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1.
[目的] 微咸水灌溉是缓解农业用水紧张、保障粮食生产的重要途径之一,但灌溉水中的可溶性盐会导致土壤盐分累积,进而影响作物生长,寻求适宜的灌溉水盐分浓度是咸水、微咸水资源得到安全利用的有利保障。[方法] 研究采用遮雨盆栽试验种植冬小麦,以去离子水为对照(CK),添加氯化盐形成不同浓度的微咸水处理,灌溉水电导率(ECw)分别为:0.26(CK),3.00(S1),5.26(S2),7.07(S3),9.24(S4) dS/m,研究土壤水盐分布和冬小麦生长、光合生理及产量形成的响应。[结果] 不同浓度微咸水灌溉下土壤含水率、土壤含盐量随盐分浓度的增加而增大。当灌溉水电导率为9.24 dS/m时,土壤含水率分别比CK高5.43%(0—10 cm),4.21%(10—20 cm),4.98%(20—40 cm);冬小麦收获后CK及S1-S4处理下0—40 cm土层土壤饱和浸提液电导率(ECe)分别为0.66,4.89,7.88,9.34,10.16 dS/m;与CK相比,灌溉水电导率为3.00,5.26 dS/m时,冬小麦生长、光合生理指标、产量无显著差异,而为7.07,9.24 dS/m时显著降低,当灌溉水电导率为9.24 dS/m时,冬小麦净光合速率、最大株高、最大叶面积、成熟期地上部干物质量、根系干物质量及产量相比CK分别降低71.00%,2.81%,15.33%,15.55%,47.25%,27.53%。利用FAO分段函数拟合计算得冬小麦灌溉微咸水电导率阈值为5.82 dS/m,超过该值,每增加1 dS/m,冬小麦相对产量下降8.80%。[结论] 综上所述,灌溉水盐分浓度越高,对土壤水盐分布及冬小麦生长的影响越大,5.82 dS/m为冬小麦的灌溉微咸水电导率阈值。综合考虑冬小麦生长、光合生理指标及土壤理化性质,建议使用微咸水灌溉冬小麦时,ECw不宜超过5.82 dS/m。该研究结果可为微咸水安全利用提供理论支撑。 相似文献
2.
农业活动对土壤甲烷汇的影响研究 总被引:3,自引:0,他引:3
耕作对土壤CH4 吸收有长期抑制作用并极大地降低了土壤CH4 汇的强度。施NH4 N肥可抑制土壤CH4 氧化 ,而NO3- N肥则无此作用 ,NH4 N肥对土壤CH4 氧化的抑制效应大于等N量粪肥。C/N值小且导致土壤酸化的作物残茬对CH4 氧化的抑制作用较大 ,生物废弃物堆肥对土壤CH4 氧化有暂时抑制作用。灌溉和施用杀虫剂可减少土壤CH4 吸收量 ,免耕、施NO3- N肥和有机肥是维持与增加农田土壤CH4 吸收量的有效措施。 相似文献
3.
盐渍土番茄苗期养分吸收特性的研究 总被引:1,自引:0,他引:1
本文研究了盐渍土下番茄苗期养分吸收特性及土壤含盐量对番茄苗期养分吸收的影响.结果表明随苗期的增长,番茄对磷钾需求量增加幅度加大,养分吸收量由氮最高转变为钾,其排列为K2O>N>P2O5>CaO>MgO.苗期后期养分吸收量为全苗期吸收总量的80%左右.随土壤含盐量的增加,抑制番茄苗期生长,对氮、磷、镁的吸收影响不大,对钾和钙的吸收有明显的抑制作用. 相似文献
4.
