Abstracts
A field methodology is presented for the measurement of the soil hydraulic conductivity in a sloping field, minimizing the leveling soil movement before water pounding and redistribution. The assurance of vertical flow only is performed through soil water potential isolines. The hydraulic conductivity was determined by the instantaneous profile method. Results for the nine neutron probe access tubes indicate that one single K(theta) relation is sufficient to represent the experimental site.
hydraulic conductivity; slope; neutron probe
É apresentada, aqui, uma metodologia de campo para a determinação da condutividade hidráulica de um solo em declive, minimizando o corte de terra para posterior inundação e redistribuição da água. A garantia da ocorrência de fluxo de água apenas na vertical, é feita através de isolinhas de potencial da água. A condutividade hidráulica foi determinada pelo método do perfil instantâneo e os resultados para os nove tubos de acesso de sonda de nêutrons indicaram que uma única relação K(teta) é suficiente para representar a parcela.
condutividade hidráulica; declive; sonda de nêutrons
NOTAS PRÉVIAS
Soil hydraulic conductivily measurement on a sloping field1 1 Research funded by FAPESP and CNPq
Determinação da condutividade hidráulica em área com declive
Luís Carlos TimmI; Julio Cesar Martins de OliveiraII; Tânia Toyomi TominagaI; Fábio Augusto Meira CássaroI; Klaus ReichardtI,III ; Osny Oliveira Santos BacchiI
ILaboratório de Física do Solo, CENA/USP, CP 96, CEP 13400 - 970, Piracicaba, SP. Fone: (0xx19) 429 4713, Fax: (0xx19) 429 4610. E-mail: lctimm@carpa.ciagri.usp.br
IIDepartamento de Física e Química, EEP, CP 226, CEP 13414 - 040, Piracicaba, SP. Fone: (0xx19) 421 4982
IIIDepartamento de Ciências Exatas, ESALQ/USP, CP 9, CEP 13418 - 970, Piracicaba, SP. Fone: (0xx19) 429 4714, Fax: (0xx19) 429 4610. E-mail: klaus@cena.usp.br
ABSTRACT
A field methodology is presented for the measurement of the soil hydraulic conductivity in a sloping field, minimizing the leveling soil movement before water pounding and redistribution. The assurance of vertical flow only is performed through soil water potential isolines. The hydraulic conductivity was determined by the instantaneous profile method. Results for the nine neutron probe access tubes indicate that one single K(q) relation is sufficient to represent the experimental site.
Key words: hydraulic conductivity, slope, neutron probe
RESUMO
É apresentada, aqui, uma metodologia de campo para a determinação da condutividade hidráulica de um solo em declive, minimizando o corte de terra para posterior inundação e redistribuição da água. A garantia da ocorrência de fluxo de água apenas na vertical, é feita através de isolinhas de potencial da água. A condutividade hidráulica foi determinada pelo método do perfil instantâneo e os resultados para os nove tubos de acesso de sonda de nêutrons indicaram que uma única relação K(q) é suficiente para representar a parcela.
Palavras-chave: condutividade hidráulica, declive, sonda de nêutrons
INTRODUCTION
Among the methodologies used for soil hydraulic conductivity determination in the field, those employed with most success are based in internal drainage experiments. Some of the earliest contributions are those of Youngs (1964), La Rue et al. (1968) and Davidson et al. (1969). At a later stage, these methods were presented more formally (Hillel et al., 1972) or in a simplified form (Libardi et al., 1980) and Sisson et al. (1980), and in the last two decades used extensively to evaluate field soil hydraulic conductivity functions. One experimental shortcoming of these methodologies is the necessity of leveling the area in order to allow a homogeneous ponding with a water depth of 0.02 to 0.05 m, until steady-state infiltration is reached. Depending on the slope of the field and on the size of the flooded area, a significant soil cut has to be performed to level the area, removing topsoil from the upper part and adding soil to the lower part. Soil surface layer, which in many cases controls the process, is severely disturbed. This experiment is a trial that intends to minimize the problems listed above, and presents a hydraulic conductivity determination in a sloping area, leveling the soil in steps, with concomitant pounding. It is shown that no lateral water flow was present during water infiltration.
