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1.
氮素调控剂对不同类型土壤氮素转化的影响   总被引:1,自引:1,他引:0  
刘建涛  许靖  孙志梅  崔少雄  王雪   《生态学杂志》2014,25(10):2901-2906
采用室内培养试验方法,比较了硝化抑制剂双氰胺(DCD)和3,5-二甲基吡唑(DMP)对华北平原两种主要土壤类型潮褐土和潮土中氮素转化的调控效果,并进一步研究了DMP与脲酶抑制剂氢醌(HQ)的配合施用对潮土中氮素转化的影响.结果表明: 在两种供试类型土壤上DMP对尿素氮的硝化抑制作用均强于DCD.与单施尿素相比,在氮素转化高峰时,DMP可使土壤中NH4+-N含量显著提高149.5%~387.2%,NO3--N含量降低22.3%~55.3%;同一抑制剂对潮土中氮素转化的调控效应较潮褐土更为明显;与DMP单施相比,DMP和HQ配施表现出明显的对氮素转化的协同抑制效果.
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2.
土壤硝化作用的抑制剂调控及其机理   总被引:18,自引:0,他引:18  
既要保证氮肥在优质高效农业生产中的促进作用,又要保证农业和环境的可持续发展,如何提高氮肥利用率、减轻氮肥污染成了解决问题的关键.从氮素在土壤中的生物化学转化过程入手,通过抑制剂的施用来调控氮素的转化,减缓硝化过程的进行,是解决该问题的一种有效措施.本文从硝化抑制剂的定义、筛选硝化抑制剂的条件、国内外较受关注的硝化抑制剂品种以及硝化抑制机理等几个方面对目前的研究进展进行综述,并提出目前研究中存在的问题及今后的研究方向.  相似文献   

3.
长效肥料ENTEC对野生刺苋驯化栽培的影响   总被引:2,自引:0,他引:2  
探讨了含有硝化抑制剂DMPP(3,4-二甲基吡唑磷酸盐)的长效肥料ENTEC对剌苋(Amaranthus spinosus L.)干物质积累及其氮素利用的影响. 结果表明: 与尿素处理相比,ENTEC对提高剌苋干物质积累作用不明显,其最大生长速率出现时间较晚; 施用ENTEC,土壤含氮量较高,且下降速度较慢,说明其具有较强的防止氮素流失的作用.同时,ENTEC有利于提高氮素的利用率,ENTEC处理的植株氮素利用率比尿素处理提高了41.56%.另外,ENTEC能促进剌苋对磷、钾素的吸收.  相似文献   

4.
3,5-二甲基吡唑磷酸盐(DMPZP)对土壤硝化作用的影响   总被引:3,自引:0,他引:3  
采用好气培养法,以双氰胺(DCD)为参比对象研究了新型吡唑类硝化抑制剂3,5-二甲基吡唑磷酸盐(DMPZP)对土壤硝化作用的影响.结果表明,DMPZP对土壤中的铵氧化作用有较强的抑制效果,在施用量为1.0%(纯N含量)时能显著提高土壤中的NH4+-N浓度,降低NO3--N浓度.DMPZP的硝化抑制效应随用量的增加而增强,相同质量的DMPZP的硝化抑制效果不及DCD,而DCD又不及2倍质量的DMPZP,但等摩尔数(物质量)的DMPZP硝化抑制效果明显优于DCD. DMPZP在施用后的第7天至第14天的硝化抑制作用最强,与不添加抑制剂的处理相比,DMPZP添加量为1.0%和2.0%(纯N含量)时的表观硝化率在第7天和第14天分别降低了29.3%、41.7%和18.6%、34.3%;在此期间,添加DMPZP处理的硝化抑制率均高于30%.DMPZP的施用还可减缓土壤pH的降低速率,但施用DMPZP和DCD对土壤pH的影响差异不显著.  相似文献   

