Thermodynamic Aspects of Precipitation Efficiency

A method for determination of Cr, Fe, Co, Ni, Cu, Zn, Hg and Pb in waters by Energy Dispersive X Ray Fluorescence (EDXRF) was implemented, using a radioisotopic source of 238Pu. For previous concentration was employed a procedure including a coprecipitation step with ammonium pyrrolidinedithiocarbamate (APDC) as quelant agent, the separation of the phases by filtration, the measurement of filter by EDXRF and quantification by a thin layer absolute method. Sensitivity curves for K and L lines were obtained respectively. The sensitivity for most elements was greater by an order of magnitude in the case of measurement with a source of 238Pu instead of 109Cd, which means a considerable decrease in measurement times. The influence of the concentration in the precipitation efficiency was evaluated for each element. In all cases the recoveries are close to 100%, for this reason it can be affirmed that the method of determination of the studied elements is quantitative. Metrological parameters of the method such as trueness, precision, detection limit and uncertainty were calculated. A procedure to calculate the uncertainty of the method was elaborated; the most significant source of uncertainty for the thin layer EDXRF method is associated with the determination of instrumental sensitivities. The error associated with the determination, expressed as expanded uncertainty (in %), varied from 15.4% for low element concentrations (2.5-5 μg/L) to 5.4% for the higher concentration range (20-25 μg/L).

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Differences in precipitation efficiency and their probable mechanisms between the warm sector and cold front stages of a heavy rainfall event over Beijing

Atmospheric Science Letters ◽

10.1002/asl.802 ◽

2018 ◽

Vol 19 (4) ◽

pp. e802 ◽

Cited By ~ 3

Author(s):

Jiahua Mao ◽

Fan Ping ◽

Xiaofan Li ◽

Lei Yin

Keyword(s):

Heavy Rainfall ◽

Cold Front ◽

Rainfall Event ◽

Heavy Rainfall Event ◽

Precipitation Efficiency ◽

Warm Sector

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Simulation of the aerosol effect on the microphysical properties of shallow stratocumulus clouds over East Asia using a bin-based meso-scale cloud model

Atmospheric Chemistry and Physics Discussions ◽

10.5194/acpd-10-23449-2010 ◽

2010 ◽

Vol 10 (10) ◽

pp. 23449-23495 ◽

Cited By ~ 2

Author(s):

I.-J. Choi ◽

T. Iguchi ◽

S.-W. Kim ◽

S.-C. Yoon ◽

T. Nakajima

Keyword(s):

East Asia ◽

Liquid Water ◽

Cloud Model ◽

Atmospheric Condition ◽

Meteorological Condition ◽

Sensitivity Factor ◽

Target Area ◽

Precipitation Efficiency ◽

Microphysical Properties ◽

Meso Scale

Abstract. A bin-based meso-scale cloud model has been employed to explore the aerosol influence on the cloud microphysical properties and precipitation efficiency of shallow stratocumulus in East Asia in March 2005. We newly constructed aerosol size distributions and hygroscopicity parameters for five aerosol species that reproduced observed aerosol and cloud condensation nuclei (CCN) number concentrations in the target period, and thereby used in model simulation of the cloud microphysical properties and precipitation efficiency. It is found that the simulated results were satisfactorily close to the satellite-based observation. Significant effects of aerosols as well as of the meteorological condition were found in the simulated cloud properties and precipitation as confirmed by comparing maritime and polluted aerosol cases and by a sensitivity test with interchanging the aerosol conditions for two cases. Cloud droplets in the polluted condition tended to exhibit relatively narrower cloud drop spectral widths with a bias toward smaller droplet sizes than those in maritime condition, supporting the dispersion effect. The polluted aerosol condition also had a tendency of thinner and higher cloud layers than maritime aerosol condition under relatively humid meteorological condition, possibly due to enhanced updraft. In our cases, vertical structures of cloud droplet number and size were affected predominantly by the change in aerosol conditions, whereas in the structures of liquid water content and cloud fraction were influenced by both meteorological and aerosol conditions. Aerosol change made little differences in cloud liquid water, vertical cloud structure, and updraft/downdraft velocities between the maritime and polluted conditions under dry atmospheric condition. Quantitative evaluations of the sensitivity factor between aerosol and cloud parameters revealed a large sensitivity values in the target area compared to the previously reported values, indicating the strong aerosol-cloud interaction.