生物改良滨海盐渍土是一种投资少、需时短、见效快、长期受益的环保生态型技术。通过田间试验将木霉制剂[活性成分为木霉分生孢子,1×107(CFU)·g~(-1)]施用到滨海中度盐渍土台田(含盐量2.99 g·kg~(-1),砂壤土),对土壤改良台田试验区不同处理(施用木霉制剂和常规对照处理)及辅助试验区日光温室(含盐量0.98 g·kg~(-1),壤土)、滨海轻度盐渍土开垦田(含盐量1.75 g·kg-1,轻壤土)、滨海重度盐渍土河滩地(含盐量26.19 g·kg~(-1),砂壤土)的耕层土壤取样室内测定,探究木霉在滨海中度盐渍土台田施用的生态效应。滨海中度盐渍土台田木霉处理与对照处理相比,土壤紧实度提高177.04%,土壤水稳性团聚体数量(≥0.25 mm)提高265.78%,土壤含水率提高320.83%,土壤碱解氮、有效磷、速效钾和有机质含量分别提高96.14%、42.17%、105.65%和63.79%;土壤稀释法培养微生物,细菌、放线菌、真菌、固氮菌数量比对照分别提高170.95%、82.68%、152.17%和471.93%。滨海中度盐渍土台田木霉处理与滨海重度盐渍土河滩地比较,有利于植物生长的指标土壤紧实度、水稳性团聚体、有机质和微生物群落数量分别提高1.53倍、2.11倍、3.20倍和28.33倍,不利植物生长的水溶性盐下降96.60%;滨海中度盐渍土台田通过木霉制剂改良,土壤紧实度、总孔隙度、含水率、有效磷、有机质和微生物数量与滨海轻度盐渍土开垦田相比无显著差异;滨海中度盐渍土台田木霉处理后土壤容重降低、总孔隙度增加,与高产日光温室非盐渍化土壤相比接近。滨海重度盐渍土通过沙土抬高1.2 m筑田变为中度盐渍土,降盐效果较好,再通过加入生物改良措施提高土壤营养和有益微生物,优化土壤团粒结构,利于提高滨海中度盐渍土台田改良效率和质量,促进滨海中度盐渍土台田生态的改善。 相似文献
5.
为给我国旱地低碳农业可持续发展提供科学依据,2018 — 2020年在陇东黄土高原雨养区冬小麦田设置夏闲期种植绿肥和不同施氮量田间试验,通过测定土壤N2O和CH4排放通量,计算N2O和CH4累积排放量等指标,分析不同处理对土壤N2O和CH4排放通量和累积排放量的影响。结果表明,在2个轮作周期内,不同处理的N2O排放峰主要出现在冬小麦播种施肥后,峰值范围平均11.24~31.85 μg N2O-N/(m2·h)。土壤CH4排放无明显峰谷变化趋势,而围绕着零值上下波动,变化范围-46.8~24.5 μg CH4-C/(m2·h)。与休闲-冬小麦处理相比,麦黑豆-冬小麦轮作处理在绿肥填闲期和冬小麦生长期土壤N2O累积排放分别显著增加了26.8%~44.2%和6.2%~52.3%,土壤CH4累积吸收分别显著减少了7.9%~76.3%和4.0%~28.4%。可见,豆科绿肥填闲种植可增加土壤N2O排放,减少土壤CH4的吸收。 相似文献
6.
