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1.
While many water-saving rice production techniques have been adopted in China, the environmental effects of these techniques require further investigation. This study aims to assess nitrogen (N) and phosphorus (P) leaching losses under real conditions in different water and N managements. Two water and three N treatments are conducted in the Taihu Lake region of China. Results show that the total N leaching losses during the rice season under flooding irrigation (FI) are 12.4, 9.31, and 7.17 kg ha−1 for farmers’ fertilization practices (FFP), site-specific N management (SSNM), and controlled-release nitrogen fertilizer management (CRN), respectively. Under controlled irrigation (CI), the respective losses were 7.40, 5.86, and 3.79 kg ha−1 for the same management methods. The total P leaching losses during the rice season under FI were 0.939, 0.927, and 0.353 kg ha−1 for FFP, SSNM, and CRN, respectively. Under CI, the losses were 0.424, 0.433, and 0.279 kg ha−1, respectively, for the same management methods. Ammonium and nitrate N accounted for 42.2–65.5% and 11.8–14.7% of the total nitrogen leaching losses under different water and N management methods, respectively. Due to significant decrease of volumes of percolation water and nitrogen and phosphorus concentrations in percolation water, N and P leaching losses were reduced in the CI treatment compared to the FI treatment under the same N management. The reduction of N input and application of controlled-release nitrogen fertilizer can reduce N and P leaching losses from paddy fields.  相似文献   

2.
Polymer-coated urea (PCU) is an important alternative to uncoated urea for improving nitrogen (N) use efficiency (NUE). Only a few studies discuss their utility for lowland rice systems. A 2-year field study was conducted to examine if nitrogen loading is reduced in lowland rice ecosystem by using mixture of PCU and uncoated urea without sacrificing yield. Five treatments involving two mixtures of PCU with 50 and 70% coated urea each at 70 and 50% of recommended dose (80 kg N ha−1) and one with uncoated urea at 100% recommended dose were laid out in a completely randomized design. Selected plant growth parameters and plant available N contents (NH4–N plus NO3–N) in soil solution and ponded water were measured over a period of 65 days after transplanting. Results showed no significant difference for vegetative and yield parameters among different treatments suggesting that treatments receiving lower doses of nitrogen exhibited higher NUE. Analysis of partial factor of productivity (PFP) for N suggested that the total N dose may be reduced by 50% using mixtures of coated and uncoated urea. Similarly, statistically similar PFP values for treatments receiving the same amount of total N for both years and for both total N dose suggested that the proportion of coated urea may also be reduced to as low as 50% without sacrificing yield. Correlation analysis on nitrogen contents in ponded water and soil solutions and the analysis of water productivity and PFP showed that soil water regime could also significantly influence the nitrogen status in soil even when PCU are applied. In turn, both the water regime and N contents in soil ultimately influences grain yield. Although the constant release of N from coated fertilizer ensures adequate N supply for plant uptake, it may not completely avoid N deficit condition especially during heavy rainfall. Analysis of the developed production function suggested that 55–65% polymer coating and about 100 cm total water input may be ideal for achieving maximum yield. The production function was developed for PCU treatments using data observed in treatments receiving 70% recommended N dose. The range of water input in these treatments was 86.5–174.0 cm.  相似文献   

3.
The present study was carried out to evaluate nutrient losses that occur during the course of agricultural activity from rice paddy fields of reclaimed tidal flat. For this study, we chose a salt-affected rice paddy field located in the Saemangeum reclaimed tidal area, which is located on the western South Korean coasts. The plot size was 1,000 m2 (40 m × 25 m) with three replicates. The soil belonged to the Gwanghwal series, i.e., it was of the coarse silty, mixed, mesic type of Typic Haplaquents (saline alluvial soil). The input quantities of nitrogen and phosphorus (as chemical fertilizer) into the experimental rice paddy field were 200 kg N ha−1 and 51 kg P2O5 ha−1 per annum, and the respective input quantities of each due to precipitation were 9.3–12.9 kg N ha−1 and 0.4–0.7 kg P ha−1 per annum. In terms of irrigation water, these input quantities were 4.5–8.2 kg N ha−1 and 0.3–0.9 kg P ha−1 per annum, respectively. Losses of these nutrients due to surface runoff were 22.5–38.1 kg N ha−1 and 0.7–2.2 kg P ha−1 for the year 2003, and 26.8–29.6 kg N ha−1 and 1.6–1.9 kg P ha−1 for the year 2004, respectively. Losses of these nutrients due to subsurface infiltration during the irrigation period were 0.44–0.67 kg N ha−1 and 0.03–0.04 kg P ha−1 for the year 2003, and 0.15–0.16 kg N ha−1 and 0.05–0.06 kg P ha−1 for 2004. When losses of nitrogen and phosphorus were compared to the amount of nutrients supplied by chemical fertilizers, it was found that 11.3–19.1% of nitrogen and 0.5–1.7% of phosphorus were lost via surface runoff, whereas subsurface losses accounted to 0.2–0.8% for nitrogen and only 0.02–0.04% for phosphorus during the 2-year study period.  相似文献   

