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1.
玉米生长后期的根系分布研究   总被引:2,自引:2,他引:0       下载免费PDF全文
为了研究玉米生长后期根系的生长发育规律,利用中国气象局固城农业气象试验站大型根剖面系统,采用微根管观测系统及方形整段标本法和地下根系室玻璃窗,对‘屯玉46号’玉米根系的生长状况进行了试验研究。结果表明:垂直方向上,方形整段标本法和微根管法测得的根长密度占整层总根长密度比例的变化趋势一致,相关系数分别为0.987和0.717,且两种方法在0~20 cm土层的根长密度比例均为最大。0~60 cm土层为玉米根系生长活跃区,方形整段标本法测得根长密度生长量为其余层的4倍。两种方法测得的根长密度无显著差异,相关系数为0.830,均匀性水平较好。玉米成熟期根系的水平幅度较乳熟期窄,下层根系仍处于生长中,垂直深度增加。玻璃窗与方形整段标本法观测的根深测定结果存在差异,这可能与观测环境条件不一致有关。  相似文献   

2.
为探究耕作方式和秸秆还田对春玉米产量、土壤水肥及根系分布的影响,通过连续两年设置耕作方式(旋耕、翻耕)与秸秆还田方式(秸秆还田、秸秆不还田)两因素田间定位试验,研究了春玉米产量和水分利用效率、根系及土壤水肥分布的特性。结果表明:旋耕和翻耕处理春玉米产量和水分利用效率差异不显著,但前者显著增加了干旱年份(2015年)0—30cm土层的根长密度、根表面积密度和根干重密度,而后者显著降低了10—30cm土层的土壤容重和紧实度,降低了0—40cm土层的土壤含水量、有效磷和速效钾含量,提高了干旱年份30—60cm和湿润年份(2016年)0—60cm土层的根长密度、根表面积密度和根干重密度;秸秆还田较秸秆不还田处理显著增加了春玉米产量和水分利用效率,增加幅度分别为9.5%和7.3%,促进了干旱年份0—60cm土层的根长密度和湿润年份30—60cm土层的根长密度、根表面积密度和根干重密度的增加,还提高了0—60cm土层的土壤含水量、硝态氮、有效磷和速效钾含量。因此,实施旋耕秸秆还田和翻耕秸秆还田可以改善土壤水肥分布,促进深层根系发育,提高春玉米的产量和水分利用效率。  相似文献   

3.
通过玉米单作、大豆单作和玉米大豆间作种植,利用WINRHIZ软件分析不同种植模式下0—10cm,10—20cm,20—30cm不同深度土层的作物根系的根系密度、根长、根表面积等根系特征指标,并采用湿筛法对各个土层团聚体稳定性进行分析,研究根系特征对团聚体稳定性的影响。结果表明:单间作条件下,玉米和大豆的根系密度、根长、根表面积、根长密度、根体积等随着土层深度的增加而减少,间作模式下根系密度、根体积在0—10cm土层分别比单作增加了14.79%和11.74%。间作模式下各土层团聚体平均重量直径和平均几何直径显著高于单作模式,团聚体破坏率、可蚀性因子K值、分形维数(D)显著小于单作模式,0—10cm土层差异表现为极显著,充分说明间作模式下团聚稳定性优于单作模式。且以上指标在0—10cm土层内差异最显著,随土层深度增加差异呈减小趋势;通过相关性分析,团聚体破坏率与根体积,根尖数呈显著负相关,与根长,根表面积,根长密度,根杈数极显著相关,说明根长、根长密度、根表面积和根杈对提高团聚体稳定性具有一定作用。因此,间作模式可通过增大根表面积、根长等改变根系特征,从而提高土壤团聚体稳定性。  相似文献   