有机无机肥配施对盐渍化土壤微生物量和呼吸的影响 总被引:6,自引:5,他引:1
微生物可以通过摄入能量合成有机渗透压物质来实现对盐度的适应,然而,不同程度盐渍土微生物对能量的需求可能会发生改变。因此,该研究于2018-2019年开展田间定位试验,选取河套灌区轻度盐渍土S1(电导率为0.46 dS/m)及中度盐渍土S2(电导率为1.07 dS/m)为研究对象,设置了6个处理,包括不施氮(CK),单施无机氮(U1)以及分别用有机氮(U3O1、U1O1、U1O3和O1)替代25%、50%、75%和100%的无机氮,监测了土壤微生物量碳氮及土壤呼吸在第二个生长季的动态状况。结果表明:土壤盐渍化程度增加会导致土壤微生物量及微生物活性下降,S2土壤较S1土壤微生物量碳下降12.01%~68.81%,土壤微生物量氮下降14.31%~58.58%,土壤呼吸速率下降11.75%~54.71%。不同盐分条件下,适当的有机肥施入比例可以显著提高土壤微生物量及微生物活性,S1和S2盐渍土分别以U1O1及O1处理较优,土壤微生物量碳、微生物量氮、土壤呼吸分别较U1处理提高48.44%、42.50%、31.74%,68.07%、48.99%、45.19%。相关性分析表明,土壤呼吸速率与土壤微生物量碳氮呈极显著正相关(P<0.01),土壤温度、土壤矿质氮与土壤微生物量碳氮、土壤呼吸速率呈显著正相关(P<0.05)。从玉米产量及改善土壤微生物生存环境角度,得到该地区适宜的施肥模式为,轻度盐渍土:有机氮替代50%无机氮;中度盐渍土:有机氮替代100%无机氮。 相似文献
7.
黄河三角洲中重度盐渍土棉田水盐运移规律研究 总被引:2,自引:1,他引:2
为充分利用黄河三角洲中重度盐渍土资源,通过前期微咸水压盐(2 g/L),选取中度(3.10~3.90 g/kg)和重度(4.60~5.70 g/kg)盐渍土,研究了不同程度盐渍化土壤棉花种植下土壤剖面水盐运移规律。研究结果表明:微咸水压盐后可以使剖面盐分处于相对均匀分布状况;覆盖促进了棉花对膜下水分的吸收利用,中度盐渍土棉花在苗期和蕾期主要耗水层为0~40 cm土壤表层,重度盐渍土棉花主要耗水层为0~30 cm土壤表层,后期由于作物生长引起深层水分(60~100 cm)消耗,且中度盐渍土深层水分吸收要高于重度盐渍土;生育期内中度盐渍土盐分上下土层波动范围为0.80~2.00 g/kg,重度盐渍土为2.00~5.60 g/kg,膜下土壤含盐量均要低于膜外土壤含盐量,至收获期中度、重度盐渍土剖面平均脱盐率分别为62.40%和55.83%,棉花产量分别为2 129.76 kg/hm2和823.66 kg/hm2。 相似文献
8.
基于水分和原位电导率的西宁盆地盐渍土含盐量估算模型 总被引:2,自引:1,他引:1
为了探讨西宁盆地黄土状盐渍土导电特性与土体本身含水率和含盐量之间的关系,该文在土体洗盐试验基础上,测得了不同含水率和含盐量条件下黄土状盐渍土电导率,分析了土体电导率与含水率、含盐量之间的相互关系和作用机理;在此基础上,建立了土体电导率与含水率、含盐量之间的多元回归模型。结果表明,在土体含盐量一定条件下随着土体含水率增加土体电导率呈逐渐增大的变化趋势,且二者之间符合幂函数关系;土体含盐量愈高条件下土体含水率增加对电导率的影响则愈为显著。在土体含水率一定的条件下,土体电导率随着含盐量增加呈逐渐增大的变化趋势,且二者之间符合线性函数关系;当土体含水率相对较高时,含盐量增加对电导率的影响程度亦较为显著。对建立的区内黄土状盐渍土电导率与含水率、含盐量之间的多元回归模型(R2=0.995)进行验证,相对误差在10%之内,表明模型可有效确定含水率大于5%且小于25%(?5.52%)及含盐量为0.18%~2.18%条件下黄土状盐渍土的含盐量。研究成果对研究区及其周边地区黄土状盐渍土其盐渍化程度划分、工程地质特性评价,以及土体盐渍化等地质灾害现象的科学防治具有理论研究价值和工程指导意义。 相似文献
9.