4.
为探究控释氮肥施用策略对稻茬小麦产量和氮肥吸收利用的影响,在大田条件下,以小麦品种扬麦16和扬麦20为材料,设置不施氮(T1)、常规速效氮肥分次施用(T2,对照)、常规控释氮肥一次性基施(T3)、速效氮肥减量分次施用(T4)、控释氮肥减量一次性基施(T5)、控释+速效氮肥一次性基施(T6)、控释+速效氮肥配合分次施用(T7)共7种氮肥处理,比较分析了不同处理下稻茬小麦产量、叶面积指数(LAI)、叶绿素相对值(SPAD值)、干物质积累量、氮素积累量、根系吸收面积和根系氧化力等性状的差异。结果表明,两个品种的产量均表现为T6>T7>T3>T5>T2>T4>T1。与T2处理相比,两个品种的平均产量在T3、T6和T7处理下分别增加17.9%、30.3%和25.1%,平均氮肥农学效率(AE)分别增加40.0%、84.8%和72.4%,平均氮肥偏生产力(PFP)分别增加22.2%、52.3%和45.6%。与单一施用速效氮肥(T2、T4)或控释氮肥(T3、T5)处理相比,在控释氮肥与速效氮肥配施(T6、T7)处理下两个品种的地上部农艺性状(干物质积累量、LAI和SPAD值)显著改善,氮素积累量、根干重、根冠比、根系氧化力、根系总吸收表面积和活跃吸收表面积均显著增加。因此,控释氮肥配施速效氮肥策略可以同步促进稻茬小麦地上部与地下部生长,最终实现高产与氮肥高效吸收利用。  相似文献   

5.
Promising results from an increasing number of field evaluations of the System of Rice Intensification (SRI) conducted in Asia and Africa indicate that African farmers could increase their rice production while lowering costs of operation and reducing the need for water by utilizing its principles and practices. This system relies not on external inputs to raise productivity but on alternative methods for managing rice plants and the soil and water resources devoted to their cultivation. Farmers in sub-Saharan Africa increasingly have to cope with the impacts of adverse climate effects because water shortages and long dry spells during the cropping season are becoming common, even in lowland rice agroecosystems. SRI management practices create both larger rice root systems that make their plants more resistant to biotic and abiotic stresses and more conducive environments for beneficial soil microflora and fauna to flourish. Better plant growth and development result from promoting plant–soil synergies. Controlled fertilizer management experiments conducted with SRI practices in The Gambia have showed that grain production can be significantly increased without higher application of inorganic fertilizer and with less requirement for water. SRI management practices with fertilizer application at the national recommended dose produced a grain yield of 7.6 t ha−1. Water productivity was greatly increased, with 0.76 g of grain produced per kg total water input, compared to 0.10 g of grain per kg of water when the crop was continuously flooded. Recent hikes in fuel prices and consequent rises in input costs are making domestic rice production less attractive and importation even more attractive. Computation of production costs showed that SRI production, not needing heavy applications of fertilizer, is economically cost-effective. Achieving yield increases through ever-higher fertilizer applications is not economically or environmentally viable. SRI management with recommended fertilizer applications produced a net return of $853 ha−1 compared to $853 ha−1 compared to 37 when using farmers’ present low-productivity practices.  相似文献   

