Aerenchyma Formation and Methane and Oxygen Exchange in Rice
Limited information exists on the direct link between the intensity of soil reduction or anaerobiosis and gas exchange in rice (Oryza sativa L.). A laboratory experiment was conducted to determine the extent to which specific levels of soil redox potential (Eh) could influence aerenchyma formation,...
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| Published in: | Soil Science Society of America journal Vol. 57; no. 2; pp. 386 - 391 |
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| Main Authors: | , , |
| Format: | Journal Article |
| Language: | English |
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Madison, WI
Soil Science Society of America
01-03-1993
American Society of Agronomy |
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| Online Access: | Get full text |
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| Abstract | Limited information exists on the direct link between the intensity of soil reduction or anaerobiosis and gas exchange in rice (Oryza sativa L.). A laboratory experiment was conducted to determine the extent to which specific levels of soil redox potential (Eh) could influence aerenchyma formation, O2 transport, and CH4 production and emission. Plants were grown in a Crowley silt loam (fine, montmorillonitic, thermic Typic Albaqualf) under controlled Eh values of 200, ‐200, and −300 mV. Radial O2 loss (ROL) from plant roots was estimated colorimetrically by using Ti3+‐citrate solution, a reduced compound. Methane production and its emission increased with decrease in soil Eh; CH4 production increased 10‐fold while its emission was enhanced 17‐fold when soil Eh dropped from ‐200 to −300 mV. A positive relationship was established between the intensity of soil anaerobiosis and both aerenchyma formation and ROL. Root and shoot dry weights and root length decreased with decrease in soil Eh. Results of this study demonstrate that soil Eh influences net CH4 flux from rice in two ways: (i) it directly determines the amount and rate of CH4 production in the soil, and (ii) it initiates morphological and physiological changes in the rice plant that affect gas exchange between the soil and the atmosphere. Although the results may not necessarily reflect actual conditions in the field, they provide a theoretical basis for understanding the influence of soil Eh on rice growth, CH4 production, and gas exchange. |
|---|---|
| AbstractList | The extent to which specific levels of soil redox potential (Eh) could influence aerenchyma formation, oxygen transport and methane production is examined. Limited information exists on the direct link between the intensity of soil reduction or anaerobiosis and gas exchange in rice (Oryza sativa L.). A laboratory experiment was conducted to determine the extent to which specific levels of soil redox potential (Eh) could influence aerenchyma formation. O[sub 2] transport, and CH[sub 4] production and emission. Plants were grown in a Crowley silt loam (fine, montmorillonitic, thermic Typic Albaqualf) under controlled Eh values of 200, -200, and [minus]300 mV. Radial O[sub 2] loss (ROL) from plant roots was estimated colorimetrically by using Ti[sup 3+]-citrate solution, a reduced compound. Methane production and its emission increased with decrease in soil Eh; CH[sub 4] production increased 10-fold while its emission was enhanced 17-fold when soil Eh dropped from [minus]200 to [minus]300 mV. A positive relationship was established between the intensity of soil anaerobiosis and both aerenchyma formation and ROL. Root and shoot dry weights and root length decreased with decrease in soil Eh. Results of this study demonstrate that soil Eh influences net CH[sub 4] flux from rice in two ways: (i) it directly determines the amount and rate of CH[sub 4] production in the soil, and (ii) it initiates morphological and physiological changes in the rice plant that affect gas exchange between the soil and the atmosphere. Although the results may not necessarily reflect actual conditions in the field, they provide a theoretical basis for understanding the influence of soil Eh on rice growth, CH[sub 4] production, and gas exchange. 36 refs., 6 figs., 2 tabs. Limited information exists on the direct link between the intensity of soil reduction or anaerobiosis and gas exchange in rice (Oryza sativa L.). A laboratory experiment was conducted to determine the extent to which specific levels of soil redox potential (Eh) could influence aerenchyma formation, O2 transport, and CH4 production and emission. Plants were grown in a Crowley silt loam (fine, montmorillonitic, thermic Typic Albaqualf) under controlled Eh values of 200, ‐200, and −300 mV. Radial O2 loss (ROL) from plant roots was estimated colorimetrically by using Ti3+‐citrate solution, a reduced compound. Methane production and its emission increased with decrease in soil Eh; CH4 production increased 10‐fold while its emission was enhanced 17‐fold when soil Eh dropped from ‐200 to −300 mV. A positive relationship was established between the intensity of soil anaerobiosis and both aerenchyma formation and ROL. Root and shoot dry weights and root length decreased with decrease in soil Eh. Results of this study demonstrate that soil Eh influences net CH4 flux from rice in two ways: (i) it directly determines the amount and rate of CH4 production in the soil, and (ii) it initiates morphological and physiological changes in the rice plant that affect gas exchange between the soil and the atmosphere. Although the results may not necessarily reflect actual conditions in the field, they provide a theoretical basis for understanding the influence of soil Eh on rice growth, CH4 production, and gas exchange. |
| Author | DeLaune, R. D. Kludze, H. K. Patrick, W. H. |
| Author_xml | – sequence: 1 givenname: H. K. surname: Kludze fullname: Kludze, H. K. email: n/a@.dne organization: Wetland Biogeochemistry Institute, Louisiana State Univ – sequence: 2 givenname: R. D. surname: DeLaune fullname: DeLaune, R. D. organization: Wetland Biogeochemistry Institute, Louisiana State Univ – sequence: 3 givenname: W. H. surname: Patrick fullname: Patrick, W. H. organization: Wetland Biogeochemistry Institute, Louisiana State Univ |
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| Copyright | 1993 Soil Science Society of America Copyright American Society of Agronomy Mar 1993 |
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| Keywords | Anaerobiosis Methane Plant tissue Laboratory study Monocotyledones Oxygen Cereal crop Oryza sativa Gramineae Angiospermae Development Spermatophyta Gas exchange Redox potential Soil plant relation |
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| Snippet | Limited information exists on the direct link between the intensity of soil reduction or anaerobiosis and gas exchange in rice (Oryza sativa L.). A laboratory... The extent to which specific levels of soil redox potential (Eh) could influence aerenchyma formation, oxygen transport and methane production is examined. |
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| SubjectTerms | 09 BIOMASS FUELS 090800 - Biomass Fuels- Production- (1990-) 095000 - Biomass Fuels- Environmental Aspects- (1990-) AGRICULTURE Agronomy. Soil science and plant productions ALKANES Biological and medical sciences Biology BIOSYNTHESIS CLIMATIC CHANGE DATA ELEMENTS EXPERIMENTAL DATA Fundamental and applied biological sciences. Psychology General agronomy. Plant production GREENHOUSE EFFECT HYDROCARBONS INFORMATION LOAM METHANE NONMETALS NUMERICAL DATA ORGANIC COMPOUNDS OXYGEN REDOX POTENTIAL Rice Soil-plant relationships. Soil fertility Soil-plant relationships. Soil fertility. Fertilization. Amendments SOILS SYNTHESIS |
| Title | Aerenchyma Formation and Methane and Oxygen Exchange in Rice |
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