华南地区覆膜旱种稻田甲烷排放及其与土壤水分和温度的关系 总被引:2,自引:0,他引:2
采用静态箱法和田间小区试验,研究了常规稻田和覆膜旱种稻田水稻全生育期CH4的排放规律,探讨了温度和水分与稻田CH4排放的关系。结果表明:覆膜旱种稻田的甲烷排放量明显低于常规水田的排放量,常规水田的甲烷累计排放通量为20.38g/m2,覆膜旱种稻田为2.46g/m2,水稻覆膜旱种后甲烷排放量降低了88%。常规水田CH4排放峰期持续了35d,覆膜旱种稻田CH4排放峰期为25d,两者在CH4排放高峰期的排放量分别占整个生育期累计排放量的72%和97%。覆膜旱作稻田CH4排放量降低,主要表现在最大排放峰值降低和排放峰持续时间缩短。土壤温度(5cm处)和水分与水稻生育期稻田甲烷的排放有显著正相关。CH4排放通量大于1.0mg·m-2·h-1主要集中在土壤质量含水率高于36.25%的区域,在土壤质量含水率小于36.25%时,常规稻田和覆膜旱种稻田都只有少量CH4排放。 相似文献
10.
不同接触和淋洗时间下脱硫石膏对滨海吹填土理化性质的影响 总被引:1,自引:0,他引:1
为改善滨海吹填土的理化性质,加快提升吹填土在城市生态建设中的土地价值,开展脱硫石膏不同接触时间处理对滨海吹填土理化性质影响的试验研究。结果表明:滨海吹填土导水能力极弱,在整个淋洗过程中始终没有淋出液排出,2,5,10,50d脱硫石膏接触处理后土壤饱和导水率分别达到6.21,7.20,7.20,7.65mm/h,显著提升了滨海吹填土的导水能力。2,5,10,50d石膏接触处理分别经220,116,116,196h淋洗后,淋出液盐分均达到0.5dS/m以下,淋洗用水量分别为5.16,3.85,4.21,4.95L。淋洗后,土壤含盐量由处理前6.98dS/m下降到0.28~0.36dS/m,土壤中Cl-、Na+浓度分别由处理前的9.03,4.85g/kg下降到0.05~0.34g/kg和0.01~0.04g/kg,土壤钠吸附比(SAR)以及土壤碱化度(ESP)分别由处理前的27.89和28.15下降到0.18~0.8和0.02~0.28,已经为非碱化土,土壤的各理化指标均得到明显改善。综合各种因素与指标,脱硫石膏与吹填土5d接触处理效果最佳。 相似文献
11.
滨海重度盐碱地微咸水滴灌水盐调控及月季根系生长响应研究 总被引:4,自引:2,他引:2
滨海盐碱地是滨海地区重要的土地资源,随着滨海地区城镇化进程及生态文明建设的发展,迫切需要低成本、快速、可持续的滨海盐碱地原土植被构建技术。针对滨海盐碱地原土建植与咸水/微咸水资源的利用,该研究以月季(Rosa chinensis)为例,采用微咸水滴灌技术进行滨海盐碱地水盐调控植被构建。试验在渤海湾曹妃甸区吹沙造田形成的典型沙质滨海盐渍土上进行,设计了灌溉水电导率(ECiw)为0.8、3.1、4.7、6.3、7.8 dS/m的5个处理,研究滴灌水盐调控对土壤盐分淋洗及月季根系生长和分布特征的影响。结果表明:在渤海湾滨海地区气候条件下,先进行淡水滴灌盐分强化淋洗和缓苗灌溉,随后采用7.8 dS/m的微咸水滴灌,0~100 cm土层土壤盐分得到了有效的淋洗,尤其是根层0~40 cm土壤盐分经过一个月左右,由初始28.33 dS/m降低到均小于4 dS/m,一个低盐适生的土壤环境得到快速营造;随着ECiw的增加,0~40 cm土层土壤最终趋于稳定的盐分呈增加趋势,土壤脱盐过程可以被logistic方程描述,脱盐过程可划分为快速脱盐、缓慢脱盐和盐分趋于稳定3个阶段;94%以上的月季根系主要分布在0~20cm的表层土壤中,随着ECiw的增加,根系生物量显著降低,根系受盐分胁迫生理干旱影响向土壤深处生长以扩大水分空间。研究认为,采用短期淡水滴灌盐分强化淋洗和缓苗淡水滴灌、随后进行微咸水滴灌的方法,可以实现土壤盐分的快速淋洗并维持在较低水平,但受盐分对根系生长的影响会作用于植物地上部分生长及植物存活,因此需要结合植物耐盐性及生产目标(产量、景观)确定适宜灌溉水矿化度阈值。 相似文献
12.