6.
Kahokugata Lake, a closed lake, has been subject to eutrophication. This research was conducted to clarify the actual phenomena and evaluation of the discharges of N and P from paddy test fields in the lowlands into Kahokugata Lake. A comprehensive mass balance of N and P was obtained from 4 years of study. About N, the mean value of harvested unhulled rice (79.9 kg/ha) was greater than mean controlled release fertilizer inputs (56.7 kg/ha). Other inputs and outputs include N in atmospheric acid deposition (21.4 kg/ha) and N fixation–denitrification (9.2 kg/ha). The rice straw recycled after harvest was balanced by straw produced in the succeeding year. The runoff and percolation losses discharged into the lake was 11.3 kg/ha, (8.6% of total inputs). Since the rice harvested was consumed domestically, which taking out from the farmland and, therefore, nitrogen pollutant into the lake was becoming small, paddy rice at this site is considered an “anti-polluting, purifying or cleansing” crop. The P content in harvested rice (39.4 kg/ha) was balanced by fertilizer inputs (36.4 kg/ha). Previous studies examining inflow–outflow relationships without considering a comprehensive mass balance may lead to erroneous conclusions. Our findings indicate paddy rice in lowlands could be an environmentally friendly crop and can play an important role in reducing pollution of lakes, and therefore should be considered in land use planning.  相似文献   

7.
通过两年田间试验,研究覆膜滴灌等磷量投入条件下,不同施用时期及比例(P1,100%基肥;P2,40%基肥+60%拔节肥;P3,40%基肥+40%拔节肥+20%大喇叭口肥;P4,40%基肥+20%拔节肥+20%大喇叭口肥+20%开花肥)对玉米产量、物质生产与磷素吸收利用的影响。结果表明,分次施磷处理(P2、P3、P4)玉米产量均高于P1处理,P4处理玉米产量与P1处理差异达显著水平(P0.05)。施磷显著提高玉米吐丝期至成熟期干物质量和磷素吸收量,吐丝期干物质量与磷素吸收量以P1处理最高,灌浆期至成熟期干物质量与磷素吸收量以P4处理最高。  相似文献   

8.
This paper describes the impact of rice hydraulic loading (percentage area under rice crop) on groundwater levels and salinity in the Murrumbidgee irrigation area (MIA), Australia using a MODFLOW-based modelling approach. The model simulations show that the groundwater levels will be in equilibrium after a fall of approximately 1 m under most of the areas, however, the groundwater salinity levels will rise by more than 1,000 μs/cm in most parts of irrigation area. If the rice growing area is reduced by 50 and 75%, there can be a net decline in groundwater levels during the first 2 years and then a new quasi-equilibrium will be established. To downscale these results at the farm level, SWAGMAN Farm model in conjunction with groundwater outflow rates obtained from a three-dimensional MODFLOW model was applied for determining net recharge rates under rice for different areas within the MIA. The highest net recharge during 2005–2006 season was 0.84 ML/ha (84 mm) in parts of the irrigation system, whereas the average net recharge due to rice hydraulic loading for the whole MIA during 2005–2006 season was estimated as 0.34 ML/ha (34 mm).  相似文献   

9.
Cultivation of forage rice for whole-crop silage has been increasing in Japan and will be important in Asia. In this study, effects of cultural practices on growth and yield of a forage rice cultivar “Tsukisuzuka” having short panicle 1 allele were analysed quantitatively using linear mixed model. The contribution of basal dressing to dry yield per 1 g/m2 nitrogen fertilizer was larger than that of topdressing. In addition, topdressing 30 and 20 days before heading was considered to have the disadvantage of increasing risk of lodging and panicle weight respectively. Effects of weather elements on growth of forage rice were also speculated. In tested fields, high solar radiation at seedling and tillering stage was considered important for the high yield. As the number of continuous cropping cycles increased, growth of forage rice got worse. And application of compost improved growth of forage rice. Elemental analysis of soil and plants revealed that this continuous cropping obstacle was likely to attributed to deficiency of potassium. In addition, potassium deficiency increased panicle weight of a forage rice cultivar having short panicle 1 allele. Therefore, control of potassium nutrition will be useful for both sustaining productivity (sufficient application of potassium) and seed production (restriction of potassium). These findings will be useful for improvement of cultivation method of forage rice.  相似文献   

