Influence of long-term tillage, straw and N fertilizer on barley yield, plant-N uptake and soil-N balance

1995 ◽  
Vol 36 (3-4) ◽  
pp. 165-174 ◽  
Author(s):  
M. Nyborg ◽  
E.D. Solberg ◽  
R.C. Izaurralde ◽  
S.S. Malhi ◽  
M. Molina-Ayala
Keyword(s):  
N Uptake ◽  
N Fertilizer ◽  
N Balance ◽  
Soil N ◽  
Plant N Uptake

Nitrogen turnover of chernozem meadow soil in a long-term mineral fertilisation trial

2010 ◽  
Vol 58 (Supplement 1) ◽  
pp. 57-62 ◽  
Author(s):  
Z. Izsáki
Keyword(s):  
N Uptake ◽  
N Balance ◽  
N Leaching ◽  
Meadow Soil ◽  
Soil N ◽  
Plant N Uptake ◽  
Experimental Conditions ◽  
N Accumulation ◽  
The Given

The elaboration and introduction of an environment-friendly N fertilisation system requires studies on the soil N regime, and on NO 3 -N accumulation and leaching under field conditions. The present work aimed to provide data on the soil N balance and on the depth distribution and leaching of NO 3 -N in chernozem meadow soil, based on the results of an 18-year long-term mineral fertilisation experiment. The soil contained 3.0–3.2% humus and had good N-supplying ability. Averaged over 18 years, the plant N uptake on plots without N fertilisation was 126 kg ha −1 year −1 . At the 80 kg ha −1 N rate the soil N balance was negative, with a mean plant N uptake of 170 kg ha −1 year −1 and a low rate of NO 3 -N leaching was observed. At 160 kg ha −1 N the accumulated N balance was only slightly negative. In 7 of the 18 years plant N uptake was below 160 kg ha −1 . Under the given experimental conditions, considering the natural N-supplying capacity of the soil, the 160 kg ha −1 N fertiliser rate proved to be excessive, surpassing the N requirements of the potential crop yield in most years and resulting in NO 3 -N leaching. The N regime data indicated that the 240 kg ha −1 N rate represented over-fertilisation in the given location.

Effects of long-term annual inputs of straw and organic manure on plant N uptake and soil N fluxes

2007 ◽  
Vol 23 (4) ◽  
pp. 368-373 ◽  
Author(s):  
J. Luxhøi ◽  
L. Elsgaard ◽  
I. K. Thomsen ◽  
L. S. Jensen
Keyword(s):  
N Uptake ◽  
Organic Manure ◽  
Soil N ◽  
Plant N Uptake ◽  
N Fluxes

scholarly journals Growing Soybean Prior to Corn Increased Soil Nitrogen Supply and N Fertilizer Efficiency for Corn in Cold and Humid Conditions of Eastern Canada

2012 ◽  
Vol 1 (2) ◽  
pp. 257
Author(s):  
Adrien N. Dayegamiye ◽  
Judith Nyiraneza ◽  
Johann K. Whalen ◽  
Michèle Grenier ◽  
Anne Drapeau
Keyword(s):  
N Uptake ◽  
N Fertilizer ◽  
Crop Rotations ◽  
Fertilizer Efficiency ◽  
Corn Yield ◽  
Soil N ◽  
Eastern Canada ◽  
Continuous Corn ◽  
N Fertilizer Efficiency ◽  
Corn Grain