5.
通过田间试验研究了含硝化抑制剂DMPP复合肥对日光温室芹菜生长和品质的影响. 结果表明,与普通复合肥相比,一次基施DMPP复合肥67.5和54.0 kg·hm-2 氮处理分别使芹菜增产5.78%和10.14%; DMPP复合肥可降低芹菜可食部分硝酸盐含量,提高Vc、游离氨基酸、可溶性糖及氮、磷含量. 与分次施用相比,适当减少DMPP复合肥施用次数和用量可提高芹菜产量并改善其品质,降低生产成本.DMPP复合肥在施入土壤中后具有显著的硝化抑制作用,延缓了菜地土壤铵态氮向硝态氮的转化,降低了氮素向水体迁移的风险.芹菜收获后土壤中全氮、铵态氮、硝态氮残留较多,有利于保持地力.  相似文献   

6.
盐渍化对农田氮素转化过程的影响机制和增效调控途径   总被引:1,自引:0,他引:1  
本文在回顾我国盐渍化农田氮肥利用现状的基础上,总结了盐渍化对农田土壤氮素转化关键过程的影响规律,剖析了其对参与氮素转化的微生物的作用机制,归纳了盐渍化农田氮素养分增效调控的主要途径。盐渍化对农田土壤氮素矿化、硝化和反硝化过程存在阈值效应,不同范围内影响差别较大。盐分以及次生障碍对相关微生物也具有不同的影响,且同样存在阈值效应。目前盐渍化农田氮素增效调控的途径主要包括土壤改良剂改良、生物质材料改良、种植耐盐植物、优化氮素形态配比和生物抑制剂改良,最后提出盐渍化农田氮素循环过程研究目前存在的不足以及未来的研究方向。本文对盐渍化农田氮素减损增效、化肥养分高效利用与农业面源污染阻控具有重要指导意义。  相似文献   

7.
高效稳定性硫酸铵氮肥在黑土中的施用效果   总被引:1,自引:0,他引:1  
为筛选高效稳定性氮肥,采用盆栽试验,通过监测施用不同处理的稳定性硫酸铵对黑土铵态氮和硝态氮含量、表观硝化率、硝化抑制率、玉米生长指标、产量和氮素效率等指标的影响,研究添加不同生化抑制剂配方的稳定性硫酸铵态氮肥在吉林黑土玉米栽培中的施用效果。本试验以不施氮肥(CK)和施硫酸铵(N)为对照,在硫酸铵中分别添加硝化抑制剂3,4-二甲基吡唑磷酸盐(DMPP)、2-氯-6-三甲基吡啶(CP),氮保护剂(N-GD)和肥料增效剂(HFJ)及其组合,制成9种稳定性硫酸铵氮肥。结果表明: 与单施硫酸铵氮肥处理相比,在黑土中添加DMPP和DMPP组合显著影响土壤中铵态氮和硝态氮含量及土壤表观硝化率,铵态氮含量提高1.4~2.0倍,硝态氮含量降低13.6%~17.9%,土壤表观硝化率降低55.3%~59.8%;添加DMPP、DMPP+HFJ和DMPP+N-GD组合硝化抑制率最高,达到16.5%以上;添加DMPP+HFJ+N-GD和HFJ的硫酸铵处理玉米叶片叶绿素含量增加最显著,增加4.5~5.3倍;硫酸铵添加硝化抑制剂和肥料增效剂对株高无显著影响;添加HFJ的硫酸铵处理玉米生物量、籽粒产量、经济系数、收获指数、氮肥农学利用率、氮素吸收利用率、肥料贡献率和氮肥偏生产力增加最显著,分别增加1.2、2.5、0.7、0.6、2.7、2.1、1.3和2.5倍。添加HFJ和DMPP、DMPP+HFJ、DMPP+N-GD处理的硫酸铵处理在黑土中施用效果最好,但是DMPP成本较高,因此,兼顾成本和氮肥利用率,建议稳定性硫酸铵态氮肥生化抑制剂首选氮肥增效剂HFJ,其次选择DMPP+HFJ或者DMPP+N-GD。  相似文献   