10.
《Field Crops Research》2005,91(1):71-81
Wheat (Triticum aestivum L.) cultivation in no-till soil of a postrice harvest field utilizes residual soil moisture and reduces the time period from rice harvest to wheat seeding in intensive rice-wheat cropping systems. Some of the major constraints in no-till wheat production are high weed infestation, poor stand establishment due to rapid drying of topsoil and low nitrogen use efficiency (NUE). A field experiment was conducted at the research farm of the Wheat Research Centre, Dinajpur, Bangladesh, for two consecutive years to overcome those constraints, to evaluate rice straw as mulch, and to determine the optimum application rate of nitrogen (N) for no-till wheat. The treatments included 12 factorial combinations of three levels of mulching: no mulch (M0), surface application of rice straw mulch at 4.0 Mg ha−1 that was withdrawn at 20 days after sowing (M1), the same level of mulch as M1 but allowed to be retained on the soil surface (M2), and four nitrogen levels (control 80, 120 and 160 kg ha−1). Rice straw mulching had a significant effect on conserving initial soil moisture and reducing weed growth. Root length density and root weight density of wheat were positively influenced both by straw mulching and N levels. N uptake and apparent nitrogen recovery of applied N fertilizer were higher in mulch treatments M1 and M2 as compared to M0. Also mulch treatment of M1 and M2 were equally effective at conserving soil moisture, suppressing growth of weed flora, promoting root development and thereby improved grain yield of no-till wheat. N application of 120 kg ha−1 with straw mulch was found to be suitable for no-till wheat in experimental field condition.  相似文献   

11.
Deep placement of urea supergranules (USG) in transplanted rice cultivation can protect nitrogen from losses. In the 20 × 20 cm plant geometry, the 4 g urea application corresponds to 116 kg N ha−1. However, the ammoniacal nitrogen concentration at the placement sites increases as the mass of the USG increases, and with the 4 g USG it takes too long for the ammonia concentration to decrease to 10 mM, the concentration at which root uptake commences. Therefore, split applications (two applications of 2 g USG) were studied regarding the change of ammoniacal nitrogen concentration at the point of application. The first application was always at transplanting, at a depth of 10 cm; the second application was made 41 days after transplanting (DAT) (tillering stage) or 62 DAT (panicle initiation). These times correspond to the beginning or the end of ammonia disappearance (plant uptake) from the site of placement, respectively. Ammonia disappearance from the placement site is faster for the second application, and it appears that the rice roots took up ammonia at a higher concentration: 20 mM for the second application versus 10 mM for the first application. The kinetics of ammonia disappearance from a single application of 2 g granules at transplanting was also influenced by the PK application rate. The rate of ammonia disappearance, the number of tillers per hill, and grain yield all increased with PK rate. The constant which characterizes the first order rate of ammonia disappearance below 10 mM also increased with PK level, proportionally to the number of tillers.  相似文献   

12.
The presence of arsenic in irrigation water and in paddy field soil were investigated to assess the accumulation of arsenic and its distribution in the various parts (root, straw, husk, and grain) of rice plant from an arsenic effected area of West Bengal. Results showed that the level of arsenic in irrigation water (0.05–0.70 mg l−1) was much above the WHO recommended arsenic limit of 0.01 mg l−1 for drinking water. The paddy soil gets contaminated from the irrigation water and thus enhancing the bioaccumulation of arsenic in rice plants. The total soil arsenic concentrations ranged from 1.34 to 14.09 mg kg−1. Soil organic carbon showed positive correlation with arsenic accumulation in rice plant, while soil pH showed strong negative correlation. Higher accumulation of arsenic was noticed in the root (6.92 ± 0.241–28.63 ± 0.225 mg kg−1) as compared to the straw (1.18 ± 0.002–2.13 ± 0.009 mg kg−1), husk (0.40 ± 0.004–1.05 ± 0.006 mg kg−1), and grain (0.16 ± 0.001–0.58 ± 0.003 mg kg−1) parts of the rice plant. However, the accumulation of arsenic in the rice grain of all the studied samples was found to be between 0.16 ± 0.001 and 0.58 ± 0.003 mg kg−1 dry weights of arsenic, which did not exceed the permissible limit in rice (1.0 mg kg−1 according to WHO recommendation). Two rice plant varieties, one high yielding (Red Minikit) and another local (Megi) had been chosen for the study of arsenic translocation. Higher translocation of arsenic was seen in the high yielding variety (0.194–0.393) compared to that by the local rice variety (0.099–0.161). An appreciable high efficiency in translocation of arsenic from shoot to grain (0.099–0.393) was observed in both the rice varieties compared to the translocation from root to shoot (0.040–0.108).  相似文献   

