Cadmium stress in paddy fields: Effects of soil conditions and remediation strategies

Subsurface drainage technology may offer a useful option in improving crop productivity by preventing water-logging in poor drainage paddy fields. The present study compared two paddy fields with and without sheet-pipe type subsurface drainage on land and water productivities in Indonesia. Sheet-pipe typed is perforated plastic sheets with a hole diameter of 2 mm and made from high-density polyethylene. It is commonly installed 30–50 cm below the soil surface and placed horizontally by a machine called a mole drainer, and then the sheets will automatically be a capillary pipe. Two fields were prepared, i.e., the sheet-pipe typed field (SP field) and the non-sheet-pipe typed field (NSP field) with three rice varieties (Situ Bagendit, Inpari 6 Jete, and Inpari 43 Agritan). In both fields, weather parameters and water depth were measured by the automatic weather stations, soil moisture sensors and water level sensors. During one season, the SP field drained approximately 45% more water compared to the NSP field. Thus, it caused increasing in soil aeration and producing a more significant grain yield, particularly for Inpari 43 Agritan. The SP field produced a 5.77 ton/ha grain yield, while the NSP field was 5.09 ton/ha. By producing more grain yield, the SP field was more effective in water use as represented by higher water productivity by 20%. The results indicated that the sheet-pipe type system developed better soil aeration that provides better soil conditions for rice.

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Modelling Methane and Nitrous Oxide Emissions from Rice Paddy Wetlands in India Using Artificial Neural Networks (ANNs)

Water ◽

10.3390/w11102169 ◽

2019 ◽

Vol 11 (10) ◽

pp. 2169 ◽

Cited By ~ 4

Author(s):

Tabassum Abbasi ◽

Tasneem Abbasi ◽

Chirchom Luithui ◽

Shahid Abbas Abbasi

Keyword(s):

Nitrous Oxide ◽

Paddy Fields ◽

Anthropogenic Sources ◽

Nitrous Oxide Emissions ◽

Soil Conditions ◽

N2o Emissions ◽

Ch4 Emissions ◽

Artificial Neural ◽

Ch4 And N2o

Paddy fields, which are shallow man-made wetlands, are estimated to be responsible for ~11% of the total methane emissions attributed to anthropogenic sources. The role of water use in driving these emissions, and the apportioning of the emissions to individual countries engaged in paddy cultivation, are aspects that have been mired in controversy and disagreement. This is largely due to the fact that methane (CH4) emissions not only change with the cultivar type but also regions, climate, soil type, soil conditions, manner of irrigation, type and quantity of fertilizer added—to name a few. The factors which can influence these aspects also encompass a wide range, and have origins in causes which can be physical, chemical, biological, and combinations of these. Exceedingly complex feedback mechanisms, exerting different magnitudes and types of influences on CH4 emissions under different conditions, are operative. Similar is the case of nitrous oxide (N2O); indeed, the present level of understanding of the factors which influence the quantum of its emission is still more patchy. This makes it difficult to even understand precisely the role of the myriad factors, less so model them. The challenge is made even more daunting by the fact that accurate and precise data on most of these aspects is lacking. This makes it nearly impossible to develop analytical models linking causes with effects vis a vis CH4 and N2O emissions from paddy fields. For situations like this the bioinspired artificial intelligence technique of artificial neural network (ANN), which can model a phenomenon on the basis of past data and without the explicit understanding of the mechanism phenomena, may prove useful. However, no such model for CH4 or N2O has been developed so far. Hence the present work was undertaken. It describes ANN-based models developed by us to predict CH4 and N2O emissions using soil characteristics, fertilizer inputs, and rice cultivar yield as inputs. Upon testing the predictive ability of the models with sets of data not used in model development, it was seen that there was excellent agreement between model forecasts and experimental findings, leading to correlations coefficients of 0.991 and 0.96, and root mean square error (RMSE) of 11.17 and 261.3, respectively, for CH4 and N2O emissions. Thus, the models can be used to estimate CH4 and N2O emissions from all those continuously flooded paddy wetlands for which data on total organic carbon, soil electrical conductivity, applied nitrogen, phosphorous and potassium, NPK, and grain yield is available.

