The Application of time domain reflectometry in solute transport experiments

Yu, Chunming,1957-

January 1998

Contaminants can enter groundwater through the unsaturated zone as dissolved solutes. To predict the location and extent of these contaminants, transport parameters such as pore water velocity y and dispersion coefficient D are required. These parameters are often obtained through transport experiments. The goal of this study is to determine y and D using time domain reflectometry (TDR) technique. Using TDR for transport experiments under unsaturated conditions, we investigated the effects of volumetric water content θᵥ, distance of flow path, and draining-wetting history on D. TDR was used to measure θᵥ, and salt concentration in twenty-one unsaturated column experiments. The 105 cm-long column was homogeneously packed with silica sand (particle size: 53 to 425 pm). Ten TDR probes at ten depths were used to obtain in situ breakthrough curves and a chloride electrode was used to measure effluent breakthrough curves at the bottom of the column. A 35 mM NaC1 (sodium chloride) was used as the tracer with 20 mM NaC1 as background solution. We developed a three-parameter expression relating θᵥ, to measured dielectric constant Kₐ: θᵥ =aKₐᵅ + b. This calibration expression fits as closely or better than the "universal polynomial" and is also consistent with the well-known mixing model. For an isotropic soil with homogeneous water distribution, this expression is further simplified to two parameters by taking α = 0.5. The effects of temperature, porosity, soil solid and bound water can be taken into account by varying a and b of the two-parameter expression. TDR measurements have been shown to be sensitive to bound water and not particular sensitive to the other factors. To calculate y and D from breakthrough curves of step-input experiments, a new moment analysis method has been developed. The transport parameters obtained from this new method show a little difference from the parameters determined from the convection-dispersion equation using the CXTFIT model (a published computer program for estimating solute transport parameters from observed breakthrough curves). Our results demonstrated that D is dependent on measurement methods and concentrations of experimental solutions.

Hydrology.

Soils -- Solute movement.

Time-domain reflectometry.

Water and solute transport : modeling and application to water conservation in layered soil

Mohammed, Fareed H. A. N.

23 July 1992

Sandy soils are among the least productive soils because of their inability to store adequate water for plant growth. Their high percolation rate not only allows water to move quickly beyond the root zone, but also washes nutrients below the reach of plant roots. High evaporation occurs from the soil surface. Many acres of these soils around the world are left out of crop production. This study is a contribution to bring these soils into production by increasing their ability to hold more water in the root zone. Several promising methods of enhancing these soils were simulated, surface mulch, buried barrier layer, and a combination of both. The effects of varying texture and thickness of these layers and varying evaporative demand were investigated. The impact of such modifications on solute distribution in the soil was also simulated. A simulation model of water and solute transport in layered soils was developed for this purpose. The Richards equation for one-dimensional water transport in unsaturated soils was modified to account for the water jump between the layers. The solute transport equation was also modified by implementing the same theory of water infiltration in layered soil to the solute convective transport. The Crank-Nicolson scheme was used to solve the transport equations with the help of the Newton-Raphson iteration method. The results of the simulation show that the proposed methods increase water content in the sandy soil by up to 45%. The combination of barriers, which decreases leaching and evaporation was the most effective in conserving water. Most of the contribution came from the influence of the mulch layer in suppressing water losses by evaporation. The combination method traps solute in the root zone, and this decreased solute leaching from the soil may limit plant growth in saline soils. / Graduation date: 1993

Sandy soils

Soils -- Solute movement

Soil percolation

Soil moisture conservation

Transport mechanisms for radon-222 in soils : a case study for Delaware County

Puck, Brent D.

January 1993

Radon transport mechanisms in soils were studied to determine the dominant transport mechanism for Delaware county soils. In modeling the soil, it was assumed that is was homogenous and moisture-free. Two transport mechanisms were investigated, the transport of radon in the soil by molecular diffusion (assumed to be governed by Fick's law) and transport by pressure-induced flow or convection (assumed to be governed by Darcy's law). Following the previous work of W. E. Clements, a general transport equation was described which incorporated both diffusion and convection. In steady-state conditions, a closed-form solution was obtained for the concentration of radon in the soil interstices as a function of depth. Similarly, solutions were examined for transport by diffusion alone. Representative soil parameters were assigned and the diffusion fraction (the ratio of concentration due to diffusion to the concentration due to both diffusion and convection) was calculated. Referring to the work of A. B. Tanner, a radon availability number (RAN) was determined for the soils; the RAN value was a measure of the activity of radon per unit area. Analyses were also performed to determine the significance of pressure variations on calculated diffusion fractions and RAN values. For 99% of the acreage in Delaware county, the diffusion fraction was 0.95 or greater. Therefore, it was concluded that molecular diffusion is the dominant transport mechanism for the soils of Delaware county. / Department of Physics and Astronomy

Radon -- Diffusion rates.