13.
The effects of different nitrogen application levels on nutrient uptake and ammonia volatilization were studied with the rice cultivar Zheyou 12 as a material.The accumulative amounts of nitrogen,phosphorus and potassium in rice plants across all growth stages showed a trend to increase with increasing nitrogen application levels from 0 to 270 kg/hm 2,but decreased at nitrogen application levels exceeding 270 kg/hm 2.Moreover,the accumulative uptake of nitrogen,phosphorus and potassium by the rice plants was increased by application of organic manure in combination with 150 kg/hm 2 nitrogen.The nitrogen uptake was high during the jointing to heading stages.Correlation analysis showed that rice yield was positively correlated with the accumulative uptake of nitrogen,phosphorus and potassium by the rice plants.The highest correlation coefficient observed was between the amount of nitrogen uptake and rice yield.The rate and accumulative amounts of ammonia volatilization increased with increasing nitrogen fertilizer application level.Compared with other stages,the rate and accumulative amount of ammonia volatilization were higher after base fertilizer application.The ammonia volatilization rates in response to the nitrogen application levels of 270 kg/hm 2 and 330 kg/hm 2 were much higher than those in the other treatments.The loss of nitrogen through ammonia volatilization accounted for 23.9% of the total applied nitrogen at the nitrogen application level of 330 kg/hm 2.  相似文献   

14.
Optimum rate and timing application of nitrogen (N) fertilizer are most crucial in achieving high yield in irrigated lowland rice. In order to assess leaf N status, a semidwarf rice cultivar (Khazar) was grown with different N application treatments (0, 40, 80, and 120 kg N ha−1 splited at transplanting, midtillering, and panicle initiation stages) in a sandy soil in Guilan Province, Iran, in 2003. The chlorophyll meter (SPAD 502) readings were recorded and leaf N concentrations were measured on the uppermost fully expanded leaf in rice plants at 10-day internals from 19 days after transplanting to grain maturity. Regression analysis showed that the SPAD readings predicted only 23% of changes in the leaf N concentration based on pooled data of leaf dry weight (N dw) for all growth stages. However, adjusting the SPAD readings for specific leaf weight (SPAD/SLW) improved the estimation of N dw, up to 88%. Specific leaf weight (SLW), SPAD readings, leaf area and weight as independent variables in a multiple regression analysis predicted 96% of the N dw changes, while SPAD readings independently predicted about 80% of leaf N concentration changes on the basis of leaf area (N a). It seems that chlorophyll meter provides a simple, rapid, and nondestructive method to estimate the leaf N concentration based on leaf area, and could be reliably exploited to predict the exact N fertilizer topdressing in rice.  相似文献   

15.
Seven years of performance data from a free surface flow constructed wetland system receiving agricultural runoff were used to determine treatment performance and to develop regression and wetland design models. Removal rates by the wetland were 21–43.6% for 5-day biochemical oxygen demand (BOD5), 49.0–58.1% for total phosphorous (TP), 24.1–46.0% for total nitrogen (TN), and 57.6–77.8% for total suspended solids (TSS). First-order area-based rate constant (k 20) values for BOD5 were 15.48 m/year in the early stage of observation and decreased to 12.00 m/year for the stable period. Similar results were found for TP, for which k 20 values were 18.72 m/year in the early stage and 14.92 m/year for the stable period. For TN, k 20 values in the early stage (21.32 m/year) were slightly lower than those for the stable period (38.02 m/year). Finally, TSS had values of 132.4 and 172.6 m/year in the early and stable periods, respectively. The low k 20 for BOD5 was not important for nonpoint source pollution control in the constructed wetland because these kinds of wetlands mainly focus on nitrogen and phosphorus retention. The wetland area and outlet concentration could be approximately predicted using the first-order kinetic model, but the maturity and hydraulic loading rate should be considered for more accurate prediction.  相似文献   