4.
膜下滴灌不同灌水定额对玉米根系生长的影响   总被引:2,自引:0,他引:2  
玉米根系的分布特征受多种因素的制约,其中影响最大的有土壤水分和生育期阶段等,通过分析不同灌水处理条件下,不同生育期,土壤深度与根长密度和根重密度的关系,研究膜下滴灌玉米各生育期根系在不同灌水定额处理下的分布规律,利用大田代表植株挖根试验得到的实测数据进行根长密度和根重密度计算。结果表明:根长在表层土壤中,随着水分的胁迫减轻,呈现增大趋势,深层反之,而且最大根深出现在80cm处,在大喇叭期,处理1在20cm土层根长密度最小(77.27mm/cm3),处理9最大(143.31mm/cm3),在40cm土层,处理8的根长密度最小(16.11mm/cm3),处理1最大(24.89mm/cm3)。根重密度与根长密度的规律基本一致,水分胁迫能促进根系向下伸长,在玉米拔节期,处理1在20cm以上土层根干重仅占总根干重的67.9%,而处理9在20cm则达到了90.2%。随着生育期的推进,表层根重密度随灌水量增大而增大,在大喇叭期,处理1的根重密度为8.16×10-4 g/cm3,处理7为2.358×10-3 g/cm3。水分胁迫使得根系深扎吸取水分来补偿亏缺,并且根变得较细较小,这说明根系自身会做出水分适应性环境调整,以达到重要机制的平衡。  相似文献   

5.
在黄土高原子午岭林区,对油松人工林、白桦天然林细根生物量、比根长、根长密度和细根表面积的垂直分布特征,以及这些根系指标与土壤水分、土壤容重、氮素和有机质的关系进行了研究。结果表明,油松人工林细根生物量随土壤深度增加呈单峰曲线,白桦林细根生物量随土壤深度增加呈减少趋势;油松林大部分根系生物量集中分布在040.cm土层中,其中020.cm土层占37%以上,2040.cm集中了41%以上;表层土壤(020.cm)具有较高的比根长、根长密度和细根表面积,而底层(4060.cm)的比根长、根长密度和细根表面积最低。油松林土壤全氮和有机质含量垂直变化趋势相似,随土壤深度的增加而降低;硝态氮(NO3--N)均随土壤深度的增加呈单峰曲线变化趋势,而铵态氮(NH4+-N)随土壤深度增加呈先降低后增加的抛物线趋势。白桦林75%的细根生物量集中在020.cm土层,比根长、根长密度和细根表面积的垂直分布规律与油松林相似,表层土壤白桦林细根表面积是油松人工林的3.91倍,而2040.cm土层白桦林细根表面积比油松人工林降低了33%。白桦林土壤全氮、有机质含量、NO3--N和NH4+-N垂直变化趋势与油松林相似。土壤水分、容重、全氮和有机质对油松和白桦细根分布的影响明显大于NH4+-N和NO3--N。白桦林表层土壤有机质含量与细根生物量的相关性达到显著水平(r=0.99,P0.05),白桦林表层土壤有机质含量与比根长和根长密度的相关性(分别为r=0.91,r=0.8)低于油松林(分别为r=0.95,r=0.94)。油松和白桦林040.cm土层细根表面积与土壤全氮相关性随土壤深度增加而下降,比根长和根长密度与土壤全氮相关性随土壤深度增加而增大。油松和白桦林2060.cm土层细根生物量、细根表面积和根长密度随有机质含量的减少而增加,而比根长呈相反的变化规律。  相似文献   

