of the very sensory systems necessary to detect favorable growth conditions. Thus, how can a metabolically quiescent cell accurately monitor environmental conditions in order to best decide when to exit dormancy? One strategy employed by microbes to deal with changing environments is the generation of phenotypes that may be less well adapted to a current condition but might confer an advantage in the future [2, 3]. This bet-hedging depends on phenotypic diversity in the population [4], which itself can derive from naturally occurring stochastic differences in gene expression [5, 6]. In the case of metabolic dormancy, a bet-hedging strategy that has been proposed is the “scout model” where cells comprising a fraction of the dormant population reinitiate growth stochastically, independent of environmental cues [7, 8]. Here, we provide experimental evidence that such a mechanism exists in dormant spores produced by the ubiquitous soil bacterium Bacillus subtilis. We observe that these spores reinitiate growth at a low but measureable frequency even in the absence of an inducing signal. This phenomenon is the result of phenotypic variation in the propensity of individual spores to reinitiate growth spontaneously. Since this bet-hedging mechanism produces individuals that will either grow under favorable conditions or die under unfavorable conditions, a population can properly respond to environmental changes despite the impaired sensory ability of individual cells

    Mechanics-based approaches for the flexural and shear behaviour of ultra-high performance fibre reinforced concrete beams

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    This thesis presents a series of journal articles outlining a mechanics-based analysis approach for the flexural and shear behaviour of ultra-high performance fibre reinforced concrete beams. These solutions apply the mechanical principles of partial interaction, shear friction and segmental analysis to the design of fibre reinforced concrete (FRC) and ultra-high performance fibre reinforced concrete (UHPFRC) beams. The analysis techniques are developed for both normal strength FRC and UHPFRC, which is important as these materials have in the past often treated separately, but should be treated together the mechanical principles do not change, rather only the material properties. Further, because of their mechanics foundation, these approaches can also be applied to conventional reinforced concrete without modification by simply ignoring all terms relating to fibre properties. In the first part of this thesis the bond, tension and shear friction properties of UHPFRC are obtained through material testing. A significant part of this research is the development of a new apparatus for determining the shear friction properties. The development of this apparatus is important as it allows for the precise control of the confining force applied to the shear plane and because tests can be conducted using standard cylinders, it allows for rapid, low-cost testing of the large number of samples required to understand the impact of different fibre types and volumes. In the second part of the thesis closed form mechanics solutions are developed for the tension stiffening properties including crack spacing and the crack opening stiffness. These are then used to develop closed form solutions for the deflections and crack widths at the serviceability limit state. Next, experimental work is conducted to investigate the impact of hybridising fibres by testing UHPFRC beams with varying cross sections and fibre types. This is followed by tests to investigate the impact of prestressing with either steel or fibre reinforced polymer (FRP) tendons. Having experimentally investigated this behaviour, a segmental analysis technique, is developed to predict deflections at all load levels and crack widths. Finally, closed-form solutions are developed for predicting moment redistribution behaviour of continuous reinforced concrete beams including those constructed of UHPFRC at all limit states. Having investigated flexural performance at both the serviceability and ultimate limit state, a numerical and analytical approach which is mechanically consistent with the proposed flexural analysis is developed to predict member shear capacity. The solutions are validated against 31 tests, including two conducted by the author on UHPFRC I-sections in order to demonstrate accuracy compared to codified solutions and those available from the literature. Simplified solutions are then developed in a form which can be implemented in routine design. In the final section of this thesis further applications of partial interaction theory are developed. In this section closed-form solutions are derived for FRP to substrate joints with and without anchors. In this section it is shown that the same theory used to analyse conventional, FRC and UHPFRC reinforcement can also be applied, without fundamental modification to predict the behaviour of FRP retrofitted sections.Thesis (Ph.D.) -- University of Adelaide, School of Civil, Environmental & Mining Engineering, 202

    Satellite data reveal differential responses of Swiss forests to unprecedented 2018 drought

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    Extreme events such as the summer drought of 2018 in Central Europe are projected to occur more frequently in the future and may cause major damages including increased tree mortality and negative impacts on forest ecosystem services. Here, we quantify the response of >1 million forest pixels of 10 × 10 m across Switzerland to the 2018 drought in terms of resistance, recovery, and resilience. We used the Normalized Difference Water Index (NDWI) derived from Sentinel-2 satellite data as a proxy for canopy water content and analyzed its relative change. We calculated NDWI change between the 2017 pre-drought and 2018 drought years (indicating resistance), 2018 and the 2019 post-drought (indicating recovery), and between 2017–2019 (indicating resilience). Analyzing the data from this large natural experiment, we found that for 4.3% of the Swiss forest the NDWI declined between 2017 and 2018, indicating areas with low resistance of the forest canopy to drought effects. While roughly 50% of this area recovered, in 2.7% of the forested area NDWI continued to decline from 2018 to 2019, suggesting prolonged negative effects or delayed damage. We found differential forest responses to drought associated with site topographic characteristics and forest stand characteristics, and to a lesser extent with climatic conditions and interactions between these drivers. Low drought resistance and high recovery were most prominent at forest edges, but also on south-facing slopes and lower elevations. Tree functional type was the most important driver of drought resilience, with most of the damage in stands with high conifer abundance. Our results demonstrate the suitability of satellite-based quantification of drought-induced forest damage at high spatial resolution across large areas. Such information is important to predict how local site characteristics may impact forest vulnerability to future extreme events and help in the search for appropriate adaptation strategies