Radioisotopes in soil chemistry.

Soils -- Solute movement.

The mobility of malathion in a silt loam soil as affected by phosphate and naturally occuring organic acids

Kurtz, Frederick C.

17 January 2009

A laboratory study of the mobility of Malathion in the soil environment was conducted. / Master of Science

LD5655.V855 1992.K877

Loam soils -- Solute movement

Malathion

Phosphates

Soils -- Absorption and adsorption

Deslocamento de solutos provenientes de água residuária em colunas de solo. / Solutes displacement in the wastewater in the soils columns.

SANTOS, Joelma Sales dos.

12 September 2018

Submitted by Johnny Rodrigues (johnnyrodrigues@ufcg.edu.br) on 2018-09-12T14:36:34Z No. of bitstreams: 1 JOELMA SALES DOS SANTOS - DISSERTAÇÃO PPGEA 2008..pdf: 2148772 bytes, checksum: df2be91fa70bfec779b2da346fa4693c (MD5) / Made available in DSpace on 2018-09-12T14:36:34Z (GMT). No. of bitstreams: 1 JOELMA SALES DOS SANTOS - DISSERTAÇÃO PPGEA 2008..pdf: 2148772 bytes, checksum: df2be91fa70bfec779b2da346fa4693c (MD5) Previous issue date: 2008-02 / Capes / Com o objetivo de avaliar os parâmetros de transporte fator de retardamento, coeficiente de dispersão-difusão e curva de efluente dos íons cálcio, magnésio, sódio, potássio e da condutividade elétrica presentes nas águas residuárias de origem de doméstica tratada e de suinocultura realizou-se um experimento em laboratório com colunas de solos Argissolo Vermelho-Amarelo Eutrófico e Neossolo Regolítico Eutrófico. Através de frascos de Mariotte passou-se cerca de dois volumes de água destilada nas colunas e, em seguida, interligou-se outro frasco contendo as águas residuárias que lixiviou 3,75 volume de poros divididos em 25 alíquotas. Os efluentes obtidos das colunas foram encaminhados ao laboratório e com os valores das concentrações relativas foram construídas as curvas de distribuição de efluentes para os solutos cálcio, magnésio, sódio e potássio. Os parâmetros de transportes foram calculados através modelo computacional DISP (Programa para cálculo dos parâmetros de transporte de solutos no solo em deslocamento de fluidos miscíveis). Os resultados obtidos permitiram concluir que os fatores de retardamento foram mais altos para o sódio no solo Argissolo Vermelho-Amarelo Eutrófico e para o íon magnésio no Neossolo Regolítico Eutrófico lixiviados com água residuária doméstica tratada. Para a água residuária de suinocultura os maiores valores foram calculados para o íon magnésio nos dois solos. Em relação aos coeficientes de dispersão-difusão verificou-se que os maiores valores foram observados para o Neossolo Regolítico Eutrófico independe do tipo de água. De modo geral o maior aporte de nutrientes foi detectado nos solos Argissolo Vermelho-Amarelo Eutrófico e Neossolo Regolítico Eutrófico após ser lixiviado com as águas residuárias doméstica tratada e de suinocultura.

Engenharia Agrícola.

Deslocamento de solutos

Águas residuárias

Colunas de solo

Movimento de solutos

Água residuária doméstica

Tratamento de águas residuárias

Dinâmica de solutos no solo

Argisolo vermelho-amarelo eutrófico

Neosolo Regolítico Eutrófico

Fator de retardamento

Coeficiente de dispersão-difusão

Solute movement

Retardation factor

Wastewater

Dispersive-diffusive coefficient