6.
覆膜和灌水量对制种玉米根系分布及产量的影响   总被引:1,自引:1,他引:0       下载免费PDF全文
为探究制种玉米根系分布及产量对滴灌条件下地膜覆盖和灌溉量的动态响应,该研究于2017年和2018年在中国西北旱区石羊河流域,以制种玉米"Ganxin 630"为供试作物,设置覆膜与灌溉水量2个控制因素,覆膜包括透明膜全覆盖(M1)和不覆膜(M0)2个水平,灌溉水量设置WF、WM和WL 3个水平(分别为灌溉需水量的100%、70%和40%),共6个处理,通过监测制种玉米生育期内的土壤水分、土壤温度、根长密度、地上干物质量和产量状况,分析不同覆膜和灌水量条件下土壤水热动态、制种玉米根长密度分布和产量的变化规律。结果表明,在相同覆膜条件下,0~60 cm土层含水量随灌溉量的增加而增加。覆膜可改善土壤水热条件,在充分灌溉下覆膜增加土壤贮水量,而亏缺灌溉下覆膜降低土壤贮水量。覆膜明显提升播种后75 d内的土壤温度,对播种后75 d之后的土壤温度没有影响。制种玉米各个生育期不同覆膜和灌水量处理下的根长密度均随着土层深度的加深而降低,播种后95 d时,86.3%~96.7%的根系分布在0~60 cm土层,其中土层深度0~30 cm和距离植株基部水平方向0~15 cm范围内的根长密度高于1.0 cm/cm3,此空间范围以外则低于1.0 cm/cm3。充分灌溉有利于浅层根系生长,而水分亏缺有利于深层根系生长,其中WL处理10 cm深度处的根长密度比WF处理在各个生育期低19.6%~32.5%,深层根长密度则高0.2%~41.9%,产量和地上生物量基本随灌溉量的增加而增加。覆膜10 cm深度处的根长密度比不覆膜在各灌水处理下高4.4%~69.2%,产量高24.9%。制种玉米地上干物质量、产量与播种后75和95 d的0~20 cm土层的根长密度的关系较为密切,相关系数分别达0.883、0.804以上,保证该阶段良好的土壤环境、促进根系生长对制种玉米的生长至关重要。该研究可为石羊河流域科学地进行灌溉和和覆膜管理提供理论依据。  相似文献   

7.
【目的】研究幼树期库尔勒香梨根系分布特征,为制定科学高效的水肥管理措施提供理论依据。【方法】在南疆选择大水漫灌果园,选取1~6年生库尔勒香梨各3株为试材,在树干周围半径160 cm,挖掘0—100 cm深剖面,每20 cm取1个样品,利用WinRHIZO根系分析系统测定不同径级梨树根系根长、根表面积、根体积。【结果】梨树根长增长始终以吸收根为主,吸收根根长占总根长的86%~95%,且3、5、6年树龄根长显著增长。根表面积增长是不同径级根系共同作用的结果,其中吸收根根表面积占比为41%~77%,输导根占比22%~33%。根体积增长以粗根和输导根为主,4、6年粗根增长较快,3、5年输导根增长较快,两类根体积增长不同步。梨树根长密度整体上随土层加深先增大后减小,呈“单峰型”变化,随水平距离增加而减小。垂直方向上根长主要分布在0—60 cm深土层,占整个采样剖面总根长的76.46%以上;水平方向上,以0—20 cm土壤根长密度占比最高,1年和2年占比分别为71.93%、41.62%,随树龄增长呈下降趋势。2~4年,梨根系密度增幅较小,主要表现为延伸生长,并在距离树干较远处形成分散的根密集区。6...  相似文献   

8.
红壤丘陵区林地根系对土壤抗冲增强效应的研究   总被引:17,自引:5,他引:12  
对不同林地根系分布特征及其对土壤抗冲增强效应进行研究,结果表明:毛竹林根系的63%集中在0~30cm土层;混交林有64%的根系分布在0~20cm土层;杉木林0~20cm土层中有占总根数42%的根系;柑橘林41%的根系分布在0~10cm土层,各林区根系随土层深度增加而迅速减少。根系对土壤抗冲性增强值表现出随土层深度增加而减小,同时也得出根系对土壤抗冲性增强值在小雨强下>中雨强下>大雨强下。直径≤1mm根系密度与土壤抗冲性增强值相关性达到极显著水平,并得出它们之间的函数关系。土壤抗冲性随冲刷历时的增加而迅速增强,增强值的大小表现出毛竹林>混交林>杉木林>柑橘林。  相似文献   