<p>Growing soybean (<em>Glycine max L.)</em> prior to corn (<em>Zea mays</em> L) can enhance corn grain and nitrogen (N) use efficiency compared to continuous corn. This two year study (2007-2008) was conducted at 62 sites in Quebec (Eastern Canada) to assess the effect of crop rotations [soybean-corn, soybean-wheat (<em>Triticum aestivum</em> L.,)-corn and corn-corn] on corn yield, N uptake, N fertilizer efficiency (NFE), and the economic optimum N rate (EONR). Plots within each crop rotation received N fertilizer rates from 0 to 250 kg N ha<sup>-1</sup> to assess the N contribution from the preceding soybean crop. Corn grain yields ranged from 8.4 to 10.8 Mg ha<sup>-1</sup> and were lower in continuous corn than in the crop rotations. Corn N uptake and NFE varied from 89 to 164 kg N ha<sup>-1</sup> and from 45 to 80 kg grain per kg N fertilizer, respectively. A significant interaction of crop rotation and year on corn N uptake and NFE was obtained implying that annual variations influenced soil N supply. The EONR for corn was lower under crop rotations than continuous corn in 2008 only. No difference in corn yield, NFE and EONR was observed for soybean-corn and soybean-wheat-corn crop sequences. In conclusion, crop rotations including soybean increased soil N availability and reduced EONR from 32 to 45 kg ha<sup>-1</sup> for corn grown in 2008.</p>

Effects of contrasted cropping systems on yield and N balance of upland rainfed rice in Madagascar: Inputs from the DSSAT model

2020 ◽  
Vol 56 (3) ◽  
pp. 355-370
Author(s):  
Julie Dusserre ◽  
Patrice Autfray ◽  
Miora Rakotoarivelo ◽  
Tatiana Rakotoson ◽  
Louis-Marie Raboin
Keyword(s):  
Upland Rice ◽  
Smallholder Farmers ◽  
Cropping Systems ◽  
N Uptake ◽  
Cropping System ◽  
N Balance ◽  
Soil N ◽  
Smallholder Farming ◽  
Velvet Bean ◽  
Experimental Conditions

AbstractIn response to the extensive development of upland rice on the hillsides of the Malagasy highlands, alternative cropping systems have been designed based on conservation agriculture (CA). As the promotion of CA in smallholder farming systems is still the subject of debate, its potential benefits for smallholder farmers require further assessment. In the context of resource-poor farmers and low-input production systems, nitrogen (N) is a major limiting nutrient. The effects of contrasted cropping systems have been studied on upland rice yield and N uptake in rainfed conditions: conventional tillage (CT) and CA with a mulch of maize or a legume (Stylosanthes or velvet bean). Decision Support Systems for Agrotechnology Transfer (DSSAT) crop growth model was used to quantify the soil N balance according to the season and the cropping system. The lowest yields were obtained in CA with a mulch of maize and were also associated with the lowest crop N uptake. Upland rice yields were higher or equivalent under CA with a legume mulch than under CT cropping systems. The supply of N was considerably higher in CA with a legume mulch than in CT, but due to higher leaching and immobilization in CA, the final contribution of N from the mulch to the crop was reduced although not negligible. DSSAT has been shown to be sufficiently robust and flexible to simulate the soil N balance in contrasting cropping systems. The challenge is now to evaluate the model in less contrasted experimental conditions in order to validate its use for N uptake and yield prediction in support to the optimization and design of new cropping systems.

scholarly journals N Balance and Requirements Under Different N Management Practices in a No-Till Perennial Rice Cropping System

2021 ◽  
Author(s):  
Guangfu Huang ◽  
Yujiao Zhang ◽  
Shilai Zhang ◽  
Jing Zhang ◽  
Shuxian Gan ◽  
...  
Keyword(s):  
N Uptake ◽  
Cropping System ◽  
Rice Production ◽  
N Balance ◽  
Dry Matter Accumulation ◽  
Soil N ◽  
Grain Yields ◽  
Four Seasons ◽  
N Management ◽  
N Use