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OPTIMIZING IRRIGATION AND DRAINAGE RATES IN SRI PADDY FIELDS

Jurnal Teknologi ◽

10.11113/jt.v76.5966 ◽

2015 ◽

Vol 76 (15) ◽

Cited By ~ 1

Author(s):

Budi Indra Setiawan ◽

Chusnul Arif ◽

Rudiyanto Rudiyanto ◽

Muhamad Askari

Keyword(s):

Water Level ◽

Daily Rainfall ◽

Flow Equation ◽

Paddy Fields ◽

Soil Conditions ◽

Drainage Rate ◽

Water Rates ◽

Neumann Type ◽

Simulator Program ◽

Planting Season

A quantified study to optimize furrow irrigation and drainage rates for SRI paddy fields has been carried out over three different planting seasons. It is very crucial to maintain soil conditions where the water level sustains soil moisture at around saturation and air-entry values. In the present study we report on a simulator program which applies a saturated water flow equation in one dimension for which boundary conditions at both ends formed water rates (Neumann type). A spreadsheet optimization using an imbedded Solver in MS Excel was employed alongside the simulation. Daily rainfall, evapotranspiration and percolation rates as sink-source functions were incorporated into the equations. Our study shows that optimizing irrigation and drainage rates gives an effective water level for SRI paddy fields within a range of -5 to 0 cm for all planting seasons. The highest value for irrigation rate within the furrow was about 6 mm per day, while the optimizing drainage rate was about 0.5 mm per day. Water table profiles are significantly affected by planting season. Our study confirmed that conserving drained water from one planting season is desirable to provide sufficient irrigation water for the next planting season.

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SOIL REHABILITATION TO INCREASE PRODUCTIVITY BOYOLALI AGRICULTURE BY FAST DETECTION CURCUMARVEL

OISAA Journal of Indonesia Emas ◽

10.52162/jie.2020.003.01.3 ◽

2020 ◽

Vol 3 (1) ◽

pp. 20-26

Author(s):

Dwi Rahmasari Fatmawati ◽

Annisa Kurniawati ◽

Arsyadani Tri Nastiti Nur ◽

Eli Budia Pamilujeng ◽

Praditya Rizqi Novanto ◽

...

Keyword(s):

Soil Acidity ◽

Paddy Fields ◽

Soil Conditions ◽

Land Rehabilitation ◽

Fast Detection ◽

Soil Rehabilitation ◽

Increase Productivity ◽

Paddy Land ◽

Biological Fertilizer ◽

Group Empowerment

Boyolali district is one of the areas that has decreased productivity of rice. The decline was due to acidic soil conditions coupled with a lack of awareness of farmers and lack of support for facilities and infrastructure. Basically, to find out the conditions of the soil can be done by detecting the soil using a pH meter. The tool is not widely used because the price is expensive and the farmers care less about the conditions of their paddy fields. The aim of this program is to empower the farming group to be the agent of land rehabilitation through early detection of CurcuMarvel using tumeric. Soil detection devices can be innovated using turmeric. Turmeric that is easily found and familiar among farmers is the solution to the problem of detecting soil conditions. The target was Sari Tani Farming Group located in Suyudan Village , Boyolali Regency. The program involved 10 farmers as the representative of the farmer group. Empowerment programs were conducted by combining several methods, including participatory, discourse, demonstration, and discussion. The activities of CurcuMarvel consist of: (1) transferring information using educational video; (2) demonstrating the soil acidity detection in one of the farmer's paddy fields; (3) land rehabilitation efforts by applying dolomite, manure, and biological fertilizer in the demonstration plot; and (4) turmeric cultivation training in the farmer's yard to prepare the village as the turmeric cultivation center. The outcomes of the program are: (1) the farmers know that their paddy land is acid; (2) the farmers increase their awareness towards the soil acidity effect; (3) the farmers conduct soil rehabilitation; and (4) the farmers have a turmeric center near to the paddy field.

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Soil Salinity Assessment in Irrigated Paddy Fields of the Niger Valley Using a Four-Year Time Series of Sentinel-2 Satellite Images

Remote Sensing ◽

10.3390/rs12203399 ◽

2020 ◽

Vol 12 (20) ◽

pp. 3399

Author(s):

Issaka Moussa ◽

Christian Walter ◽

Didier Michot ◽

Issifou Adam Boukary ◽

Hervé Nicolas ◽

...

Keyword(s):

