Effect of Bioagent-added Organo-mineral Nitrogen Fertilizer on Total Nitrogen, pH, and Chrome Content in Lowland Paddy

Nitrogen uptake by Rhodes grass was a linear function of the quantity of 15NH4N03 applied for rates up to the equivalent of 400 lb N/ac, but the proportion of fertilizer nitrogen recovered in the plants fell significantly when the rate was increased to 800 lb N/ac. A nitrogen pretreatment equivalent to 200 lb N/ac had relatively little effect on the uptake of 15NH4N03 by the grass, despite the fact that it almost doubled the weight of roots in the pots when the 15NH4N03 was first applied. Over the range 0–400 lb N/ac, 84.1%% of added total nitrogen and 75.5% of added 15N was taken up by plants that received no nitrogen fertilizer during the pretreatment phase, and 80.3% of added total nitrogen and 71.9% of added 15N was taken up by plants that received a pretreatment of 200 lb N/ac. Fertilizer nitrogen was distributed between tops and roots in the ratio (averaged for the two pretreatments) of 5.2 : 1 for total nitrogen and 4.5 : 1 for 15N; these ratios were constant over the range 0–400 lb N/ac and were not significantly different.

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The effect of wet season land treatment and nitrogen fertilizer on safflower, linseed, and wheat in the Ord River valley. 1. Soil and crop nitrogen

Australian Journal of Experimental Agriculture ◽

10.1071/ea9680059 ◽

1968 ◽

Vol 8 (30) ◽

pp. 59 ◽

Cited By ~ 2

Author(s):

R Wetselaar ◽

DF Beech

Keyword(s):

Ammonium Sulphate ◽

Nitrogen Fertilizer ◽

Mineral Nitrogen ◽

Plant Performance ◽

Research Station ◽

Wet Season ◽

Nitrogen Yield ◽

Nitrogen Yields ◽

Four Levels ◽

Highly Correlated

Safflower, linseed, and wheat were grown under irrigation at Kimberley Research Station in the 1964 dry season following 6 and 18 month clean and weedy fallows. Four levels of nitrogen fertilizer, as ammonium sulphate and urea, were superimposed. Crop nitrogen yields were highest after 18 months clean fallow, and were highly correlated with the amount of nitrate-nitrogen that had accumulated in the soil profile during the preceding fallow period. For wheat, which was the most efficient user of mineral nitrogen, 160 lb nitrogen an acre as ammonium sulphate was required after 18 months weedy fallow to equal the crop nitrogen yield after 18 months clean fallow without nitrogen fertilizer. The mean crop nitrogen yield with urea was only 76.7 per cent of that with ammonium sulphate. The results indicate that the form, and possibly the distribution, of mineral nitrogen in the soil in the early stages of crop growth could be important factors determining the efficiency of nitrogen for optimum plant performance.

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Suitability of Composted Maize Straw and Mineral Nitrogen Fertilizer for Tomato Production

Journal of Vegetable Science ◽

10.1300/j484v11n01_06 ◽

2005 ◽

Vol 11 (1) ◽

pp. 57-65 ◽

Cited By ~ 2

Author(s):

W. B. Akanbi ◽

M. O. Akande ◽

J. A. Adediran

Keyword(s):

Nitrogen Fertilizer ◽

Mineral Nitrogen ◽

Tomato Production ◽

Maize Straw

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Effect of nitrogen fertilizer applied to winter oilseed rape (Brassica napus) on soil mineral nitrogen after harvest and on the response of a succeeding crop of winter wheat to nitrogen fertilizer

The Journal of Agricultural Science ◽

10.1017/s002185960008881x ◽

1996 ◽

Vol 126 (1) ◽

pp. 63-74 ◽

Cited By ~ 36

Author(s):

M. A. Shepherd ◽

R. Sylvester-Bradley

Keyword(s):