9.
陕北毛乌素沙漠黑沙蒿根系分布特征研究   总被引:5,自引:0,他引:5  
研究沙生植物根系空间分布特征对制定沙质困难立地植被恢复与重建技术路线,选定适宜树种,提高造林成活率、保存率和效益,都会起到非常重要的作用.采用埋置网状沙袋土芯、分层挖掘、根系分析系统等方法对毛乌素沙地主要优势植物黑沙蒿的根系生长和分布特征进行了测定,结果表明:(1)不同年龄的黑沙蒿根系生物量变化范围及其在各土层中的分布规律各不相同.黑沙蒿根系生物量随着树龄的增加而增加,在一定时期达到最大值,然后逐渐下降并趋于稳定;其根系分布也随年龄的增加向深层土壤延伸,在垂直方向上,根生物量随深度增加呈指数递减.1~5年生黑沙蒿根系生物量主要分布在0-60 cm土层,占总根系生物量百分比分别为99.06%、97.71%、94.31%、93.82%、84.35%.0-20 cm土层根系生物量占根总生物量百分比随着树龄的增加逐渐减小,20-60 cm土层的根系生物量百分比则随着树龄的增大先增大后减少.(2)黑沙蒿根长的变化特征与其根生物量的分布规律较为相似,随着年龄的增加不同土层间根长的变幅增大,但随着土壤深度的增加沙蒿根长呈指数甬数模式递减.(3)1~5年生黑沙蒿比根长在0-200 cm 土层平均比根长随着树龄的增加而减小,1年生黑沙蒿的比根长最大,5年生黑沙蒿用以构建根系的碳投人最多,比根长最小.黑沙蒿用以构建根长的生物量投入效率也随着年龄的增加而减小.同龄黑沙蒿在不同土层的比根长也各不相同,不仅说明了植物对其生存环境具有较高的可塑性,也反映了土壤环境条件存在差异.  相似文献   

10.
在水分亏缺和正常供水(土壤含水量分别维持在田间持水量的40%~45%和75%~80%)两种水分条件下,采用土柱实验方法,研究了玉米杂交种户单四号(F1)及其父本803(♂)、母本天四(♀)根系剖面分布对水分亏缺的响应.结果表明:水分亏缺除了对父本的总根重无显著影响之外,使杂交种和母本的总根重以及3个品种的总根长和根系总表面积均显著下降.在剖面分布上,水分亏缺显著降低了杂交种和母本在表层土层中的根重和根表面积.使杂交种在表层和中层土层中的根长以及亲本在深层土层中的根长显著下降.可见,玉米杂交种响应中度干旱胁迫的形态学变化是减少上层干土中的根系生长,而增加深层土层中根系的相对生长,即其深层根系分布占总根系的比重较亲本高,这种根系剖面分布的优化导致杂交种较高的生物量积累和水分利用效率.  相似文献   

11.
开展根系生物量的观测和研究,建立通用性的根系生物量模型对于开展生态系统生物量的监测和评估具有重要意义。为得到根系生物量的实时信息,2016年9月末利用挖土法和根系扫描系统,获取玉米根系的生物量及生态指标,分析了玉米根系生物量的垂直分布特征并建立了根系生物量与根系生态指标之间的模拟方程。结果表明:玉米根系生物量主要集中于0~30 cm,占玉米根系垂直分布量的94.44%。利用普通最小二乘法建立根系生物量模型均存在异方差问题,增加根长作为自变量建立的根系生物量模型显著提高了模拟精度,决定系数(R2)达0.91以上。采用对数转换消除方程的异方差及比较不同的模拟方程后发现,玉米根系生物量与根径和根长的组合变量(D2H)建立的指数函数是模拟玉米根系生物量的最优方程,决定系数(R2)最高,为0.90,平均绝对误差(MAE)、估计值的标准误差(SEE)、平均预估误差(MPE)均最小,满足了模拟方程的精度要求。对该方程进一步验证发现,模拟值和实测值之间的相关系数为0.92,说明此模型能较好地模拟根系生物量。利用根系生物量模型结合微根管法,可解决根系生物量实时观测难的问题。  相似文献   

