Time of soil water thermodynamic equilibrium during retention curve establishment using gamma-ray beam attenuation

Pires, L.; Bacchi, O.; Reichardt, K.

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Tytuł artykułu

Time of soil water thermodynamic equilibrium during retention curve establishment using gamma-ray beam attenuation

Autorzy

Pires L. , Bacchi O. , Reichardt K.

Treść / Zawartość

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Time of soil water thermodynamic equilibrium during retention curve establishment.pdf

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Abstrakty

The soil water retention curve (SWRC) represents a fundamental part of the characterization of the soil hydraulic properties. The establishment of SWRC is usually time-consuming and presents several problems such as the difficulty of a correct judgment of the time of equilibrium. This work presents a new methodology that involves gammaray beam attenuation technique associated with the traditional pressure chambers, having as objective the more precise judgment of the time to attain equilibrium. The gamma-ray source used has an activity of 3.7 GBq consisting of 241Am, with peak energy of 59.54 keV. For the determination of retention curves using the gamma-ray attenuation technique, an acrylic pressure chamber was projected and constructed to be positioned between the source and detector with the gamma-ray beam crossing the center of the chamber and the soil sample during water extraction. The proposed technique allowed, through a specifically elaborated software for data acquisition, to evaluate with precision the exact instant of the equilibrium and, consequently, to obtain the right moment to change the chamber pressure to a new desired level, leading to a reduction of the time required for the whole retention curve determination. The results obtained show that the gamma-ray attenuation technique can be very useful as an auxiliary tool to evaluate SWRC, utilizing the Richards chamber.

Słowa kluczowe

gamma-ray attenuation time of equilibrium pressure chamber soil water retention curve

Wydawca

Institute of Nuclear Chemistry and Technology

Czasopismo

Nukleonika

Rocznik

2005

Tom

Vol. 50, nr 4

Strony

173--177

Opis fizyczny

Bibliogr. 19 poz., rys.

Twórcy

autor

Pires L.

lfpires@cena.usp.br

Center for Nuclear Energy in Agriculture, The University of Săo Paulo, C. P. 96, C. E. P. 13.400-970, Piracicaba, SP, Brazil, Tel.: +55-19 3429 4600 ext. 4712, Fax: +55-19 3429 4610

autor

Bacchi O.

Center for Nuclear Energy in Agriculture, The University of Săo Paulo, C. P. 96, C. E. P. 13.400-970, Piracicaba, SP, Brazil, Tel.: +55-19 3429 4600 ext. 4712, Fax: +55-19 3429 4610

autor

Reichardt K.

Center for Nuclear Energy in Agriculture, The University of Săo Paulo, C. P. 96, C. E. P. 13.400-970, Piracicaba, SP, Brazil, Tel.: +55-19 3429 4600 ext. 4712, Fax: +55-19 3429 4610

Bibliografia

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2. Assouline S, Tavares-Filho J, Tessier D (1997) Effect of compaction on soil physical and hydraulic properties: experimental results and modeling. Soil Sci Soc Am J 61:390−398.
3. Bacchi OOS, Reichardt K, Oliveira JCM, Nielsen DR (1998) Gamma-ray beam attenuation as an auxiliary technique for the evaluation of soil water retention curve. Scientia Agricola 55:499−502.
4. Chahal RS, Yong RN (1965) Validity of the soil water characteristics determined with the pressurized apparatus. Soil Sci 99:98−103.
5. Conner AL, Atwater HF, Plassmann EH, MacCrary JH (1970) Gamma-ray attenuation coefficients measure-ments. Phys Rev A 1:539−544.
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13. Ng CWW, Pang YW (2000) Experimental investigations of the soil-water characteristics of a volcanic soil. Can Geotech J 37:1252−1264.
14. Pires LF, Bacchi OOS, Reichardt K (2004) Damage to soil physical caused by soil sampler devices as assessed by gamma ray computed tomography. Aust J Soil Res 42:857−863.
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16. Reginato RJ, van Bavel CHM (1962) Pressure cell for soil cores. Soil Sci Soc Am J 26:1−3.
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Bibliografia

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bwmeta1.element.baztech-article-BUJ6-0004-0087