16.
缓/控释肥对双季稻产量和氮素利用率的影响   总被引:13,自引:0,他引:13  
为明确缓/控释肥(slow/controlled-release fertilizer,CRF)在水稻上的应用效果,连续2年在南方双季稻区第四纪红壤发育的水稻土上进行双季稻大田试验,比较了不施氮肥(CK)、推荐分3次施肥(OF)、一次性基施缓/控释肥(100CRF)和一次性基施80%缓/控释肥(80CRF)条件下,双季稻的产量形成、氮素吸收和利用的差异。结果表明,2年4季产量平均表现为80CRF100CRFOFCK,其中80CRF、100CRF和OF分别比CK增产25.32%、23.93%和22.54%(P0.05),而各施氮处理间无显著差异;2年籽粒平均吸氮量中,早稻100CRF、80CRF处理均显著高于OF处理(P0.05),晚稻100CRF处理显著高于OF处理(P0.05),但80CRF处理与OF无显著差异,秸秆吸氮量与籽粒一致。100CRF、80CRF处理下氮肥吸收利用率均显著高于OF处理(P0.05);氮肥农学利用率、氮肥偏生产力以80CRF最高,显著高于100CRF和OF处理(P0.05);2012年晚季80CRF的氮肥生理利用率、土壤氮素依存率最高,显著高于100CRF处理(P0.05),2013年早晚稻均以OF处理最高,显著高于100CRF处理(P0.05);2年定位试验中的80CRF处理与OF处理氮素生理利用率无显著差异。因此,一次性施用缓/控释肥产量水平与推荐分次施肥水平相当,但施用缓/控释肥能显著提高水稻氮素吸收量和含量。全量施缓/控释肥虽能提高早晚稻氮肥吸收利用率,但氮素生理利用率降低;在推荐施肥的基础上减量20%施用缓/控释肥的早晚稻氮肥吸收利用率、农艺利用率、偏生产力均显著提高,氮肥生理利用率与推荐施肥无差异;即在稳产的基础上,提高了氮素的利用效果,是值得推荐的施肥方式。  相似文献   

17.
《Field Crops Research》1999,61(2):147-162
In irrigated rice production in West Africa, nitrogen (N) and phosphorus (P) fertilizers make up about 20% of total production costs. This research seeks to evaluate whether those fertilizers are profitable under current use by farmers and to identify the factors that may improve fertilizer efficiency and profitability. A combination of farmer surveys and on-farm trials were used to determine actual fertilizer use, costs, and net revenues from fertilizer in key irrigated systems in Mali (Office du Niger), Burkina Faso (Kou Valley), and Senegal (Thiagar and Guédé). A second paper provides an agronomic analysis of soil fertility management at these sites. Net returns to fertilizer use were estimated and value/cost ratios (VCRs) calculated. A value/cost ratio of 1.5–2.0 was considered desirable for farmer adoption under West African conditions. Average VCRs for fertilizers ranged from 1.6 in the Kou Valley in Burkina Faso, to 3.6 in the Office du Niger, Mali. In researcher-managed on-farm trials in Thiagar, Senegal, fertilizers had VCRs of 1.5–3.1. Large N doses of 180 kg N ha−1 still had VCRs of 2.5. Farmers in the region used less than recommended doses of N, with the exception of farmers in the Office du Niger, Mali. With an average application of 89 kg N ha−1, farmers in Thiagar, Senegal were able to gain 54 000 FCFA ha−1 (US$ 110) of net revenues from the fertilizers with fertilizer N recovery rates averaging 34%. Improving that recovery rate by 50% could increase net revenues by 50%. In field trials in Thiagar, increasing N application to 180 kg ha−1 resulted in net returns of near 200 000 FCFA ha−1 for an investment of 118 000 FCFA ha−1. Risk of negative net returns was found in Thiagar and in Kou Valley, and was related to weed infestation and water scarcity, respectively. Farmers in the dry season in Kou Valley had a 33% probability of net losses with fertilizer application because of unreliable water supply. In contrast, no farmers had negative returns in the Office du Niger inspite of high N application rates. Farmers can improve profitability and economic efficiency in irrigated rice production in two ways. First, they can modify crop management practices (date of seeding, date and mode of fertilizer application, etc.) in order to improve the recovery rate of applied N, thus relaxing the nitrogen fertilizer constraint. Second, for farmers able to purchase additional fertilizer, there are gains to be made by increasing applied nitrogen at least to recommended levels in most areas. Credit allocations that restrict fertilizer purchases are counterproductive given the profitability of fertilizers. Negative returns were found only in areas with high risks of water scarcity or weed infestation. Researchers and development agents need to develop more site-specific fertilizer recommendations that correspond to weather, cultivars, prices of inputs and outputs, and fertilizer products.  相似文献   