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Reply to “Comments on ‘Incorporating the Effects of Moisture into a Dynamical Parameter: Moist Vorticity and Moist Divergence’”

Weather and Forecasting ◽

10.1175/waf-d-16-0111.1 ◽

2016 ◽

Vol 31 (4) ◽

pp. 1397-1405

Author(s):

Weihong Qian ◽

Ning Jiang ◽

Jun Du

Keyword(s):

Large Scale ◽

Value Added ◽

Heavy Rain ◽

Heavy Precipitation ◽

Small Scale ◽

Precipitation Efficiency ◽

Long Duration ◽

Advection Term ◽

Rain Events ◽

Mathematical Derivation

Abstract Mathematical derivation, meteorological justification, and comparison to model direct precipitation forecasts are the three main concerns recently raised by Schultz and Spengler about moist divergence (MD) and moist vorticity (MV), which were introduced in earlier work by Qian et al. That previous work demonstrated that MD (MV) can in principle be derived mathematically with a value-added empirical modification. MD (MV) has a solid meteorological basis. It combines ascent motion and high moisture: the two elements necessary for rainfall. However, precipitation efficiency is not considered in MD (MV). Given the omission of an advection term in the mathematical derivation and the lack of precipitation efficiency, MD (MV) might be suitable mainly for heavy rain events with large areal coverage and long duration caused by large-scale quasi-stationary weather systems, but not for local intense heavy rain events caused by small-scale convection. In addition, MD (MV) is not capable of describing precipitation intensity. MD (MV) worked reasonably well in predicting heavy rain locations from short to medium ranges as compared with the ECMWF model precipitation forecasts. MD (MV) was generally worse than (though sometimes similar to) the model heavy rain forecast at shorter ranges (about a week) but became comparable or even better at longer ranges (around 10 days). It should be reiterated that MD (MV) is not intended to be a primary tool for predicting heavy rain areas, especially in the short range, but is a useful parameter for calibrating model heavy precipitation forecasts, as stated in the original paper.

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Recycling of water treatment sludges in municipal wastewater treatment plants – a practical example

Water Practice & Technology ◽

10.2166/wpt.2008.007 ◽

2008 ◽

Vol 3 (1) ◽

Author(s):

K. Klinksieg ◽

T. Dockhorn ◽

N. Dichtl

Keyword(s):

Wastewater Treatment ◽

Water Treatment ◽

Wastewater Treatment Plant ◽

Iron Hydroxide ◽

Settling Tank ◽

Treatment Plant ◽

Full Scale ◽

Aeration Tank ◽

Second Phase ◽

Precipitation Efficiency

Full-scale and lab-scale research experiments were conducted to determine the phosphorous precipitation efficiency of iron hydroxide sludge from drinking water treatment. During full-scale investigations at a wastewater treatment plant, ferric sludge was added to the inflow of the primary settling tank in a first experimental phase and to the inflow of the aeration tank in a second phase. In the outflow of the mechanical stage and in the outflow of the biological stage, a reduction of the PO4-P concentrations could be observed. The concentration of COD, the SVI and the filament abundance were not changed significantly by adding the ferric sludge to the wastewater treatment plant. In lab tests, improved precipitation efficiency of the ferric sludge could be achieved by using anaerobic conditions and acid pulping. The research showed that the wastewater treatment process can benefit from the reuse of ferric sludge from drinking waterworks and that this also presents an inexpensive recycling option for these sludges.