MATERIAL AND METHODS
A field of "Terra Roxa Estruturada" (Rhodic Kandiudox) of 7.4% slope, located in Piracicaba, SP, Brazil, was levelled in three steps (Figure 1A and B) in order to flood a 4.2 x 4.2 m plot. Nine access tubes for neutron probe soil water content q (m3 m-3) measurements (depths 0.2; 0.4; 0.6; 0.8 and 1.0 m) were numbered as follows: 1.1; 1.2; 1.3 (step 1); 2.1; 2.2; 2.3 (step 2) and 3.1; 3.2; 3.3 (step 3) and six tensiometer sets for soil water matric potential h (m H2O) (depths 0.3; 0.45; 0.60; 0.75; 0.9; 1.0 and 1.1 m) labelled as: 1a; 1b (step1); 2a; 2b (step 2); and 3a; 3b (step 3). Total soil water potential H = h + z values, where z stands for the gravimetric soil water potential (m H2O), were calculated in relation to step 1, for which z (m) was assumed to be zero. At steady-state infiltration, saturated soil hydraulic conductivity Ko (mm day-1) was measured using plastic cylinders of 0.3 m diameter. After this, flooding was terminated, plots were covered with a plastic sheet to avoid soil water evaporation and rainfall. Redistribution of water was monitored for two weeks, making measurements of q (z,t) and h (z,t). This data was analyzed in order to establish soil hydraulic conductivity K(q) functions using the simplified methodology of Libardi et al. (1980).
RESULTS AND DISCUSSION
Since the main difference between this experiment and all others based on soil pounding followed by internal drainage is the slope of the land, which was levelled in three steps, an analysis of the H(z) profiles was made in order to verify if there was lateral water flow. Figure 1C shows H(z) isolines at the end of the infiltration process, which indicate that the water flow occurred mainly in the vertical direction and that the Libardi et al. (1980) procedure could be applied without restriction. Hydraulic conductivity K(q) data are presented in Table 1, referring to the parameters Ko, g and qo of the exponential model used by Libardi et al. (1980):
where:
q - is the soil water content (m3 m-3)
qo - its saturated value
Ko - the saturated soil hydraulic conductivity (mm day-1)
g - a regression parameter.
Data of Table 1 are first presented individually for each of the nine neutron probe access tubes, followed by a mean, standard deviation (SD) and coefficient of variation (CV). Ko data of ring infiltrometers are 106 times larger than those calculated from the intercept of the q versus ln t plots. This fact is well discussed by Reichardt et al. (1998), which show that Ko and qo can be seen as fitting parameters, and therefore, an infinite set of Ko/qo pairs can be used to describe the same K(q) relation. Since infiltrometer Ko data represent direct measurements, they should be used in K(q) equations of type (1). The saturated soil water content qo values shown in the last column of Table 1 are the neutron probe measurements performed at the end of the infiltration process.
Coefficients of variation of Ko values are the highest, suggesting that it is prohibitive to use average values. For g values they are smaller but still very high. Values of qo present a very low CV, indicating an apparent soil homogeneity. It must be recognized that qo is part of the exponent of Eq. (1) and that very small changes in qo will imply in very large changes of K.
Table 1 also presents average data for each levelled step. These values were compared statistically using ANOVA and no significant difference was found for the mean values of Ko, g and qo for steps 1, 2 and 3. This suggests that the high CV values found for the nine locations discussed above are acceptable. Since no difference was found, an overall average was calculated, yielding the last line of Table 1. Therefore, the mean hydraulic conductivity of the field, can be written as:
(2)
CONCLUSION
This study shows that the water flow during the redistribution occurred mainly in the vertical direction and that the Libardi et al. (1980) procedure, in this case, could be applied without restrictions.
Recebido em 16/05/2000, Protocolo 054/00
- DAVIDSON, J.M.; STONE, L.R.; NIELSEN, D.R.; LA RUE, M.E. Field measurement and use of soil water properties. Water Resources Research, Washington (DC), v.5, p.1312-1321, 1969.
- HILLEL, D.; KRENTOS, V.D.; STYLIANAU, Y. Procedure and test of an internal drainage method for measuring soil hydraulic characteristics in situ. Soil Science, Baltimore, v.114, p.395-400, 1972.
- LA RUE, M.E.; NIELSEN, D.R.; HAGAN, R.M. Soil water flux below a ryegrass root zone. Agronomy Journal, Madison, v.60, p.625-629, 1968.
- LIBARDI, P.L.; REICHARDT, K.; NIELSEN, D.R.; BIGGAR, J.W. Simple field methods for estimating the unsaturated hydraulic conductivity. Soil Science Society America Journal, Madison, v.44, p.3-7, 1980.
- REICHARDT, K.; PORTEZAN, O.; LIBARDI, P.L.; BACCHI, O.O.S.; MORAES, S.O.; OLIVEIRA, J.C.M.; FALLEIROS, M.C. Critical analysis of the field determination of soil hydraulic conductivity functions using the flux-gradient approach. Soil & Tillage Research, Amsterdam, v.48, p.81-89, 1998.
- SISSON, J.B.; FERGUSON, A.H.; van GENUCHTEN, M.Th. Simple method for predicting drainage from field plots. Soil Science Society America Journal, Madison, v.44, p.1147-1152, 1980.
- YOUNGS, E.G. An infiltration method of measuring the hydraulic conductivity of unsaturated porous materials. Soil Science, Baltimore, v. 97, p.307-311, 1964
Publication Dates
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Publication in this collection
07 Nov 2006 -
Date of issue
Dec 2000
History
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Received
16 May 2000