8.
采用静态暗箱-气相色谱法,研究施用生物炭与添加硝化抑制剂对菜地周年综合温室效应的影响.结果表明: 与不施用生物炭相比,施用生物炭处理N2O和CH4的综合温室效应增加8.7%~12.4%,蔬菜产量增加16.1%~52.5%,温室气体强度降低5.4%~28.7%.添加硝化抑制剂显著减少N2O排放,不影响CH4排放,综合温室效应减少17.5%~20.6%,蔬菜产量增加21.2%~40.1%,温室气体强度显著降低.混合施用生物炭与硝化抑制剂一方面增加蔬菜产量,另一方面显著增加综合温室效应(增幅为10.6%~11.2%).因此,在菜地添加硝化抑制剂,既能保证蔬菜产量又能减少温室气体排放,是合适的减排措施.  相似文献   

9.
氮肥种类及运筹技术调控土壤氮素损失的研究进展   总被引:1,自引:1,他引:0  
氮肥的不合理施用导致氮肥利用率低下,大量氮素通过径流、淋溶、氨挥发、硝化-反硝化作用等途径损失到环境中,从而对水体、大气造成污染,带来严重的环境问题,影响人类健康.施氮量、施肥时间和方式,以及肥料种类对氮素流失量的影响显著.土壤氮素浓度过饱和是导致氮素大量流失的最根本原因,充分利用环境供氮量,减少化学氮肥施用量,采用深施等技术,以及配合施用有机肥,可以有效降低氮素的损失,提高氮素利用率.在开发应用新型高效氮肥和强化氮肥高效管理技术研究的同时,加强环境氮素的监测和利用力度,是实现减氮增效的有力手段.  相似文献   

10.
几种硝化抑制剂对土壤和小白菜硝酸盐含量及产量的影响   总被引:25,自引:3,他引:22  
通过田间试验,对湖南长沙地区的红菜园土和冲积菜园土两种土壤条件下氢醌 (HQ)、双氰胺 (DCD)和硫脲 (TU) 3种硝化抑制剂对土壤和小白菜硝酸盐含量及小白菜产量的影响进行研究.结果表明,3种硝化抑制剂在试验的各个时期均不同程度地降低了土壤和小白菜的硝酸盐含量,其中以双氰胺的效果最好.但不同供试土壤条件下的试验结果不完全一致.3种硝化抑制剂均可不同程度提高小白菜产量,其中双氰胺效果最好,且在红菜园土的增产效果比冲积菜园土显著.  相似文献   

11.
探究施用生物炭和脲酶抑制剂/硝化抑制剂对亚热带水稻土氮素硝化过程的调控作用、氨挥发和N2O排放的温室效应潜能的影响,确定生物炭与硝化和脲酶抑制剂的最佳组合,可为削减施用氮肥带来的活性氮气体排放对环境的负面风险提供理论依据。本研究采用室内好气培养试验方式,以单施尿素(N)为对照,设置7个试验处理[尿素+生物炭(NB),尿素+硝化抑制剂(N+NI),尿素+脲酶抑制剂(N+UI),尿素+硝化抑制剂+脲酶抑制剂(N+NIUI),尿素+硝化抑制剂+生物炭(NB+NI),尿素+脲酶抑制剂+生物炭(NB+UI),尿素+硝化抑制剂+脲酶抑制剂+生物炭(NB+NIUI)],观测生物炭与脲酶抑制剂(NBPT)/硝化抑制剂(DMPP)配施下土壤无机氮含量、N2O排放及氨挥发的变化动态。结果表明: 1)培养期间,与N处理(5.11 mg N·kg-1·d-1)相比,NB处理的土壤硝化速率常数显著增加33.9%,N+NI处理显著降低22.9%;NB处理显著提高了氨氧化细菌(AOB)丰度,增幅达56.0%。2)与N处理相比,N+NI和NB+NI处理的NH3累积排放量均显著增加约49%;N+UI处理降低了NH3累积损失量,NB+UI处理抑制效果更明显。3)各处理的N2O排放速率高峰均出现在施肥后前10 d;NB处理的N2O排放高峰出现最早,N处理排放速率最高(5.87 μg·kg-1·h-1);硝化抑制剂与脲酶抑制剂配施减少土壤N2O排放的效果最佳。综合计算各处理直接N2O和间接N2O(NH3)排放产生的温室效应潜能(GWP)发现,N+NI和NB+NI处理较N处理分别增加了34.8%和40.9%,而NB和NB+UI处理的GWP显著降低了45.9%和60.5%。因此,生物炭与脲酶抑制剂配施对降低土壤活性氮气体排放所产生的温室效应潜能效果最佳。  相似文献   

