Using TDR to Estimate Hydraulic Conductivity and Air Entry in Growing Media and Sand
Gas relative diffusivity measurements are key indicators of the quality of growing media. Previous studies have shown that this property can be estimated indirectly from measurements of the point of air entry (ψa), air‐filled porosity (θa), and saturated hydraulic conductivity (Ks). Different tools...
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| Veröffentlicht in: | Soil Science Society of America journal 2002-03, Vol.66 (2), p.373-383 |
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| creator | Caron, Jean Rivière, Louis-Marie Charpentier, Sylvain Renault, Pierre Michel, Jean-Charles |
| description | Gas relative diffusivity measurements are key indicators of the quality of growing media. Previous studies have shown that this property can be estimated indirectly from measurements of the point of air entry (ψa), air‐filled porosity (θa), and saturated hydraulic conductivity (Ks). Different tools are required to measure these parameters and this paper investigates how a single tool, time domain reflectrometry (TDR), already used to determine θa from measurements of volumetric water content (θ), could be utilized to measure ψa and Ks in growing media. Cylinders were filled with 13 different substrates and coarse sand. A transient‐state technique (vertical infiltration at −1 hPa of water potential) was used to calculate Ks from θ measurements in time. In growing media, calculated Ks values from transient‐state experiment were statistically equal to estimates obtained from steady‐state measurements at a potential of −1hPa. However, both methods underestimated the Ks values obtained under steady‐state conditions after a pulse of water had been applied or after prolonged wetting. For sand, TDR‐based measurements and steady‐state infiltration at −1 hPa, provided estimates of Ks equal to those obtained after prolonged saturation. To estimate ψa, TDR probes in a horizontal and a vertical position were tested in addition to a pressure transducer technique. For growing media, the horizontal positioning of the probes provided more consistent estimates of ψa than the other two techniques. Estimates of ψa with TDR in sand, both in vertical and horizontal position, were similar. |
| doi_str_mv | 10.2136/sssaj2002.3730 |
| format | Article |
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Previous studies have shown that this property can be estimated indirectly from measurements of the point of air entry (ψa), air‐filled porosity (θa), and saturated hydraulic conductivity (Ks). Different tools are required to measure these parameters and this paper investigates how a single tool, time domain reflectrometry (TDR), already used to determine θa from measurements of volumetric water content (θ), could be utilized to measure ψa and Ks in growing media. Cylinders were filled with 13 different substrates and coarse sand. A transient‐state technique (vertical infiltration at −1 hPa of water potential) was used to calculate Ks from θ measurements in time. In growing media, calculated Ks values from transient‐state experiment were statistically equal to estimates obtained from steady‐state measurements at a potential of −1hPa. However, both methods underestimated the Ks values obtained under steady‐state conditions after a pulse of water had been applied or after prolonged wetting. For sand, TDR‐based measurements and steady‐state infiltration at −1 hPa, provided estimates of Ks equal to those obtained after prolonged saturation. To estimate ψa, TDR probes in a horizontal and a vertical position were tested in addition to a pressure transducer technique. For growing media, the horizontal positioning of the probes provided more consistent estimates of ψa than the other two techniques. Estimates of ψa with TDR in sand, both in vertical and horizontal position, were similar.</description><identifier>ISSN: 0361-5995</identifier><identifier>EISSN: 1435-0661</identifier><identifier>DOI: 10.2136/sssaj2002.3730</identifier><identifier>CODEN: SSSJD4</identifier><language>eng</language><publisher>Madison: Soil Science Society</publisher><subject>Air ; Biological and medical sciences ; Environmental Sciences ; Fundamental and applied biological sciences. Psychology ; Life Sciences ; Porosity ; Sand & gravel ; Soils ; Time</subject><ispartof>Soil Science Society of America journal, 2002-03, Vol.66 (2), p.373-383</ispartof><rights>Published in Soil Sci. Soc. Am. 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Previous studies have shown that this property can be estimated indirectly from measurements of the point of air entry (ψa), air‐filled porosity (θa), and saturated hydraulic conductivity (Ks). Different tools are required to measure these parameters and this paper investigates how a single tool, time domain reflectrometry (TDR), already used to determine θa from measurements of volumetric water content (θ), could be utilized to measure ψa and Ks in growing media. Cylinders were filled with 13 different substrates and coarse sand. A transient‐state technique (vertical infiltration at −1 hPa of water potential) was used to calculate Ks from θ measurements in time. In growing media, calculated Ks values from transient‐state experiment were statistically equal to estimates obtained from steady‐state measurements at a potential of −1hPa. However, both methods underestimated the Ks values obtained under steady‐state conditions after a pulse of water had been applied or after prolonged wetting. For sand, TDR‐based measurements and steady‐state infiltration at −1 hPa, provided estimates of Ks equal to those obtained after prolonged saturation. To estimate ψa, TDR probes in a horizontal and a vertical position were tested in addition to a pressure transducer technique. For growing media, the horizontal positioning of the probes provided more consistent estimates of ψa than the other two techniques. Estimates of ψa with TDR in sand, both in vertical and horizontal position, were similar.</description><subject>Air</subject><subject>Biological and medical sciences</subject><subject>Environmental Sciences</subject><subject>Fundamental and applied biological sciences. 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Previous studies have shown that this property can be estimated indirectly from measurements of the point of air entry (ψa), air‐filled porosity (θa), and saturated hydraulic conductivity (Ks). Different tools are required to measure these parameters and this paper investigates how a single tool, time domain reflectrometry (TDR), already used to determine θa from measurements of volumetric water content (θ), could be utilized to measure ψa and Ks in growing media. Cylinders were filled with 13 different substrates and coarse sand. A transient‐state technique (vertical infiltration at −1 hPa of water potential) was used to calculate Ks from θ measurements in time. In growing media, calculated Ks values from transient‐state experiment were statistically equal to estimates obtained from steady‐state measurements at a potential of −1hPa. However, both methods underestimated the Ks values obtained under steady‐state conditions after a pulse of water had been applied or after prolonged wetting. For sand, TDR‐based measurements and steady‐state infiltration at −1 hPa, provided estimates of Ks equal to those obtained after prolonged saturation. To estimate ψa, TDR probes in a horizontal and a vertical position were tested in addition to a pressure transducer technique. For growing media, the horizontal positioning of the probes provided more consistent estimates of ψa than the other two techniques. Estimates of ψa with TDR in sand, both in vertical and horizontal position, were similar.</abstract><cop>Madison</cop><pub>Soil Science Society</pub><doi>10.2136/sssaj2002.3730</doi><tpages>11</tpages></addata></record> |
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| subjects | Air Biological and medical sciences Environmental Sciences Fundamental and applied biological sciences. Psychology Life Sciences Porosity Sand & gravel Soils Time |
| title | Using TDR to Estimate Hydraulic Conductivity and Air Entry in Growing Media and Sand |
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