Organic Matter ◽

Oilseed Rape ◽

Nitrogen Fertilizer ◽

Organic Matter Content ◽

Matter Content ◽

Mineral Nitrogen ◽

Fertilizer N ◽

Soil Mineral ◽

Soil Mineral Nitrogen ◽

Optimum Amount

SUMMARYSoil mineral nitrogen (Nmin) was measured to 90 cm at a total of 12 sites in the UK in the autumn after an oilseed rape experiment, which measured responses to fertilizer N. On average, Nmin, increased by 15 kg/ha per 100 kg/ha fertilizer nitrogen (N) applied to the rape, up to the economic optimum amount of N (Nmin). There were larger increases in Nmin where fertilizer applications exceeded Nopt, thus super-optimal fertilizer applications disproportionately increased the amount of nitrate likely to leach over-winter. The small effects of sub-optimal N on Nmin were associated with large increases in N offtake by the oilseed rape, whereas the larger effects of super-optimal N on Nmin were associated with only small increases in N offtake. Over 70% of the variation in autumn Nmin was explained by the previous rape's N fertilizer rate and the topsoil organic matter content.Nitrogen applied to the rape increased grain yields of the succeeding wheat crops when no further fertilizer N was applied to the wheat. It was concluded that N applied to oilseed rape significantly affected Nmin after harvest, and these effects were not completely nullified by leaching over-winter, so soil N supply to the succeeding wheat crop was significantly increased. Responses in grain yield indicated that each 100 kg/ha N applied to the rape provided N equivalent to c. 30 kg/ha for the following cereal. Each 1% of soil organic matter further contributed N to the wheat, equivalent to 25 kg/ha.It is important to ensure that oilseed rape receives no more than the optimum amount of fertilizer N if subsequent leaching is to be minimized. Reductions below optimum amounts will have only a small effect on leaching. Substantial changes in the economic optimum N for rape production should be accompanied by adjustment in fertilizer N application to following wheat crops. Fertilizer recommendation systems for wheat should take account of the fertilizer N applied to the preceding oilseed rape and the topsoil organic matter content.

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Effect of Partial Substitution of Mineral Nitrogen Fertilizer by Farm Compost on Soil Fertility and Productivity

Journal of Soil Sciences and Agricultural Engineering ◽

10.21608/jssae.2018.36525 ◽

2018 ◽

Vol 9 (12) ◽

pp. 761-764

Author(s):

M. Taha ◽

Salwa Eisa

Keyword(s):

Soil Fertility ◽

Nitrogen Fertilizer ◽

Mineral Nitrogen ◽

Partial Substitution

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Influence of temperature upon the mobilization of nitrogen in peat

Agricultural and Food Science ◽

10.23986/afsci.71345 ◽

1953 ◽

Vol 25 (1) ◽

pp. 37-46

Author(s):

Armi Kaila ◽

Jaakko Köylijärvi ◽

Erkki Kivinen

Keyword(s):

Organic Matter ◽

Total Nitrogen ◽

Considerable Increase ◽

Ammonia Nitrogen ◽

Mineral Nitrogen ◽

Chemical Transformations ◽

Peat Soils ◽

Ammonia Content ◽

Marked Accumulation ◽

Thermophilic Organisms

The preliminary experiments the results of which are recorded in the present paper, have been carried out in order to obtain some information on the microbiological and chemical mobilization of peat nitrogen at various temperatures. In the incubation experiment at 5°, 20°, 35°, 50°, and 65CC the accumulation of ammonia nitrogen increased with a rising temperature except in the limed series where a minimum was found at 20°. The maximum of nitrate-nitrogen lay at 20 in both the series. The amount of nitrite-nitrogen was almost negligible in all the samples. The mineral nitrogen in the samples incubated at 50° and 65° represented 10—20 % of the total nitrogen. Thus, the organic nitrogen in peat soils can be mobilized to a marked extent, if the conditions are favourable. Accumulation of mineral nitrogen could be stated also at the lower temperatures where the reutilization of released nitrogen in the synthesis of new microbial substance is always more intensive than in the range of thermophilic organisms. Even at 5° a release of nitrogen was noticable. In these experiments liming did not show any beneficial effect upon the accumulation of mineral nitrogen, on the contrary, the values for total nitrogen and ammonia nitrogen were lower in the limed series. The nitrate formation was generally somewhat higher in the limed samples than in the corresponding unlimed ones. It was supposed that the considerable increase in the ammonia content of the samples incubated at 50° and 65° was partly due to purely chemical transformations, since the mere heating of moist samples at 75° for two hours brought about a marked accumulation of ammonia nitrogen. The treatment with dry heat was less effective except when the temperature was raised to 200° in which case a carbonization of the peat took place. The losses of organic matter and of total nitrogen due to the heating were almost negligible at the temperatures below 150°. At 150° and at 200°, respectively, about one tenth and one third of the organic matter was burnt up, and the losses of total nitrogen corresponded to approximately one half of the decrease in dry matter. On the basis of the results reported above valid conclusions ought not to be drawn, since the material is too scarce. However, these experiments indicate that reasons for further research exist.

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