12.
This study was undertaken to investigate the effects of both nitrogen (N) and potassium (K) rates on rice resistance to brown spot, caused by the fungus Bipolaris oryzae. Rice plants (cultivar ‘Metica 1’) were grown in soil corrected with 0, 25, 50, 75 and 100 mg of N / kg (as NH4NO3) of soil as well as with 25, 50, 75, 125 and 150 mg of K / kg (as KCl) of soil. Thirty‐three‐day‐old plants were inoculated with a suspension of Bipolaris oryzae conidia and the incubation period (IP), number of lesions (NL) per cm2 of leaf area and disease severity was evaluated. Disease severity was scored at 24, 48, 72, 96, 120 and 144 h after inoculation and data were used to obtain the area under brown spot progress curve (AUBSPC). Soil plant analysis development (SPAD) index, plant dry weight and concentration of N and K in leaf tissues were also determined for both non‐inoculated (NI) and inoculated (IN) plants. Concentration of N in leaf tissue increased as the N rates in the soil increased. Concentration of K in leaf tissue increased sharply as the K rates in the soil increased for both NI and IN plants. Concentration of K in leaf tissue was not affected by N rates. The IP increased as the N rates increased, but was somewhat less impacted by increasing K rates. The NL decreased as the N rates increased. The NL dramatically declined at the highest K rates. The AUBSPC dramatically declined as the N and K rates in the soil increased. SPAD index values increased as the N and K rates in the soil increased for both NI and IN plants. Plant dry weight increased as the N and K rates in the soil increased for both NI and IN plants. Results from this study suggest that combining high N and K rates may contribute to reducing the intensity of brown spot in rice while improving plant development.  相似文献   

13.
研究华北冬绿肥二月兰对不同供氮水平的响应特征,确定实现绿肥高产高效的土壤适宜供氮量,可为华北集约化农田最大化发挥绿肥生态效应和优化春玉米/冬绿肥轮作体系氮素管理提供理论依据和技术参考.选取多年不施肥试验地设置供氮梯度试验,研究了不同供氮水平对冬绿肥二月兰翻压前地上部生物量累积、氮素吸收、土壤无机氮残留和冬绿肥季土壤氮素平衡的影响.结果表明: 在土壤无机氮含量较低(0~90 cm土层15 kg·hm-2)条件下,施氮显著提高二月兰生物量和吸氮量.其中,施氮90 kg·hm-2处理表现最高,绿肥生物量(干质量)和吸氮量分别为2031.0和42.0 kg·hm-2;土壤无机氮残留量随施氮量增加而增加,且在施氮量高于60 kg·hm-2后呈现快速增加趋势;随施氮量增加二月兰生长季的表观氮平衡表现出由亏缺到盈余的变化特征,在施氮量为60~90 kg·hm-2条件下氮收支基本平衡.土壤供氮量(绿肥播前0~90 cm土壤无机氮含量与施氮量之和)与二月兰生物量、吸氮量和绿肥翻压前土壤无机氮含量的关系可以分别用二次、线性加平台和指数方程进行模拟,依据模型计算二月兰生物量最高值(2010 kg·hm-2)时的播前土壤供氮量和绿肥翻压前土壤无机氮残留量分别是136和78 kg·hm-2;而在二月兰吸氮量最高值40 kg·hm-2时,二月兰生物量为1919 kg·hm-2,相当于最高生物量的95%,绿肥翻压前土壤残留无机氮降低至57 kg·hm-2,与之对应的播前土壤供氮量为105 kg·hm-2,该值与目前华北地区优化施氮下玉米收获后土壤残留无机氮推荐含量(100 kg·hm-2)基本相当.综合考虑绿肥的农学和环境效应,春玉米/冬绿肥轮作体系中二月兰播前土壤供氮量应控制在100~105 kg·hm-2.  相似文献   