12.
局部水分胁迫对玉米根系生长的影响   总被引:2,自引:0,他引:2  
采用分根法进行玉米水培试验, 研究局部水分胁迫对玉米根系生长的影响。设4个水分胁迫水平: CK, 0.2 MPa, 0.4 MPa, 0.6 MPa, 在整个根系经受一定的水分胁迫之后对部分根系复水处理, 测定局部供应后 0 h、6 h、12 h、1 d、3 d、5 d、7 d、9 d等不同时期各部分根系的面积、长度及干重。结果表明, 各胁迫程度均表现为, 与对照相比, 复水侧根区的根系面积、根长与根干重出现了明显增长, 且始终显著大于持续胁迫侧根区, 且随处理时间延长更加明显。不同胁迫程度下复水侧玉米根系的增长幅度不同。水分胁迫预处理后, 0.2 MPa水平下, 复水侧根区根系的面积、长度与干重以及整个根区总根长、总面积均可以达到甚至高于对照水平, 其他处理均显著低于对照。轻度胁迫后复水的根区根系产生明显的补偿效应。适度胁迫后复水有利于作物根系总面积增长, 但对总根长、根干重无显著影响。根系补偿效应与胁迫强度及复水的时间有关。  相似文献   

13.
A method of processing soil core samples for root studies by subsampling   总被引:2,自引:0,他引:2  
Root studies are generally believed to be very important in ecological research. Soil coring is a valuable approach to root research, but it requires a very large amount of processing time. We present here a method for processing soil cores consisting of the combination and homogenization of several soil cores from a plot, with subsequent subsampling for root extraction. The required subsample size was determined for a topsoil and a subsoil sample from a groundnut field and was found to be 5–10% of the total soil sample. Advantages and limitations of the method are discussed.  相似文献   

14.
Global atmospheric nitrogen deposition has increased steadily since the 20th century, and has complex effects on terrestrial ecosystems. This work synthesized results from 54 papers and conducted a meta-analysis to evaluate the general response of 15 variables related to plant root traits to simulated nitrogen deposition. Simulated nitrogen deposition resulted in significantly decreasing fine root biomass (<2 mm diameter; −12.8%), while significantly increasing coarse root (≥2 mm diameter; +56.5%) and total root (+20.2%) biomass, but had no remarkable effect on root morphology. This suggests that simulated nitrogen deposition could stimulate carbon accumulation in root biomass. The root: shoot ratio decreased (−10.7%) suggests that aboveground biomass was more sensitive to simulated nitrogen deposition than root biomass. In addition, simulated nitrogen deposition increased the fine root nitrogen content (+17.6%), but did not affect carbon content, and thus decreased the fine root C:N ratio (−13.5%). These changes delayed the decomposition of roots, combined with increasing of the fine root turnover rate (+21.4%), which suggests that simulated nitrogen deposition could increase carbon and nutrient retention in the soil. Simulated nitrogen deposition also strongly affected the functional traits of roots, which increased root respiration (+20.7%), but decreased fungal colonization (−17.0%). The effects of simulated nitrogen deposition on the plant root systems were dependent on ecosystem and climate zone types, because soil nutrient conditions and other biotic and abiotic factors vary widely. Long-term simulated experiments, in which the experimental N-addition levels were less than twofold of the average of atmospheric nitrogen deposition, would better reflect the response of ecosystems under atmospheric nitrogen deposition. These results provide a synthetic understanding of the effects of simulated nitrogen deposition on plant root systems, as well as the mechanisms underlying the effects of simulated nitrogen deposition on plants and the terrestrial ecosystem carbon cycle.  相似文献   