Grain Yield ◽

Temporal Resolution ◽

Soil Salinity ◽

Bare Soil ◽

Paddy Fields ◽

Soil Conditions ◽

High Temporal Resolution ◽

Total Biomass ◽

Growing Seasons ◽

Sentinel 2

Salinization is a major soil degradation threat in irrigated systems worldwide. Irrigated systems in the Niger River basin are also affected by salinity, but its spatial distribution and intensity are not currently known. The aim of this study was to develop a method to detect salt-affected soils in irrigated systems. Two complementary approaches were tested: salinity assessment of bare soils using a salinity index (SI) and monitoring of indirect effects of salinity on rice growth using temporal series of a vegetation index (NDVI). The study area was located south of Niamey (Niger) in two irrigated systems of rice paddy fields that cover 6.5 km2. We used remote-sensing and ground-truth data to relate vegetation behavior and reflectance to soil characteristics. We explored all existing Sentinel-2 images from January 2016 to December 2019 and selected cloud-free images on 157 dates that covered eight successive rice-growing seasons. In the dry season of 2019, we also sampled 44 rice fields, collecting 147 biomass samples and 180 topsoil samples from January to June. For each field and growing season, time-integrated NDVI (TI-NDVI) was estimated, and the SI was calculated for dates on which bare soil conditions (NDVI < 0.21) prevailed. Results showed that since there were few periods of bare soil, SI could not differentiate salinity classes. In contrast, the high temporal resolution of Sentinel-2 images enabled us to describe rice-growing conditions over time. In 2019, TI-NDVI and crop yields were strongly correlated (r = 0.77 with total biomass yield and 0.82 with grain yield), while soil electrical conductivity was negatively correlated with both TI-NDVI (r = −0.38) and crop yield (r = −0.23 with total biomass and r = −0.29 with grain yield). Considering the TI-NDVI data from 2016–2019, principal component analysis followed by ascending hierarchical classification identified a typology of five clusters with different patterns of TI-NDVI during the eight growing seasons. When applied to the entire study area, this classification clearly identified the extreme classes (i.e., areas with high or no salinity). Other classes with low TI-NDVI (i.e., during dry seasons) may be related to areas with moderate or seasonal soil salinity. Finally, the high temporal resolution of Sentinel-2 images enabled us to detect stresses on vegetation that occurred repeatedly over the growing seasons, which may be good indicators of soil constraints due to salinity in the context of the irrigated paddy systems of Niger. Further research will validate the ability of the method developed to detect moderate soil salinity constraints over large areas.

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How different soil moisture levels affect the microbial activity

Ciência Rural ◽

10.1590/0103-8478cr20190831 ◽

2020 ◽

Vol 50 (6) ◽

Author(s):

Luiz Gustavo de Oliveira Denardin ◽

Lucas Aquino Alves ◽

Cícero Ortigara ◽

Bruna Winck ◽

João Augusto Coblinski ◽

...

Keyword(s):

Soil Moisture ◽

Moisture Content ◽

Enzymatic Activity ◽

Microbial Activity ◽

Water Saturation ◽

Paddy Fields ◽

Soil Conditions ◽

Flooded Soil ◽

Activity Data ◽

Soil Microbial

ABSTRACT: The lowland soils are characterized by high susceptibility to water saturation. This anaerobic condition is usually reported in paddy fields and alters the decomposition process of soil organic compounds. The aim of this study was to evaluate the soil microbial and enzymatic activity of a lowland soil at different soil moisture contents. A poorly drained Albaqualf cultivated with irrigated rice was used to evaluate microbial and enzymatic activity in treatments with different levels of soil moisture, being: i) 60% of field capacity (FC) (60%FC); ii) 100% of FC (100%FC); iii) flooded soil with a 2 cm water layer above soil surface, and iv) soil kept at 60%FC with late flood after 29 days the incubation. The greater soil microbial activity was observed in the 100%FC treatment, being 41% greater than 60%FC treatment and only 2% higher than flooded treatment. The enzymatic activity data by fluorescein diacetate (FDA) hydrolysis corroborated the higher CO2 release in treatments with higher soil moisture content. Differently from the results reported, the main methodologies to evaluate microbial activity still recommend maintenance of the soil with a moisture content close to 60% of the FC. However, in lowland soil with history of frequent paddy fields, the maintenance of moisture close to 60% of the FC can limit the microbial activity. The soil respiration technique can be used to evaluate the microbial activity in flooded soil conditions. However, further studies should be conducted to understand the effect of the cultivation history on the microbial community of these environments.

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Improving soil remediation through characterization

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100138300 ◽

1995 ◽

Vol 53 ◽

pp. 386-387

Author(s):

E. C. Buck ◽

N. L. Dietz ◽

J. K. Bates

Keyword(s):

Dust Particles ◽

Radiochemical Analysis ◽

Solid Product ◽

Uranium Contamination ◽

Physical Separation ◽

X Ray ◽

Rocky Flats ◽

Remediation Strategies ◽

Bearing Materials ◽

X Ray Absorption

Operations at former weapons processing facilities in the U. S. have resulted in a large volume of radionuclidecontaminated soils and residues. In an effort to improve remediation strategies and meet environmental regulations, radionuclide-bearing particles in contaminant soils from Fernald in Ohio and the Rocky Flats Plant (RFP) in Colorado have been characterized by electron microscopy. The object of these studies was to determine the form of the contaminant radionuclide, so that it properties could be established [1]. Physical separation and radiochemical analysis determined that uranium contamination at Fernald was not present exclusively in any one size/density fraction [2]. The uranium-contamination resulted from aqueous and solid product spills, air-borne dust particles, and from the operation of an incinerator on site. At RFP the contamination was from the incineration of Pu-bearing materials. Further analysis by x-ray absorption spectroscopy indicated that the majority of the uranium was in the 6+ oxidation state [3].

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