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Enhanced Monovalent Cation Biomineralization Ability by Quartz Sand for Effective Removal of Soluble Iron in Simulated Acid Mine Drainage

Water ◽

10.3390/w12030732 ◽

2020 ◽

Vol 12 (3) ◽

pp. 732

Author(s):

Heru Wang ◽

Mengying Li ◽

Yongwei Song

Keyword(s):

Heavy Metals ◽

Acid Mine Drainage ◽

Removal Efficiency ◽

Quartz Sand ◽

Mine Drainage ◽

Monovalent Cation ◽

Iron Minerals ◽

Precipitation Efficiency ◽

Acid Mine ◽

Effective Removal

Acid mine drainage (AMD) is characterized by low pH, high soluble Fe, and heavy metal concentrations. Conventional lime neutralization produces large amounts of Fe(OH)2 and Fe(OH)3, which complicate subsequent disposal. Secondary iron minerals synthesized by biomineralization can reduce the concentration of soluble Fe in addition to adsorbing and removing heavy metals in AMD. Therefore, an appropriate method for improving the precipitation efficiency of Fe is urgently needed for AMD treatment. Using simulated AMD, this work analyzes the influence of quartz sand (40 g/L) on the Fe2+ oxidation and total Fe deposition efficiencies, as well as the phases of secondary iron minerals in an Acidithiobacillus ferrooxidans system including K+, Na+, or NH4+ (53.3 mmol/L). Quartz sand had no significant effect on Fe2+ oxidation and 160 mmol/L Fe2+ was completely oxidized by A. ferrooxidans in 168 h, but contributed to the oxidized product (Fe3+) mineralization, improving the total Fe removal efficiency in simulated AMD. Compared with treatments involving K+ or Na+ alone, quartz sand improved the total Fe precipitation efficiency by 26.6% or 30.2%, respectively. X-ray diffraction showed that quartz sand can promote the transformation of the biomineralization pathway from schwertmannite to jarosite with higher yields, which is important for improving the removal efficiency of heavy metals in AMD.

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Precipitation efficiency derived from isotope ratios in water vapor distinguishes dynamical and microphysical influences on subtropical atmospheric constituents

Journal of Geophysical Research Atmospheres ◽

10.1002/2015jd023403 ◽

2015 ◽

Vol 120 (18) ◽

pp. 9119-9137 ◽

Cited By ~ 16

Author(s):

A. Bailey ◽

J. Nusbaumer ◽

D. Noone

Keyword(s):

Water Vapor ◽

Isotope Ratios ◽

Precipitation Efficiency

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Lagrangian Investigation of the Precipitation Efficiency of Convective Clouds

Journal of the Atmospheric Sciences ◽

10.1175/jas-d-14-0159.1 ◽

2015 ◽

Vol 72 (3) ◽

pp. 1045-1062 ◽

Cited By ~ 15

Author(s):

Wolfgang Langhans ◽

Kyongmin Yeo ◽

David M. Romps

Keyword(s):

Large Eddy Simulations ◽

Cloud Base ◽

Water Molecules ◽

Lagrangian Particle ◽

Surface Precipitation ◽

Convective Clouds ◽

Precipitation Efficiency ◽

Surface Rainfall ◽

Large Eddy ◽

Cumulus Congestus

Abstract The precipitation efficiency of cumulus congestus clouds is investigated with a new Lagrangian particle framework for large-eddy simulations. The framework is designed to track particles representative of individual water molecules. A Monte Carlo approach facilitates the transition of particles between the different water classes (e.g., vapor, rain, or graupel). With this framework, it is possible to reconstruct the pathways of water as it moves from vapor at a particular altitude to rain at the surface. By tracking water molecules through both physical and microphysical space, the precipitation efficiency can be studied in detail as a function of height. Large-eddy simulations of individual cumulus congestus clouds show that the clouds convert entrained vapor to surface precipitation with an efficiency of around 10%. About two-thirds of all vapor that enters the cloud does so by entrainment in the free troposphere, but free-tropospheric vapor accounts for only one-third to one-half of the surface rainfall, with the remaining surface rainfall originating as vapor entrained through the cloud base. The smaller efficiency with which that laterally entrained water is converted into surface precipitation results from the smaller efficiencies with which it condenses, forms precipitating hydrometeors, and reaches the surface.