14.
Knowledge‐based nitrogen (N) management, which is designed for a better synchronization of crop N demand with N supply, is critical for global food security and environmental sustainability. Yet, a comprehensive assessment on how these N management practices affect food production, greenhouse gas emission (GHG), and N pollution in China is lacking. We compiled the results of 376 studies (1166 observations) to evaluate the overall effects of seven knowledge‐based N management practices on crop productivity, nitrous oxide (N2O) emission, and major reactive N (Nr) losses (ammonia, NH3; N leaching and runoff), for staple grain (rice, wheat, and corn) production in China. These practices included the application of controlled‐release N fertilizer, nitrification inhibitor (NI) and urease inhibitor (UI), higher splitting frequency of fertilizer N application, lower basal N fertilizer (BF) proportion, deep placement of N fertilizer, and optimal N rate based on soil N test. Our results showed that, compared to traditional N management, these knowledge‐based N practices significantly increased grain yields by 1.3–10.0%, which is attributed to the higher aboveground N uptake (5.1–12.1%) and N use efficiency in grain (8.0–48.2%). Moreover, these N management practices overall reduced GHG emission and Nr losses, by 5.4–39.8% for N2O emission, 30.7–61.5% for NH3 emission (except for the NI application), 13.6–37.3% for N leaching, and 15.5–45.0% for N runoff. The use of NI increased NH3 emission by 27.5% (9.0–56.0%), which deserves extra‐attention. The cost and benefit analysis indicated that the yield profit of these N management practices exceeded the corresponding input cost, which resulted in a significant increase of the net economic benefit by 2.9–12.6%. These results suggest that knowledge‐based N management practice can be considered an effective way to ensure food security and improve environmental sustainability, while increasing economic return.  相似文献   

15.
施氮时期对玉米土壤硝态氮含量变化及氮盈亏的影响   总被引:26,自引:3,他引:23  
在“郑单 95 8”(9株 / m2 )组成的土 -植系统 ,研究了不施氮、基施氮 10叶展追氮、基施氮 吐丝期追氮和基施氮 乳熟期追氮共 4个处理下 0~ 2 0 0 cm的土壤 NO- 3- N含量在夏玉米生长期间的变化和土壤氮素的表观盈亏量 ,结果表明 :2 0 cm以上的土壤 NO- 3- N含量以大口期为界、2 0 cm以下的土壤 NO- 3- N含量以吐丝期为界前降后升。在 0~ 2 0 cm土层 ,与不施氮相比 ,施氮能增加土壤 NO- 3- N含量 ,而且吐丝期和乳熟至成熟阶段的 NO- 3- N含量在 10叶展期和吐丝期各自追氮后均显著增加。在 2 0~4 0 cm土层 ,乳熟期的 NO- 3- N含量施氮后明显比不施氮高。在 80 cm以下土层 ,施氮后的土壤 NO- 3- N含量明显比不施氮高 ;追氮期相比 ,后一追氮处理在乳熟期和成熟期的 NO- 3- N含量均比前一追氮处理明显增加 ,其中成熟期基施氮 乳熟期追氮处理在 16 0~ 2 0 0 cm土层的 NO- 3- N含量比基施氮 吐丝期追氮处理 (为 2 5 .3m g N/ kg(干土 ) )高 16 %。土壤氮素的表观盈余发生在吐丝期之前且 80 %以上盈余量出现在大口期前 ,表观亏损出现在吐丝期以后且其亏损量在乳熟期前后各占一半。经玉米季后 ,本试验中不施氮处理出现表观盈余 (为 5 6 .3kg N/ hm2 ) ;施氮后表观盈余量增加 ,主要是施氮减少了吐丝以后  相似文献   