Abstract Aims: In the absence of tillage, perennial rice is an innovation and supplement to rice production. Evaluating crop N uptake and N requirements and maintaining soil N balance are essential for informing decisions regarding optimal N management and the accessibility of the soil environment benefits of perennial rice cropping systems. Methods: To assess the soil nitrogen cycle and balance, formulate optimal N fertilizer management for perennial rice, a field experiment with four nitrogen rates (N0, N1, N2 and N3 refer to 0, 120, 180 and 240 kg N ha-1, respectively) integrated with three planting densities (D1, D2 and D3 refer to 100×103, 167×103 and 226×103 plants ha-1, respectively) was conducted for two years over four seasons (2016-2017) in southern China. Results: The results showed that N2D3 mode could sustainably produce higher dry matter accumulation (15.15 t ha-1) and grain yields (7.67 t ha-1) over four seasons, showed significantly higher N uptake (201 kg ha-1 each season) and less soil N loss (27.1%). Additionally, the N2D3 mode could reach the optimal N balance (-0.2 kg ha-1) in perennial rice fields with low N requirements (23.9 kg N Mg-1 grain), resulting in higher N use efficiency (NAE: 26.5 kg N kg-1, NRE: 64.9%). Conclusion: In the perennial rice cropping system, 180 kg N ha-1 integrated with 226×103 plants ha-1 resulted in higher grain yields with lower N requirements, higher N use efficiencies, and lower soil N losses, thereby maintaining the soil N balance for sustainable perennial rice production.

scholarly journals Nitrogen Uptake and Use Efficiency in Sweet Basil Production under Low Tunnels

HortScience ◽  
2020 ◽  
Vol 55 (4) ◽  
pp. 429-435 ◽  
Author(s):  
Tej P. Acharya ◽  
Mark S. Reiter ◽  
Greg Welbaum ◽  
Ramón A. Arancibia
Keyword(s):  
Open Field ◽  
N Uptake ◽  
Dry Weight ◽  
N Fertilizer ◽  
Plant N Uptake ◽  
Available N ◽  
Sweet Basil ◽  
Total Plant ◽  
Use Efficiency ◽  
Low Tunnels

Low tunnels (LTs) enhance vegetative growth and production in comparison with open field, but it is not known whether nitrogen (N) requirements and use efficiency increase or decrease for optimal crop performance. Therefore, the purpose of this study was to determine differences in N requirement, uptake, and use efficiency in basil grown under LTs compared with open field. The experimental design each year was a split plot with four replications. The main effect (plots) was N fertilizer application rate (0, 37, 74, 111, 148, and 185 kg·ha−1) and the secondary effect (subplots) was production system (LTs covered with spun-bonded rowcover vs. open field). Plant height and stem diameter were greater under LT than open field; however, they were unaffected by N fertilizer rate. Total fresh and dry weight increased with LT by 61% and 58% and by 50% and 48% in 2017 and 2018, respectively. Optimum N rates for fresh weight (98% of peak yield) were 124 and 104 kg·ha−1 N under LT and open field, respectively. Leaf N concentration decreased under LT, but total plant N uptake increased because of increased dry weight. Without fertilization, soil available N use efficiency (SNUE) for dry weight increased by 45% and 66% in 2017 and 2018, respectively. Mixed results were obtained for N fertilizer use efficiency (NFUE) in response to N rate. In conclusion, LT increased summer production of sweet basil, total plant N uptake, and SNUE.

Water and Nitrogen Budget Dynamics for a Maize-Peanut Rotation in Florida

2020 ◽  
Vol 63 (6) ◽  
pp. 2003-2020
Author(s):  
Maria I. Zamora Re ◽  
Sagarika Rath ◽  
Michael D. Dukes ◽  
Wendy Graham
Keyword(s):  
Crop Rotation ◽  
Root Zone ◽  
N Uptake ◽  
Irrigation Scheduling ◽  
N Fertilizer ◽  
N Leaching ◽  
Soil N ◽  
Fertilizer Rate ◽  
Irrigation Treatments ◽  
Fertilizer Rates