盐碱地土壤:氧化亚氮和二氧化碳排放的潜在来源? 总被引:2,自引:1,他引:1
Increasing salt-affected agricultural land due to low precipitation,high surface evaporation,irrigation with saline water,and poor cultural practices has triggered the interest to understand the influence of salt on nitrous oxide(N_2O) and carbon dioxide(CO_2)emissions from soil.Three soils with varying electrical conductivity of saturated paste extract(EC_e)(0.44-7.20 dS m~(-1)) and sodium adsorption ratio of saturated paste extract(SARe)(1.0-27.7),two saline-sodic soils(S2 and S3) and a non-saline,non-sodic soil(S1),were incubated at moisture levels of 40%,60%,and 80%water-filled pore space(WFPS) for 30 d,with or without nitrogen(N)fertilizer addition(urea at 525 μg g~(-1) soil).Evolving CO_2 and N2 O were estimated by analyzing the collected gas samples during the incubation period.Across all moisture and N levels,the cumulative N_2O emissions increased significantly by 39.8%and 42.4%in S2 and S3,respectively,compared to S1.The cumulative CO_2 emission from the three soils did not differ significantly as a result of the complex interactions of salinity and sodicity.Moisture had no significant effect on N_2O emissions,but cumulative CO_2 emissions increased significantly with an increase in moisture.Addition of N significantly increased cumulative N_2O and CO_2 emissions.These showed that saline-sodic soils can be a significant contributor of N_2O to the environment compared to non-saline,non-sodic soils.The application of N fertilizer,irrigation,and precipitation may potentially increase greenhouse gas(N2O and CO_2) releases from saline-sodic soils. 相似文献
13.
Microbial adaptation to salinity can be achieved through synthesis of organic osmolytes,which requires high amounts of energy;however,a single addition of plant residues can only temporarily improve energy supply to soil microbes.Therefore,a laboratory incubation experiment was conducted to evaluate the responses of soil microbes to increasing salinity with repeated additions of plant residues using a loamy sand soil with an electrical conductivity in saturated paste extract(ECe) of 0.6 dS m-1.The soil was kept non-saline or salinized by adding different amounts of NaCl to achieve ECe of 12.5,25.0 and 50.0 dS m-1.The non-saline soil and the saline soils were amended with finely ground pea residues at two rates equivalent to 3.9 and 7.8 g C kg-1 soil on days 0,15 and29.The soils receiving no residues were included as a control.Cumulative respiration per g C added over 2 weeks after each residue addition was always greater at 3.9 than 7.8 g C kg-1 soil and higher in the non-saline soil than in the saline soils.In the saline soils,the cumulative respiration per g C added was higher after the second and third additions than after the first addition except with3.9 g C kg-1 at ECe of 50 dS m1.Though with the same amount of C added(7.8 g C kg-1),salinity reduced soil respiration to a lesser extent when 3.9 g C kg-1 was added twice compared to a single addition of 7.8 g C kg-1.After the third residue addition,the microbial biomass C concentration was significantly lower in the soils with ECe of 25 and 50 dS m1 than in the non-saline soil at3.9 g C kg-1,but only in the soil with ECe of 50 dS m-1 at 7.8 g C kg-1.We concluded that repeated residue additions increased the adaptation of soil microbial community to salinity,which was likely due to high C availability providing microbes with the energy needed for synthesis of organic osmolytes. 相似文献
14.