18.
不同施氮量对单季稻养分吸收及氨挥发损失的影响   总被引:4,自引:0,他引:4  
 以杂交晚粳浙优12为材料,研究了不同氮素用量对单季晚稻养分吸收和氨挥发损失的影响。结果表明,施氮量在0~330  kg/hm2范围内水稻植株氮积累量、磷积累量及钾积累量均表现为随施氮量的增加而增加,施氮水平超过270  kg/hm2后增施氮肥反而降低水稻对氮磷钾的吸收。施氮量在150  kg/hm2时增施有机肥有助于杂交粳稻浙优12对土壤中氮素、磷素以及钾素的吸收利用。水稻拔节期至抽穗期为吸氮量最大时期,施氮量在0~270  kg/hm2范围内杂交粳稻浙优12各生育期植株氮积累量随着施氮量增加而增加。相关分析表明,水稻产量与水稻植株全生育期氮积累量、磷积累量和钾积累量极显著正相关,其中,与水稻吸氮总量的相关系数最大。氨挥发速率、累计氨挥发量随施氮量的增加而增加,以施用基肥阶段氨挥发速率最快,累计氨挥发量最高。在基肥氮肥和分蘖肥氮肥施入后,高施肥水平(270  kg/hm2、330  kg/hm2)下氨挥发速率均远高于其他处理,其中,施氮量330  kg/hm2处理施基肥后测得的累计氨挥发量占基肥施氮量的23.9%。  相似文献   

19.
【目的】为解决水稻土壤保肥能力较弱,水稻产量较低,氮肥利用效率不高等问题,【方法】于山东省济宁市任城区水稻田设置氮肥水平与栽植密度双因素大田试验,设4个施氮量水平,即无氮(N1,0 kg/hm2)、低氮(N2,216 kg/hm2)、中氮(N3,288 kg/hm2)和高氮(N4,360 kg/hm2);栽植密度设3个梯度,即低密度(24万穴/hm2)、中密度(27万穴/hm2)和高密度(30万穴/hm2)。以探究不同氮肥水平和栽植密度下水稻成熟期土壤养分含量及氮肥利用效率的变化。【结果】随着土层加深,氮、磷、钾、有机质含量均明显下降。其中D3N4处理碱解氮含量下降了60.8%,D3N3处理速效磷含量降低了72.7%。随着施氮量增加,土壤pH值和有机质含量有所下降,速效钾含量升高,肥料偏生产力和氮肥农学利用效率降低,产量先升高后降低;随着栽植密度增加,土壤pH值与速效磷含量有所下降,表层土壤碱解氮含量略有升高,有机质含量与产量及肥料偏生产力均先升高后降低,氮肥农学利用效率降低。【结论】当栽植密度为27万穴/hm2时,氮肥用量288 kg/hm2,水稻产量最高,为14 615.3 kg/hm2;相同密度下氮肥按照216 kg/hm2施用,水稻产量、氮肥农学效率和肥料偏生产力均较高。研究结果可在实际生产中参考应用。  相似文献   

20.
A field experiment using system of rice intensification (SRI) techniques was conducted in Chiba, Japan during the 2008 rice-growing season (May–September) with eight treatment combinations in a split–split plot design (S–SPD) to observe the potential of SRI methods under the temperate climatic conditions in Japan. Intermittent irrigation with alternate wetting and drying intervals (AWDI) and continuous flooding throughout the cropping season were the two main-plot factors, while the effects of age of seedlings and plant spacing were evaluated as sub and sub–sub plot factors, respectively. The experiment results revealed that the proposed AWDI can save a significant amount of irrigation water (28%) without reduced grain yield (7.4 t/h compared with 7.37 t/h from normal planting with ordinary water management). Water productivity was observed to be significantly higher in all combinations of practices in the intermittent irrigation plots: 1.74 g/l with SRI management and AWDI as compared to 1.23 g/l from normal planting methods with ordinary water management. In addition, the research outcomes showed a role of AWDI in minimizing pest and disease incidence, shortening the rice crop cycle, and also improving plant stand until harvest. Synergistic effects of younger seedlings and wider spacing were seen in tillering ability, panicle length, and number of filled grains that ultimately led to higher productivity with better grain quality. However, comparatively better crop growth and yields when using the same SRI practices with ordinary water management underscore a need for further investigations in defining what constitute optimum wetting and drying intervals considering local soil properties, prevailing climate, and critical watering stages in rice crop management.  相似文献   

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