    Graphite Composite Booms with Integral Hinges

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    A document discusses lightweight instrument booms under development for use aboard spacecraft. A boom of this type comprises a thin-walled graphite fiber/ matrix composite tube with an integral hinge that can be bent for stowage and later allowed to spring back to straighten the boom for deployment in outer space. The boom design takes advantage of both the stiffness of the composite in tubular geometry and the flexibility of thin sections of the composite. The hinge is formed by machining windows in the tube at diametrically opposite locations so that there remain two opposing cylindrical strips resembling measuring tapes. Essential to the design is a proprietary composite layup that renders the hinge tough yet flexible enough to be bendable as much as 90 in either of two opposite directions. When the boom is released for deployment, the torque exerted by the bent hinge suffices to overcome parasitic resistance from harnesses and other equipment, so that the two sections of the hinge snap to a straight, rigid condition in the same manner as that of measuring tapes. Issues addressed in development thus far include selection of materials, out-of-plane bending, edge cracking, and separation of plies

    ViMA -- the spinning rotor gauge to measure the viscosity of tritium between 77 and 300 K

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    Experimental values for the viscosity of the radioactive hydrogen isotope tritium (T2_2) are currently unavailable in literature. The value of this material property over a wide temperature range is of interest for applications in the field of fusion, neutrino physics, as well as to test ab initio calculations. As a radioactive gas, tritium requires careful experiment design to ensure safe and environmental contamination free measurements. In this contribution, we present a spinning rotor gauge based, tritium compatible design of a gas viscosity measurement apparatus (ViMA) capable of covering the temperature range from 80 K to 300 K.Comment: 11 pages, 3 figures, Tritium Conference 202

    Towards the first direct measurement of the dynamic viscosity of gaseous tritium at cryogenic temperatures

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    Accurate values for the viscosity of the radioactive hydrogen isotope tritium (T) at cryogenic temperatures are unavailable. Values for tritium found in literature are based on extrapolation by mass ratios as well as an empirical factor derived from hydrogen (H) and deuterium (D ) viscosity measurements, or classical kinetic theory which does not handle quantum effects. Accurate data of the tritium viscosity will help to improve the modelling of the viscosity of diatomic molecules and can be used as a test of their interaction potentials. With this contribution we report a major step towards a fully tritium and cryogenic temperature compatible setup for the accurate measurement of the viscosity of gases, using a spinning rotor gauge (SRG) at the Tritium Laboratory Karlsruhe. After calibration with helium, measurements with hydrogen and deuterium conducted at room temperature agree with literature values within 2%. The performance at liquid nitrogen (LN ) temperature has been successfully demonstrated with a second setup in a liquid nitrogen bath. Again after calibration with helium at LN temperature, the viscosities of H and D were determined and are in agreement with literature to about 2%

    Soil H218O labelling reveals the effect of drought on C18OO fluxes to the atmosphere

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    Concurrent and continuous measurements of the 18O/16O ratio in CO2 and H2Ov after a H2 18O labelling showed that drought reduces the 18O-equilibrium between CO2 and H2O at the shoot leve

    Viscosity measurements of gaseous H2 between 200 K to 300 K with a spinning rotor gauge

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    Experimental values for the viscosity of the radioactive hydrogen isotopologue tritium are still unknown in literature. Existing values from ab initio calculations disregard quantum mechanic effects and are therefore only good approximations for room temperature and above. To fill in these missing experimental values, a measurement setup has been designed, to measure the viscosity of gaseous hydrogen and its isotopologues (H2_2, HD, HT, D2_2, DT, T2_2) at cryogenic temperatures. In this paper, the first results with this Cryogenic Viscosity Measurement Apparatus (Cryo-ViMA) of the viscosity of gaseous hydrogen between 200 K to 300 K are presented.Comment: 9 pages, 2 figures, 22nd International Vacuum Congress, submitted to e-Journal of Surface Science and Nanotechnolog

    Release of Hydrogen from Nanoconfined Hydrides by Application of Microwaves

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    The release of hydrogen from solid hydrides by thermolysis can be improved by nanoconfinement of the hydride in a suitable micro/mesoporous support, but the slow heat transfer by conduction through the support can be a limitation. In this work, a C/SiO2 mesoporous material has been synthesized and employed as matrix for nanoconfinement of hydrides. The matrix showed high surface area and pore volume (386 m²/g and 1.41 cm³/g), which enabled the confinement of high concentrations of hydride. Furthermore, by modification of the proportion between C and SiO2, the dielectric properties of the complex could be modified, making it susceptible to microwave heating. As with this heating method the entire sample is heated simultaneously, the heat transfer resistances associated to conduction were eliminated. To demonstrate this possibility, ethane 1,2-diaminoborane (EDAB) was embedded on the C/SiO2 matrix at concentrations ranging from 11 to 31%wt using a wet impregnation method, and a device appropriate for hydrogen release from this material by application of microwaves was designed with the aid of a numerical simulation. Hydrogen liberation tests by conventional heating and microwaves were compared, showing that by microwave heating hydrogen release can be initiated and stopped in shorter times.2019-04-0
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