基于EPO-PLS回归模型的盐渍化土壤含水率高光谱反演 总被引:5,自引:1,他引:4
表层土壤含水率对于指导农业灌溉有重要的作用。研究表明,土壤光谱受到土壤水分和盐分的共同影响,但对于盐渍化地区的土壤含水率高光谱反演却很少涉及。该文通过对11组不同含盐量土壤室内蒸发过程连续监测,获取相关反射率光谱和水分、盐分的变化数据,利用外部参数正交化方法(external parameter orthogonalisation,EPO)预处理土壤光谱,滤除盐分(质量比0.1%~5.0%)的影响,建立经过EPO预处理后的偏最小二乘(partial least squares regression after EPO pre-processing,EPO-PLS)土壤水分预测模型。与偏最小二乘(partial least square model,PLS)模型相比,验证样本的决定系数R2和对分析误差RPD(residual predictive deviation)分别从0.722、1.976上升到0.898、3.145;均方根误差RMSE从5.087 g/(100 g)减少到3.237 g/(100 g)。通过EPO算法预处理后的模型性能提升显著,利用该方法能够有效的消除土壤盐分的影响,很好地实现盐渍化地区的水分含量估测。 相似文献
15.
Osmotic potential (OP) of soil solution may be a more appropriate parameter than electrical conductivity (EC) to evaluate the effect of salts on plant growth and soil biomass.However,this has not been examined in detail with respect to microbial activity and dissolved organic matter in soils with different texture.This study evaluated the effect of salinity and sodicity on respiration and dissolved organic matter dynamics in salt-affected soils with different texture.Four non-saline and non-sodic soils differing in texture (S-4,S-13,S-24 and S-40 with 4%,13%,24% and 40% clay,respectively) were leached using combinations of 1 mol L-1 NaC1 and 1 mol L-1 CaC12 stock solutions,resulting in EC (1:5 soil:water ratio) between 0.4 and 5.0 dS m-1 with two levels of sodicity (sodium absorption ratio (SAR) < 3 (non-sodic) and 20 (sodic),1:5 soil:water ratio).Adjusting the water content to levels optimal for microbial activity,which differed among the soils,resulted in four ranges of OP in all the soils:from-0.06 to--0.24 (controls,without salt added),-0.55 to-0.92,-1.25 to-1.62 and-2.77 to-3.00 Mpa.Finely ground mature wheat straw (20 g kg-1) was added to stimulate microbial activity.At a given EC,cumulative soil respiration was lower in the lighter-textured soils (S-4 and S-13) than in the heavier-textured soils (S-24 and S-40).Cumulative soil respiration decreased with decreasing OP to a similar extent in all the soils,with a greater decrease on Day 40 than on Day 10.Cumulative soil respiration was greater at SAR =20 than at SAR < 3 only at the OP levels between-0.62 and-1.62 MPa on Day 40.In all the soils and at both sampling times,concentrations of dissolved organic C and N were higher at the lowest OP levels (from-2.74 to-3.0 MPa) than in the controls (from-0.06 to-0.24 MPa).Thus,OP is a better parameter than EC to evaluate the effect of salinity on dissolved organic matter and microbial activity in different textured soils. 相似文献
16.