16.
为明确长期氮磷钾肥配施下贵州典型黄壤玉米产量、氮磷钾肥增产效应及土壤养分的演变特征,利用国家贵阳黄壤肥力与肥效长期定位试验,研究氮磷钾平衡施肥(NPK)与缺素施肥(N、NK、NP、PK)对玉米相对产量、氮磷钾肥增产贡献率及土壤氮磷钾素养分可持续性指数等的影响.结果表明: 氮磷钾平衡施肥有显著增产效果,玉米相对产量均值为:NPK>NP>NK>PK>CK;氮、磷、钾肥增产贡献率和农学利用率均为氮肥>磷肥>钾肥,施肥依存度为氮、磷、钾肥配施>氮肥>磷肥>钾肥,但缺磷处理(NK)玉米相对产量以每年1.4%的速度极显著下降,磷肥贡献率和依存度则以每年2.3%和1.4%的速度极显著上升,最终磷肥对玉米生产的影响逐渐与氮肥持平;缺磷处理土壤pH值和有机质含量均最低,而缺氮处理则较高;施用化学磷肥可提高黄壤磷素可持续性指数,但氮肥和钾肥对黄壤氮素和钾素可持续性指数无显著影响.综上,平衡施肥是贵州典型黄壤地区玉米高产的重要保障,其中磷肥与氮肥同等重要,但长期单施化肥尤其是缺磷处理不利于黄壤养分的可持续利用.  相似文献   

17.
Anthropogenic activities, and in particular the use of synthetic nitrogen (N) fertilizer, have doubled global annual reactive N inputs in the past 50–100 years, causing deleterious effects on the environment through increased N leaching and nitrous oxide (N2O) and ammonia (NH3) emissions. Leaching and gaseous losses of N are greatly controlled by the net rate of microbial nitrification. Extensive experiments have been conducted to develop ways to inhibit this process through use of nitrification inhibitors (NI) in combination with fertilizers. Yet, no study has comprehensively assessed how inhibiting nitrification affects both hydrologic and gaseous losses of N and plant nitrogen use efficiency. We synthesized the results of 62 NI field studies and evaluated how NI application altered N cycle and ecosystem services in N‐enriched systems. Our results showed that inhibiting nitrification by NI application increased NH3 emission (mean: 20%, 95% confidential interval: 33–67%), but reduced dissolved inorganic N leaching (?48%, ?56% to ?38%), N2O emission (?44%, ?48% to ?39%) and NO emission (?24%, ?38% to ?8%). This amounted to a net reduction of 16.5% in the total N release to the environment. Inhibiting nitrification also increased plant N recovery (58%, 34–93%) and productivity of grain (9%, 6–13%), straw (15%, 12–18%), vegetable (5%, 0–10%) and pasture hay (14%, 8–20%). The cost and benefit analysis showed that the economic benefit of reducing N's environmental impacts offsets the cost of NI application. Applying NI along with N fertilizer could bring additional revenues of $163 ha?1 yr?1 for a maize farm, equivalent to 8.95% increase in revenues. Our findings showed that NIs could create a win‐win scenario that reduces the negative impact of N leaching and greenhouse gas production, while increases the agricultural output. However, NI's potential negative impacts, such as increase in NH3 emission and the risk of NI contamination, should be fully considered before large‐scale application.  相似文献   