HighlightsDSSAT simulations of final N uptake, biomass, and yield for a maize-peanut rotational field experiment with three irrigation treatments and three N fertilizer rates had good performance for the irrigated treatments (average nRMSE of 9%) but greater error for the rainfed treatments (average nRMSE of 15%).Experiments and DSSAT simulations demonstrated that N fertilizer and irrigation applications were reduced by 26% and 60%, respectively, when using a 247 kg N ha-1 fertilizer rate and a sensor-based irrigation schedule rather than conventional practices of 336 kg N ha-1 and a calendar-based irrigation method, with no impact on yield.Simulations demonstrated that N leaching during the crop rotation was reduced by 37% when an N fertilizer rate of 247 kg N ha-1 and sensor-based irrigation scheduling were used versus conventional practices.Soil N increased (=15 mg kg-1) when maize and peanut residues decayed and then leached during the fallow season. Cover or cash crops planted immediately after the maize and peanut harvests have potential to take up this N and reduce leaching.Abstract. Nitrogen (N) is an essential element for crop growth and yield; however, excessive N applications not taken up by crops can result in N leaching from the root zone, increasing N loads to waterbodies and leading to a host of environmental problems. The main objective of this study was to simulate water and N balances for a maize-peanut (Zea mays L. and Arachis hypogaea L.) rotational field experiment with three irrigation treatments and three N fertilizer rates. The irrigation treatments consisted of mimicking grower irrigation practices in the region (GROW), using soil moisture sensors to schedule irrigation (SMS), and non-irrigated (NON). The N fertilizer rates were low, medium, and high (157, 247, and 336 kg N ha-1, respectively) for maize with a constant 17 kg ha-1 for all peanut treatments. DSSAT maize genetic coefficients were calibrated using the SMS-high treatment combination under the assumption of no water or N stress. The other eight treatment combinations were used as independent data for model validation of the crop coefficients. All soil hydrologic parameters were specified based on measured values, and default DSSAT peanut genetic coefficients were used with no calibration. For the irrigated treatments, DSSAT models had good performance for N uptake, biomass, and yield (average nRMSE of 8%) and moderate performance for soil water content (average nRMSE of 18%). Soil nitrate RMSE was 21% lower than the standard deviation of the observed data (5.8 vs. 7.2 mg kg-1). For the rainfed treatments, DSSAT had greater error (average nRMSE of 15% for N uptake, biomass, and yield, and average nRMSE of 31% for soil water). Soil nitrate RMSE was 11% greater than the standard deviation of the observed data (8.0 vs. 7.2 mg kg-1), and nRMSE was &gt;30% during the crop rotation. Simulations estimated that N leaching over the crop rotation was reduced by 24% on average when using the 247 kg N ha-1 fertilizer rate compared to 336 kg N ha-1 across the irrigation treatments. Furthermore, N leaching was reduced by 37% when using SMS to schedule irrigation and the 247 kg N ha-1 fertilizer rate for maize and 17 kg N ha-1 for peanut compared to conventional practices (GROW and 336 kg N ha-1 for maize and 17 kg N ha-1 for peanut). Moreover, this management practice reduced N fertilizer use by 26% and irrigation water use by up to 60% without negative impacts on yield. Observed and simulated soil N increased during maize and peanut residue decay, with simulations estimating that this soil N would leach below the root zone during the fallow season. This leaching could potentially be reduced if a cover crop or cash crop were planted between the maize and peanut crops to take up the mineralized N. Keywords: Agricultural best management practices, Bare fallow, BMPs, Maize-peanut rotation, N balance, N fertilization, N leaching, Sandy soils, Sensor-based irrigation scheduling, Water balance.