Elham Shahrayini Mahboobeh Fallah Mahmoud Shabanpour Saeid Saadat 《Archives of Agronomy and Soil Science》2018,64(10):1329-1340
Inappropriate crop management and long-term use of heavy agricultural equipment can lead to soil compaction. On the other hand, soil and water salinity causes reduction in the plant yield in addition to adverse effects on plants tolerance to the various stresses. The aim of this study was to investigate the interaction between soil compaction and salinity on the macronutrients uptake and wheat yield as well as its agronomic traits. The pot experiment was carried out on the loamy soil in a completely randomized block design with three replications. The treatments consisted of two salinity types (saline, EC = 6 dS/m and non-saline soil) and five levels of compaction; control, 5%, 10%, 15% and 20%. The results showed that soil compaction had significant effect on the amount of N, P and K in wheat grain, so that the uptake of N, P and K by grain has been decreased by increasing the compaction level of soil. Soil salinity had significant effect on N, P and K content in grain that the content of N, P and K has been diminished in the saline treatments compared to non-saline treatments. Results on the agronomic traits and yield of wheat also revealed that soil compaction and salinity had significant effect (p < 0.01) on straw weight, number of ears, number of grain, and thousand grain weight which caused reduction in these parameters. The interaction between compaction and salinity had only significant correlation (p < 0.01) with thousand grain weight leading to the decrement of thousand grain weight with increasing compaction levels, particularly in the saline treatment. 相似文献
17.
Strategy for long term use of saline drainage water for irrigation in semi-arid regions 总被引:3,自引:0,他引:3
In arid and semi-arid regions, effluent from subsurface drainage is often saline and in the absence of a natural outlet, its disposal is a serious environmental threat. A field experiment was conducted for 7 years using drainage water of different salinity levels (ECiw=6, 9, 12 and 18.8 dS/m) for irrigation of wheat during the dry winter season. The objective was to find whether crop production would still be feasible and soil salinity would not be increased unacceptably by this practice. The experimental crop was wheat during the winter season and pearl-millet and sorghum in the rainy season, grown on a sandy loam soil provided with subsurface drainage system. All crops were given a pre-plant irrigation with non-saline canal water and subsequently, saline drainage water of different salinity levels was used for the irrigation of wheat as per the treatment. On an average, the mean yield reduction in wheat yield at different ECiw was 4.2% at 6, 9.7% at 9, 16.3% at 12 and 22.2% at 18.8 dS/m. Pearl-millet and sorghum yields decreased significantly only where 12 dS/m or higher salinity water was applied to previous wheat crop. The high salinity and sodicity of the drainage water increased the soil salinity and sodicity in the soil profile during the winter season, but these hazards were eliminated by the subsurface drainage during the ensuing monsoon periods. The results obtained provide a promising option for the use of poor quality drainage water for the irrigation of winter wheat without undue yield reduction and soil degradation. 相似文献
18.
Soil salinization may negatively affect microbial processes related to carbon dioxide(CO_2) and nitrous oxide(N_2O) emissions. A short-term laboratory incubation experiment was conducted to investigate the effects of soil electrical conductivity(EC) and moisture content on CO_2 and N_2O emissions from sulfate-based natural saline soils. Three separate 100-m long transects were established along the salinity gradient on a salt-affected agricultural field at Mooreton, North Dakota, USA. Surface soils were collected from four equally spaced sampling positions within each transect, at the depths of 0–15 and 15–30 cm. In the laboratory, artificial soil cores were formed combining soils from both the depths in each transect, and incubated at 60% and 90% water-filled pore space(WFPS) at 25?C. The measured depth-weighted EC of the saturated paste extract(EC_e) across the sampling positions ranged from 0.43 to 4.65 dS m~(-1). Potential nitrogen(N) mineralization rate and CO_2 emissions decreased with increasing soil EC_e, but the relative decline in soil CO_2 emissions with increasing ECe was smaller at 60% WFPS than at 90% WFPS. At 60% WFPS, soil N_2O emissions decreased from 133 μg N_2O-N kg~(-1) soil at EC_e 0.50 dS m~(-1) to 72 μg N_2O-N kg~(-1) soil at EC_e = 4.65 dS m~(-1). In contrast, at 90% WFPS,soil N_2O emissions increased from 262 μg N_2O-N kg~(-1) soil at EC_e = 0.81 dS m~(-1) to 849 μg N_2O-N kg~(-1) soil at EC_e = 4.65 dS m~(-1), suggesting that N_2O emissions were linked to both soil ECe and moisture content. Therefore, spatial variability in soil EC_e and pattern of rainfall over the season need to be considered when up-scaling N_2O and CO_2 emissions from field to landscape scales. 相似文献
19.