15.
The presence of vegetation increases soil burden stability along slopes and therefore reduces soil erosion. The contribution of the vegetation is due to mechanical (reinforcing soil shear resistance) and hydrologic controls on stream banks and superficial landslides. This study focused on the biotechnical characteristics of the root system of three shrub species: Rosa canina (L.), Cotoneaster dammeri (C.K. Schneid) and Juniperus horizontalis (Moench). The aim of this paper is to increase our understanding on root biomechanical properties of shrubs species and their contribution to soil reinforcement. The considered shrubs grew up in wood containers, exposed to natural conditions in a village near Asti (Northern Italy) for 2 years. Laboratory tests were conducted to measure the ultimate root tensile strength and to estimate the root density distribution with depth (root area ratio), in order to quantify the soil mechanical reinforcement. Root tensile strength measurements were carried out on single root specimens and root area ratio was estimated analyzing the whole root system. The improvement of soil mechanical properties obtained by the presence of shrubs was estimated using two different models. The first model, based on a simple force equilibrium model, considers that the tensile strength of all roots crossing the shear plane is fully mobilized. This classical approach is implemented by the Fiber Bundle Model concept, to account for non-simultaneous root breaking. C. dammeri roots presented the highest tensile strength and soil reinforcement values, while R. canina and J. horizontalis were characterized by lower values. Similarly at each considered depth C. dammeri showed the highest soil reinforcement effect.  相似文献   

16.
A protocol is described for non-destructive visualization and quantification of roots for relatively large core using computed tomography (CT) and computer codes developed to isolate and analyze the CT matrices. The scanner settings were optimized using a phantom core filled with different soil and materials (including root segments) of known geometry and orientation. CT parameters were optimized (130 kV peak voltage and 480 mAs), using a core 0.23×0.14 m diam. filled with a single grain sand scanned at a voxel resolution of 275×275×1000 μm. Quantitative attributes of the roots of chickpea 21 days after germination such as the number of root laterals, their volume, length, wall area, tortuosity and orientation are presented and compared with results obtained by destructive sampling. Results suggest the CT approach systematically underestimated root length compared to destructive sampling (difference reaching up to 10%). The average root segment length estimated by the non-destructive algorithm was 28.1 mm compared to 36 mm by destructive analysis. However, the non-destructive approach revealed details that are not possible to obtain with invasive techniques. For instance, the root laterals had an average tortuosity of 2.5 indicating that their length was 2.5 greater than the distance between their extremities.  相似文献   

17.
不同养分与水分管理对水稻植株根系形态及其活力的影响   总被引:15,自引:2,他引:13  
室内盆栽试验研究不同养分与水分管理模式对水稻植株根系形态及其活力的影响结果表明 ,干湿交替模式和控制水分灌溉模式采用厩肥 化肥配施处理水稻植株根系平均活跃吸收面积分别比单施化肥处理高 19.3%和 2 8 2 % ;平均根系活力分别高 2 3.7%和 37.9%。而连续淹水模式则削弱有机与无机肥配施对水稻植株根系形态及其活力的改善效果。厩肥 化肥配施处理可显著提高水稻中后期植株根表磷酸酶活性 ,尤以控制水分灌溉模式采用有机与无机肥配施比单施化肥处理高 4 4 .7%。  相似文献   