Nitrogen dynamics of chickpea: Effects of cultivar choice, N fertilization, Rhizobium inoculation, and cropping systems

2010 ◽  
Vol 90 (5) ◽  
pp. 655-666 ◽  
Author(s):  
Y. Gan ◽  
A M Johnston ◽  
J D Knight ◽  
C. McDonald ◽  
C. Stevenson
Keyword(s):  
Cicer Arietinum ◽  
Cropping Systems ◽  
N Uptake ◽  
N Fertilizer ◽  
The Other ◽  
N Balance ◽  
Rhizobium Inoculation ◽  
Use Efficiency ◽  
N Management ◽  
Fertilizer Rates

Understanding N dynamics in relation to cultural practices may help optimize N management in annual legume crops. This study was conducted at six environsites (location × year combinations) in southern Saskatchewan, 2004-2006, to quantify N uptake, N2 fixation, and N balance in chickpea (Cicer arietinum L.) in relation to cultivar choice, cropping systems, rhizobial inoculation, and soil N fertility. The cultivars Amit, CDC Anna, CDC Frontier, and CDC Xena were grown at N fertilizer rates of 0, 28, 56, 84, and 112 kg N ha-1 with no Rhizobium and at 0, 28, and 84 kg N ha-1 combined with Rhizobium inoculation, evaluated in both conventional tilled-fallow and continuously cropped no-till systems. Flax was used as a non-N-fixing reference crop. The cultivar CDC Xena had the lowest yield (1.57 Mg ha-1) and seed N uptake (54.4 kg N ha-1), with N use efficiency (NUE, 13.2 kg seed N kg-1) being 17% less than the average of the other cultivars. Consequently, N balance (N input via fertilizer and N-fixation minus N exported) was -32.4 kg N ha-1 for CDC Xena and less negative than the average of the other cultivars (-39.8 kg N ha-1). Inoculated chickpea took up 10 kg ha-1 more N into the seed and 5 kg ha-1 more N into the straw than chickpea that was not inoculated. The amount of N fixed as a percentage of total N uptake was 15% for non-inoculated chickpea and 29% for inoculated chickpea, resulting in negative N balance regardless of cropping system. Increasing N fertilizer rates decreased NUE, with the rate of decrease being greater for non-inoculated chickpea compared with inoculated chickpea. We conclude that optimum productivity of chickpea can be achieved with application of effective Rhizobium inoculants, and that best N management practices must be adopted in the succeeding crops due to a large negative N balance after a chickpea crop.Key words: Chickpea, Cicer arietinum, N fertilizer, N2 fixation, Rhizobium inoculants, N balance, nitrogen use efficiency, N uptake

Long-term partitioning of biomass and nitrogen following application of nitrogen fertilizer to Corsican pine

1992 ◽  
Vol 22 (1) ◽  
pp. 82-87 ◽  
Author(s):  
M.F. Proe ◽  
J. Dutch ◽  
H.G. Miller ◽  
J. Sutherland
Keyword(s):  
Linear Response ◽  
Growth Response ◽  
N Uptake ◽  
Indirect Evidence ◽  
Basal Area ◽  
N Fertilizer ◽  
Atmospheric Input ◽  
N Level ◽  
Internal Cycling

The effects of N fertilizer on Corsican pine (Pinusnigra var. maritima (Ait.) Melv.) were studied for 22 years. Basal area increment significantly (p < 0.05) increased in response to N fertilizer for 3, 6, 11, and 13 years after applications ceased, in treatments that received 252, 504, 1008, and 1512 kg N•ha−1, respectively. Volume increment changed from a quadratic to a linear response to N level during the study period. Overall, the highest rate of N fertilizer increased the aboveground standing biomass by 42%, four-fifths of which occurred in stems. The response of crown components was variable, but there was evidence of a prolonged increase in foliage biomass due to N fertilizer. Initial retention of N within stands was sustained in the longer term, although N distribution altered. These results supported earlier predictions that the growth response to N fertilizer could be sustained through internal cycling, without increasing demands for N uptake from the soil. Increase of N within stands (over and above fertilizer inputs) was similar to estimated rates of atmospheric input, with indirect evidence of a positive feedback between increased foliage biomass and increased levels of N interception by crowns.

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