Decomposition of maize straw in saline soil 总被引:3,自引:0,他引:3
Xiaogang Li Fengmin Li Bhupinderpal-Singh Zhijun Cui Zed Rengel 《Biology and Fertility of Soils》2006,42(4):366-370
The interactive effects of salinity and water on organic matter decomposition in soil are poorly known. A loamy topsoil adjusted
to five concentrations of salinity (0, 31, 62, 93 and 124 mmol Na kg−1 soil) using either NaCl or Na2SO4 was incubated at a water content of either 17 or 25% (w/w) in the dark at 28.5°C for 47 days, with maize straw added at 20 g
kg−1 soil. Comparing with non-saline soil, (1) NaCl salinity at all levels decreased cumulative CO2 evolved during days 1–3 (averaged across two water levels), increased in the period 4–32 days at both water contents, and
thereafter caused variable effects, depending upon water content and salinity; and (2) Na2SO4 salinity at various levels mainly caused no effect on cumulative CO2 evolved during days 1–3 (averaged across two water levels), and thereafter (i.e. in days 4–47) caused mainly positive effects
at 17% (w/w) water content and negative effects at 25% (w/w) water content. Cumulative CO2 evolved over 47 days for both types of salinities was mainly greater at 17% (w/w) and smaller at 25% (w/w) water content
compared with non-saline soil. Generally, at 25% (w/w) than at 17% (w/w) water content, there was a greater CO2 evolved over 47 days, and also during different incubation phases for both types of salinities; the difference at low salinity
levels was generally large and decreased as salinity increased. In conclusion, the salinity effect depends on soil water content
and incubation period or decomposition phase. 相似文献
20.
河套灌区土壤盐分对化肥氮素转化过程的影响研究 总被引:2,自引:0,他引:2
土壤盐渍化严重影响土壤养分利用与生产力提升,为阐明土壤盐渍化对河套灌区农田土壤肥料氮素转化关键过程的影响。以内蒙古河套灌区不同含盐量土壤为试验材料,通过室内恒温培养试验,分析了不同盐分梯度下土壤中氮素转化的水解和硝化过程。试验共设置了低盐(EC_(5:1)=1.46 dS/m)、中盐(EC_(5:1)=2.19 dS/m)、高盐(EC_(5:1)=3.43 dS/m)3种盐分梯度,分别施用尿素和磷酸二铵两种化学氮肥。研究结果表明:①土壤盐分升高抑制了尿素的水解作用,高盐处理尿素的净水解量较中盐和低盐处理分别降低19.4%和27.1%,而土壤盐分在中盐时对磷酸二铵的水解表现出促进效应,中盐处理磷酸二铵净水解量较低盐、高盐处理分别提高33.6%和4.3%。②土壤高盐分会抑制硝化反应的开始,高盐处理相较低盐、中盐处理推迟3 d左右;土壤盐分升高对两种氮肥净硝化量的影响均表现为先促进后抑制的作用,中盐处理尿素的净硝化量,较低盐、高盐处理分别提高了8.6%和9.1%,中盐处理磷酸二铵的净硝化量,较低盐、高盐处理分别提高了19.1%和5.1%。③在等氮输入条件下,各土壤盐分梯度下磷酸二铵处理转化产生的铵态氮、硝态氮、无机氮均高于尿素处理。土壤盐分含量对化肥氮转化影响显著,不同肥料种类其影响存在差别;土壤盐分升高对肥料养分的释放存在抑制,适量的土壤盐分会促进硝化作用,这增加氮素淋溶损失的风险。 相似文献