18.
不同种植模式对土壤质量及马铃薯生长的影响   总被引:1,自引:0,他引:1  
为探究轮作藜麦、玉米及连作对马铃薯根系生理及根系发育的影响及其机制,比较了3种种植模式(轮作藜麦、轮作玉米及连作)对马铃薯根际土壤微环境、根系生理、根系发育及植株生长的影响,以期为减轻马铃薯连作障碍、筛选较好的轮作模式提供理论依据。结果表明:(1)轮作藜麦、玉米明显降低土壤pH,提高土壤中有机质、碱解氮和有效磷含量,增强土壤肥力相关酶的活性,增加土壤细菌、放线菌数量和细菌与真菌数量比值(B/F),降低真菌数量,改善马铃薯根际土壤微环境,对植株生长发育起到促进作用,表现在马铃薯的株高、茎粗、地上部干重、根干重、单株薯重均有一定程度的增加。(2)轮作藜麦、玉米使得马铃薯根系超氧化物歧化酶(SOD)、过氧化物酶(POD)和过氧化氢酶(CAT)活性上升,超氧阴离子产生速率下降,丙二醛(MDA)含量减少,渗透调节物质含量增加,表明通过轮作藜麦和玉米使得连作对马铃薯植株造成的胁迫得到了一定程度缓解。(3)轮作藜麦、玉米显著提高了马铃薯根系总根长、根表面积、根体积、根平均直径和根尖数,说明轮作藜麦及玉米促进了马铃薯根系的生长发育,这与轮作藜麦及玉米改善土壤理化性质、生物学性质及促进马铃薯地上部分的发育相对应。比较轮作藜麦及轮作玉米的整体表现,以轮作玉米调控马铃薯连作障碍的效果较好。  相似文献   

19.
Impact of tillage on maize rooting in a Cambisol and Luvisol in Switzerland   总被引:3,自引:0,他引:3  
Soil conditions under no-tillage (NT) are often unfavorable for the growth of maize roots in comparison to conventional tillage (CT). In 1997 and 1999, the impacts of tillage on the morphology and spatial distribution of maize (Zea mays L.) roots at anthesis were investigated in a 5-year field trial at two sites (loamy silt and sandy loam soils) in the Swiss midlands. Four soil cores, perpendicular to the maize row, were taken to a depth of 100 cm in each plot; the root length density (RLD), the mean root diameter (MD), and the relative length per diameter-class distribution (LDD) of the roots were determined.

Roots were longer and thinner in 1999 than in 1997. The RLD was significantly higher and the MD was smaller on the loamy silt than on the sandy loam. The RLD and MD decreased with the distance from the plant row. Most of the maize roots, about 80% of the total root length, were in the layer from 0 to 40 cm, with maximum values from 5 to 10 cm; the thickest roots were in the soil layer from 10 to 50 cm. Significant differences in RLD with increasing distance from the row of plants were found in the top 30 cm.

Averaged over the whole soil profile, RLD was higher and MD was smaller under CT than under NT. The impact of tillage on RLD and MD interacted with spatial factors and years. Within the soil profile, RLD was significantly higher under NT than under CT at a depth of 5 cm, whereas it was higher under CT than under NT below 10 cm. Below 50 cm, there was no difference in RLD between the tillage systems. In a horizontal direction, MD was consistently higher in the row and lower in the mid-row under NT than under CT.

Our results show that differences in maize root growth between tillage systems, which were reported in previous studies, persist until anthesis. The accumulation of maize roots near the soil surface in NT suggests that subsurface-banding of starter fertilizer is a more efficient way of applying fertilizer (particularly immobile nutrients such as phosphorus) compared with broadcasting in order to supply sufficient nutrients for NT maize.  相似文献   


20.
不同硼效率棉花品种根系参数和伤流液组分的差异   总被引:4,自引:0,他引:4  
溶液培养条件下研究硼对不同硼效率棉花品种根系参数、伤流量及伤流液组分的影响。结果表明,缺硼抑制棉花根系生长,根重、根体积、根长、活跃吸收面积、总吸收面积、活跃吸收面积占总吸收面积的比例以及伤流量均显著降低,高效品种降低幅度比低效品种小;缺硼还使高效品种根系比表面积升高,而低效品种无显著变化。缺硼显著影响不同棉花品种伤流液各组分含量,与低效品种相比,高效品种伤流液中有较多的NO3-、K+、无机磷、可溶性糖和游离氨基酸。说明缺硼条件下高效品种根系比低效品种具有更强的吸收、代谢活力,可能是其硼效率较高的主要原因之一。  相似文献   

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