18.
There is a growing concern about excessive nitrogen (N) and water use in agricultural systems in North China due to the reduced resource use efficiency and increased groundwater pollution. A two-year experiment with two soil moisture by four N treatments was conducted to investigate the effects of N application rates and soil moisture on soil N dynamics, crop yield, N uptake and use efficiency in an intensive wheat–maize double cropping system (wheat–maize rotation) in the North China Plain. Under the experimental conditions, crop yield of both wheat and maize did␣not␣increase significantly at N rates above 200 kg N ha−1. Nitrogen application rates affected little on ammonium-N (NH4-N) content in the 0–100 cm soil profiles. Excess nitrate-N (NO3-N), ranging from 221 kg N ha−1 to 620 kg N ha−1, accumulated in the 0–100 cm soil profile at the end of second rotation in the treatments with N rates of 200 kg N ha−1 and 300 kg N ha−1. In general, maize crop has higher N use efficiency than wheat crop. Higher NO3-N leaching occurred in maize season than in wheat season due to more water leakage caused by the concentrated summer rainfall. The results of this study indicate that the optimum N rate may be much lower than that used in many areas in the North China Plain given the high level of N already in the soil, and there is great potential for reducing N inputs to increase N use efficiency and to mitigate N leaching into the groundwater. Avoiding excess water leakage through controlled irrigation and matching N application to crop N demand is the key to reduce NO3-N leaching and maintain crop yield. Such management requires knowledge of crop water and N demand and soil N dynamics as they change with variable climate temporally and spatially. Simulation modeling can capture those interactions and is considered as a powerful tool to assist in␣the␣future optimization of N and irrigation managements. Section Editor: L. Wade  相似文献   

19.
施钾量和施钾时期对小麦氮素和钾素吸收利用的影响   总被引:21,自引:0,他引:21  
利用15N示踪技术,研究了施钾量和施钾时期对高产小麦氮素和钾素吸收利用的影响.结果表明: 0~20 cm土层土壤速效钾含量为118.5 mg·kg-1时,一次性基施钾肥未提高植株的氮、钾积累量;速效钾含量为79.0 mg·kg-1时,施钾显著提高了植株的氮、钾积累量.采用分期施钾时(1/2基施、1/2拔节期追施),随施钾量增加,小麦吸收的肥料氮和土壤氮量及追施氮肥在土壤中的残留量均增加,肥料氮的损失量降低.分期施钾显著提高了植株的氮、钾积累量、吸收效率和生产效率,当施钾量为135 kg·hm-2时,与一次性施钾相比,分期施钾促进了植株对追肥氮和土壤氮的吸收,提高了追施氮肥在土壤中的残留量.结果还表明:施钾提高了小麦的籽粒产量、蛋白质含量和湿面筋含量;分期施钾处理优于一次性施钾处理,以K45+45(45 kg·hm-2基施、45 kg·hm-2拔节期追施)处理最优.过多施钾使小麦产量和品质趋于降低.  相似文献   

20.
草地生态系统中土壤氮素矿化影响因素的研究进展   总被引:41,自引:5,他引:36  
氮素是各种植物生长和发育所需的大量营养元素之一,也是牧草从土壤吸收最多的矿质元素.土壤中的氮大部分以有机态形式存在,而植物可以直接吸收利用的是无机态氮.这些有机态氮在土壤动物和微生物的作用下。由难以被植物直接吸收利用的有机态转化为可被植物直接吸收利用的无机态的过程就是土壤氮的矿化.氮素矿化受多种因子的影响,这些因子可以归结为生物因子和非生物因子.生物因子包括:土壤动物、土壤微生物和植物种类.土壤动物可以促进土壤有机质的矿化;土壤微生物种类、结构及功能与氮的分解、矿化有密切的关系;不同的植物种类对土壤氮素的矿化作用是不相同的,一般来说。有豆科植物生长的土壤比其它种类土氮素矿化的作用大.非生物因素一般可以分为环境因子和人类活动干扰.环境因子中土壤温度和含水量对土壤氮素矿化的影响是国内外众多科学家研究的方向.尽管如此,在此方面的研究还没有取得一致意见,仍然需要进行这方面的研究,而在其他诸如:不同的土壤质地与土壤类型方面,研究报道的结论也很不一致,草地生态系统中人类活动对土壤氮素矿化的影响主要包括,不同强度的放牧,割草以及施肥、火烧强度等.非生物因子对氮素矿化的影响非常直接和明显,尤其是人类活动.本文综述了近年来影响草地生态系统土壤氮素矿化有关因素的一些进展.  相似文献   

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