Water Quality Variability in a Bioswell and Concrete Drainage Pipe, Southwest Lincoln, Nebraska

Abstract The goal of this project is to evaluate the effectiveness of bioswells in protecting water quality from urban runoff. The hypothesis tested in this project is that water in bioswells improves water quality. Water quality in both a bioswell and an underground concrete lined ditch, both containing ground and surface water, were tested for certain water quality parameters. These parameters consisted of: Dissolved Oxygen, pH, water temperature, weather temperature, Total Dissolved Solids, Specific Conductivity, Alkalinity, Total Dissolved Carbon, Chemical Oxygen Demand, and depth and width of the sampling site. An additional contaminant that was looked at was motor oil. This was measured by comparing Total Organic Carbon with Chemical Oxygen Demand. A variety of different methods to measure the water quality parameters were utilized. The concrete site had more stable readings, but much higher water temperatures. However, the bioswell water is mainly from surface water runoff, and the underground concrete lined pipe is from underground water, so the two cannot be directly compared. The bioswell had high readings, especially pertaining to Oxygen Demand, Total Organic Carbon, and Specific Conductivity in early test dates. But, these readings improved as they were filtered though the bioswell. As plant activity increased and the weather began to warm up there were more stable readings. It is concluded that bioswells are an effective way to reduce problems associated with urban runoff pertaining to certain water quality parameters.

Formation of an extended CoSi2 thin nanohexagons array coherently buried in silicon single crystal

A Co-doped silica film was deposited on the surface of a Si(100) wafer and isothermally annealed at 750 degrees C to form spherical Co nanoparticles embedded in the silica film and a few atomic layer thick CoSi2 nanoplatelets within the wafer. The structure, morphology, and spatial orientation of the nanoplatelets were characterized. The experimental results indicate that the nanoplatelets exhibit hexagonal shape and a uniform thickness. The CoSi2 nanostructures lattice is coherent with the Si lattice, and each of them is parallel to one of the four planes belonging to the {111} crystallographic form of the host lattice. (C) 2012 American Institute of Physics. [doi:10.1063/1.3683493]

In-plane mapping of buried InGaAs quantum rings and hybridization effects on the electronic structure

This work reports the investigation on the structural differences between InAs quantum rings and their precursor quantum dots species as well as on the presence of piezoelectric fields and asymmetries in these nanostructures. The experimental results show significant reduction in the ring dimensions when the sizes of capped and uncapped ring and dot samples are compared. The iso-lattice parameter mapped by grazing-incidence x-ray diffraction has revealed the lateral extent of strained regions in the buried rings. A comparison between strain and composition of dot and ring structures allows inferring on how the ring formation and its final configuration may affect optical response parameters. Based on the experimental observations, a discussion has been introduced on the effective potential profile to emulate theoretically the ring-shape confinement. The effects of confinement and strain field modulation on electron and hole band structures are simulated by a multiband k.p calculation. (C) 2012 American Institute of Physics. [http://dx.doi.org/10.1063/1.4733964]

Water-assisted Flow of Heavy Oil in a Vertical Pipe: Pilot-scale Experiments

The use of the core-annular flow pattern, where a thin fluid surrounds a very viscous one, has been suggested as an attractive artificial-lift method for heavy oils in the current Brazilian ultra-deepwater production scenario. This paper reports the pressure drop measurements and the core-annular flow observed in a 2 7/8-inch and 300 meter deep pilot-scale well conveying a mixture of heavy crude oil (2000 mPa.s and 950 kg/m3 at 35 C) and water at several combinations of the individual flow rates. The two-phase pressure drop data are compared with those of single-phase oil flow to assess the gains due to water injection. Another issue is the handling of the core-annular flow once it has been established. High-frequency pressure-gradient signals were collected and a treatment based on the Gabor transform together with neural networks is proposed as a promising solution for monitoring and control. The preliminary results are encouraging. The pilot-scale tests, including long-term experiments, were conducted in order to investigate the applicability of using water to transport heavy oils in actual wells. It represents an important step towards the full scale application of the proposed artificial-lift technology. The registered improvements in terms of oil production rate and pressure drop reductions are remarkable.

Macroscopic and microbiological alterations of bird and small mammal bones buried in a Cerrado biome (south western Brazil)

In this paper, we present the results of an experimental approach developed to study the macroscopic and microbiological alteration of bird and small mammal bones buried under a Cerrado biome. The first experiment evaluated the macroscopic alteration of cooked and fresh carcasses buried through the dry and rainy seasons. The second experiment analyzed the mycobiota associated to the decomposition of a complete bird that remained buried for almost a year. Results show that in tropical forest environments: 1) bone structure and pre-taphonomic factors determine its differential alteration by biochemical processes; 2) fungal populations associated to the decomposition of animal remains depend on soil chemistry and ecological dynamics; 3) even in a corrosive environment, bird bones are more capable of surviving to several mycological decomposition steps. (C) 2011 Elsevier Ltd. All rights reserved.