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An Investigation of the Connections among Convection, Clouds, and Climate Sensitivity in a Global Climate Model

Journal of Climate ◽

10.1175/jcli-d-13-00145.1 ◽

2014 ◽

Vol 27 (5) ◽

pp. 1845-1862 ◽

Cited By ~ 56

Author(s):

Ming Zhao

Keyword(s):

Climate Sensitivity ◽

Radiative Forcing ◽

Climate Model ◽

Global Climate ◽

Global Climate Model ◽

Convective Precipitation ◽

Entrainment Rate ◽

Cloud Radiative Forcing ◽

Precipitation Efficiency ◽

Perturbed Physics

Abstract This study explores connections between process-level modeling of convection and global climate model (GCM) simulated clouds and cloud feedback to global warming through a set of perturbed-physics and perturbed sea surface temperature experiments. A bulk diagnostic approach is constructed, and a set of variables is derived and demonstrated to be useful in understanding the simulated relationship. In particular, a novel bulk quantity, the convective precipitation efficiency or equivalently the convective detrainment efficiency, is proposed as a simple measure of the aggregated properties of parameterized convection important to the GCM simulated clouds. As the convective precipitation efficiency increases in the perturbed-physics experiments, both liquid and ice water path decrease, with low and middle cloud fractions diminishing at a faster rate than high cloud fractions. This asymmetry results in a large sensitivity of top-of-atmosphere net cloud radiative forcing to changes in convective precipitation efficiency in this limited set of models. For global warming experiments, intermodel variations in the response of cloud condensate, low cloud fraction, and total cloud radiative forcing are well explained by model variations in response to total precipitation (or detrainment) efficiency. Despite significant variability, all of the perturbed-physics models produce a sizable increase in precipitation efficiency to warming. A substantial fraction of the increase is due to its convective component, which depends on the parameterization of cumulus mixing and convective microphysical processes. The increase in convective precipitation efficiency and associated change in convective cloud height distribution owing to warming explains the increased cloud feedback and climate sensitivity in recently developed Geophysical Fluid Dynamics Laboratory GCMs. The results imply that a cumulus scheme using fractional removal of condensate for precipitation and inverse calculation of the entrainment rate tends to produce a lower climate sensitivity than a scheme using threshold removal for precipitation and the entrainment rate formulated inversely dependent on convective depth.

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The Kinematic and Microphysical Characteristics and Associated Precipitation Efficiency of Subtropical Convection during SoWMEX/TiMREX

Monthly Weather Review ◽

10.1175/mwr-d-14-00081.1 ◽

2015 ◽

Vol 143 (1) ◽

pp. 317-340 ◽

Cited By ~ 20

Author(s):

Wei-Yu Chang ◽

Wen-Chau Lee ◽

Yu-Chieng Liou

Keyword(s):

Water Content ◽

Liquid Water ◽

Wind Shear ◽

Vertical Wind Shear ◽

Vertical Wind ◽

Convective Precipitation ◽

Squall Line ◽

Convective System ◽

Low Level ◽

Precipitation Efficiency

Abstract Dual-Doppler, polarimetric radar observations and precipitation efficiency (PE) calculations are used to analyze subtropical heavy rainfall events that occurred in southern Taiwan from 14 to 17 June 2008 during the Southwest Monsoon Experiment/Terrain-Influenced Monsoon Rainfall Experiment (SoWMEX/TiMREX) field campaign. Two different periods of distinct precipitation systems with diverse kinematic and microphysical characteristics were investigated: 1) prefrontal squall line (PFSL) and 2) southwesterly monsoon mesoscale convective system (SWMCS). The PFSL was accompanied by a low-level front-to-rear inflow and pronounced vertical wind shear. In contrast, the SWMCS had a low-level southwesterly rear-to-front flow with a uniform vertical wind field. The PFSL (SWMCS) contained high (low) lightning frequency associated with strong (moderate) updrafts and intense graupel–rain/graupel–small hail mixing (more snow and less graupel water content) above the freezing level. It is postulated that the reduced vertical wind shear and enhanced accretional growth of rain by high liquid water content at low levels in the SWMCS helped produce rainfall more efficiently (53.1%). On the contrary, the deeper convection of the PFSL had lower PE (45.0%) associated with the evaporative loss of rain and the upstream transport of liquid water to form larger stratiform regions. By studying these two events, the dependence of PE on the environmental and microphysical factors of subtropical heavy precipitation systems are investigated by observational data for the first time. Overall, the PE of the convective precipitation region (47.9%) from 14 to 17 June is similar to past studies of convective precipitation in tropical regions.

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