Geometrical and kinematic properties of interfacial waves in stratified oil-water flow in inclined pipe

The stratified oil-water flow pattern is common in the petroleum industry, especially in offshore directional wells and pipelines. Previous studies have shown that the phenomenon of flow pattern transition in stratified flow can be related to the interfacial wave structure (problem of hydrodynamic instability). The study of the wavy stratified flow pattern requires the characterization of the interfacial wave properties, i.e., average shape, celerity and geometric properties (amplitude and wavelength) as a function of holdup, inclination angle and phases' relative velocity. However, the data available in the literature on wavy stratified flow is scanty, especially in inclined pipes and when oil is viscous. This paper presents new geometric and kinematic interfacial wave properties as a function of a proposed two-phase Froude number in the wavy-stratified liquid-liquid flow. The experimental work was conducted in a glass test line of 12 m and 0.026 m id., oil (density and viscosity of 828 kg/m(3) and 0.3 Pa s at 20 degrees C, respectively) and water as the working fluids at several inclinations from horizontal (-20 degrees, -10 degrees, 0 degrees, 10 degrees, 20 degrees). The results suggest a physical relation between wave shape and the hydrodynamic stability of the stratified liquid-liquid flow pattern. (C) 2011 Elsevier Inc. All rights reserved.

Drag reduction phenomenon in viscous oil-water dispersed pipe flow: Experimental investigation and phenomenological modeling

An experimental study on drag-reduction phenomenon in dispersed oil-water flow has been performed in a 26-mm-i.d. Twelve meter long horizontal glass pipe. The flow was characterized using a novel wire-mesh sensor based on capacitance measurements and high-speed video recording. New two-phase pressure gradient, volume fraction, and phase distribution data have been used in the analysis. Drag reduction and slip ratio were detected at oil volume fractions between 10 and 45% and high mixture Reynolds numbers, and with water as the dominant phase. Phase-fraction distribution diagrams and cross-sectional imaging of the flow suggested the presence of a higher amount of water near to the pipe wall. Based on that, a phenomenology for explaining drag reduction in dispersed flow in a flow situation where slip ratio is significant is proposed. A simple phenomenological model is developed and the agreement between model predictions and data, including data from the literature, is encouraging. (c) 2011 American Institute of Chemical Engineers AIChE J, 2012

On soil-structurae interaction in large non-slender partially buried structures.

[EN]This paper addresses the seismic analysis of a deeply embedded non-slender structure hosting the pumping unit of a reservoir. The dynamic response in this type of problems is usually studied under the assumption of a perfectly rigid structure using a sub-structuring procedure (three-step solution) proposed specifically for this hypothesis.

Detection of small buried objects: asymptotic factorization and MUSIC

In this work, we consider a simple model problem for the electromagnetic exploration of small perfectly conducting objects buried within the lower halfspace of an unbounded two–layered background medium. In possible applications, such as, e.g., humanitarian demining, the two layers would correspond to air and soil. Moving a set of electric devices parallel to the surface of ground to generate a time–harmonic field, the induced field is measured within the same devices. The goal is to retrieve information about buried scatterers from these data. In mathematical terms, we are concerned with the analysis and numerical solution of the inverse scattering problem to reconstruct the number and the positions of a collection of finitely many small perfectly conducting scatterers buried within the lower halfspace of an unbounded two–layered background medium from near field measurements of time–harmonic electromagnetic waves. For this purpose, we first study the corresponding direct scattering problem in detail and derive an asymptotic expansion of the scattered field as the size of the scatterers tends to zero. Then, we use this expansion to justify a noniterative MUSIC–type reconstruction method for the solution of the inverse scattering problem. We propose a numerical implementation of this reconstruction method and provide a series of numerical experiments.

A sampling method for detecting buried objects using electromagnetic scattering

We consider a simple (but fully three-dimensional) mathematical model for the electromagnetic exploration of buried, perfect electrically conducting objects within the soil underground. Moving an electric device parallel to the ground at constant height in order to generate a magnetic field, we measure the induced magnetic field within the device, and factor the underlying mathematics into a product of three operations which correspond to the primary excitation, some kind of reflection on the surface of the buried object(s) and the corresponding secondary excitation, respectively. Using this factorization we are able to give a justification of the so-called sampling method from inverse scattering theory for this particular set-up.

Formulazione e messa a punto di una metodologia per il progetto di ventilatori per gallerie del vento con applicazione al "long-pipe" del laboratorio CICLoPE : analisi attraverso l'impiego di modelli matematici in MATLAB

Nell'ottica di un futuro riprogetto, totale o parziale, del ventilatore della galleria del vento del progetto CICLoPE dell'Università di Bologna, è stato messo a punto, grazie a modelli matematici di letteratura, un algoritmo per la determinazione della geometria delle pale di un fan. La procedura si basa su ipotesi di incompressibilità e assenza di vortici di estremità ed è in grado di fornire la geometria del ventilatore una volta che sono state fissate: le condizioni richieste nella sezione di test, l'efficienza del tunnel e alcune proprietà del ventilatore stesso (ad esempio tipologia di profilo aerodinamico e numero di pale). L'algoritmo è in grado di lavorare solamente con la configurazione ventilatore seguito da profili raddrizzatori, ma è in previsione un'estensione che consentirà di studiare anche la configurazione a fan controrotanti (come quella del CICLoPE). Con questo software sono state progettate numerose soluzioni diverse per studiare il legame tra rendimento e geometria del ventilatore. Inoltre sono stati individuati i parametri che permettono di ottenere una pala con rastremazione e svergolatura trascurabili, con lo scopo di abbassare i costi del manufatto. In particolare è stato dimostrato come le configurazioni con diametro della nacelle grande (superiore al 65\% del diametro della sezione di potenza) siano particolarmente adatte a fornire rendimenti alti con la minima complicatezza della pala. Per quanto riguarda l'efficienza aerodinamica del profilo, i test comparativi indicano che questo parametro influisce relativamente poco sul rendimento del macchinario ma modifica profondamente la geometria della pala. Efficienze elevate tendono, secondo lo studio, a richiedere pale estremamente rastremate e poco svergolate; questo porta a preferire l'adozione di profili mediamente efficienti ma dall'ampio intervallo operativo in termini di angolo di attacco.

Analisi sperimentale di un sistema per il posizionamento e la movimentazione di sensori in galleria del vento, con applicazione al "long-pipe" in CICLoPE

Analisi di un sistema per il posizionamento e la movimentazione di sensori in galleria del vento. In particolare l’analisi è stata focalizzata sul sistema di movimentazione sonde (traversing) presente nel long-pipe in CICLoPE (Center for International Cooperation in Long Pipe Experiments). La struttura menzionata nasce per far fronte ad alcuni dei limiti presenti negli attuali laboratori fluidodinamici per lo studio della turbolenza ad alti numeri di Reynolds. Uno degli obiettivi del centro è quello di caratterizzare le più piccole strutture caratteristiche della turbolenza. Al fine di permettere tale studio era necessario migliorare il traversing esistente per ottenere movimenti ad alta precisione, in modo da raggiungere lo stesso ordine di grandezza delle scale più piccole della turbolenza. Il miglioramento di tale strumentazione è stato necessario anche per fornire un valido supporto alle metodologie esistenti per la determinazione della distanza tra sonde e parete, che resta una delle difficoltà nello studio della turbolenza di parete. L’analisi del traversing, svolta attraverso più test, ha fatto emergere problemi sia nella struttura del sistema, sia nel software che gestisce il motore per la movimentazione. La riprogrammazione del software e la rettifica di alcuni componenti del sistema hanno permesso di eliminare gli errori emersi. Le piccole imprecisioni restanti durante la movimentazione, non eliminabili con un’implementazione software, verranno totalmente superate grazie all’impiego del nuovo motore dotato di un encoder rotativo che sarà in grado di retroazionare il sistema, fornendo il reale spostamento effettuato.

Anemometria a filo caldo: studio di un sistema di calibrazione per sonde a due fili con applicazione al "long pipe" in CICLoPE

L’anemometro a filo caldo (in inglese hot wire) é lo strumento maggiormente usato per studiare sperimentalmente la turbolenza. A seconda di quante componenti della velocitá interessa studiare, esistono anemometri a uno, due o tre fili. Questo elaborato di tesi si concentra su sonde a due fili. Per prima cosa, ogni volta che si utilizza questo strumento bisogna effettuare una calibrazione, fase molto importante perché permette di relazionare le tensioni che ogni filo acquisisce con la velocitá reale del flusso. Sono presentati tre differenti metodi utilizzati per sonde a due fili e, dopo averli analizzati, sono stati applicati a dati acquisiti prima al CAT (Coaxial Aerodinamic Tunnel), struttura presente a Forlí, nell’hangar dell’Universitá di Bologna e poi al CICLoPE (Center for International Cooperation in Long Pipe Experiments), Long-Pipe costruito a Predappio, utilizzato per lo studio della turbolenza. La calibrazione per sonde a due fili si puó dividere in due parti, quella di velocitá e quella per gli angoli. Mentre al CAT é possibile effettuarle entrambi, al CICLoPE non é attualmente possibile eseguire la calibrazione angolare perché non esiste alcuno strumento utilizzabile per regolare la sonda all’angolo desiderato. Lo scopo di questo elaborato di tesi è trovare un metodo di calibrazione per sonde a due fili applicabile al CICLoPE eseguendo sul posto solamente una calibrazione di velocitá e adattando quella angolare effettuata precedentemente al CAT. Questo puó provocare dei problemi perché la calibrazione risulta fortemente dipendente da condizioni interne dei fili, come la resistenza, ma anche da condizioni al contorno, come la temperatura e la pressione dell’ambiente esterno. Dopo aver eseguito due campagne sperimentali di test, una al CAT e una al CICLoPE, i dati acquisiti sono stati elaborati per valutare l’efficacia dei vari metodi.