Effect of Long-Term Application of K Fertilizer and Wheat Straw to Soil on Crop Yield and Soil K Under Different Planting Systems

Effect of application of K fertilizer and wheat straw to soil on crop yield and status of soil K in the plough layer under different planting systems was studied. The experiments on long-term application of K fertilizer and wheat straw to soil in Hebei fluvo aquic soil and Shanxi brown soil in northern China were begun in 1992. The results showed that K fertilizer and straw could improve the yields of wheat and maize with the order of NPK ＋ St 〉 NPK 〉 NP ＋ St 〉 NP, and treatment of K fertilizer made a significant difference to NP, and the efficiency of K fertilizer in maize was higher than in wheat under rotation system of Hebei. In contrast with Shanxi, the wastage of soil potassium was a more serious issue in the rotation system in Hebei, only treatment of NPK ＋ St showed a surplus of potassium and the others showed a wane. K fertilizer and straw could improve the content of water-soluble K, nonspecifically adsorbed K, non-exchangeable K, mineral K, and total K in contrast to NP; however, K fertilizer and straw reduce the proportion of mineral K and improve proportion of other forms of potassium in the two locating sites. Compared with the beginning of orientation, temporal variability character of soil K content and proportion showed a difference between the two soil types; furthermore, there was a decrease in the content of mineral K and total K simultaneously in the two locating sites. As a whole, the effect of K fertilizer applied to soil directly excelled to wheat straw to soil. Wheat straw to soil was an effective measure to complement potassium to increase crop yield and retard the decrease of soil K.

Effects of Interaction of Soil Moisture and Organic Matter on Powdery Mildew Disease and Growth of Heracleum moellendorffii Hance

Taking annual Heracl'eum moellendorffii Hance as the material,this research studied the epidemic dynamics of H.moellendorffii Hance powdery mildew and plant growth by using the interactive methods of soil moisture and soil organic matter.The results showed that the interaction of higher soil moisture content(60%-80%)and soil organic matter content(75-100 g•kg^(-1))had few diseases,dosease index and area under disease progression curve(AUDPC)compared with those of other treatments,thus could effectivley control powdery mildew disease.Moreover,higher soil moisture and organic matter content increased the yield,contents of soluble sugar,soluble protein,vitamin C and coumarin in H.moellendorffii Hance.

Growth Parameters of DK8031 Maize Variety as Affected by Varying Irrigation and Nitrogen Fertilizer Rates in Embu County, Kenya

Determination of crop growth parameters of maize helps assess the performance of the crop for food security. A study was conducted in two seasons covering 2012 and 2013 to establish optimal irrigation and nitrogen fertilizer rates for drought tolerant hybrid maize （Zea mays L.）, DK8031 variety, in sandy loam soils using furrow irrigation. Four additive irrigation levels （119.05 mm, 238.10 mm, 357.15 mm and 476.2 mm） were allocated the main plots while five nitrogen fertilizer rates （0 kg/ha, 60, 75 kg/ha, 90 kg/ha and 100 kg/ha） were allocated the sub-plots. Both irrigation and nitrogen fertilizer treatments significantly enhanced crop growth parameters under consideration. Stand count per treatment plot, plant height and number of leaves per ranged from 45-59 plants/plot, 215-238 cm and 14-16 leaves respectively. It was concluded that use of supplementary irrigation and phased nitrogen fertilizer rates for maize growing in areas such as Embu can greatly promote crop growth.

绿洲灌区密植对氮肥减量玉米产量的补偿潜力

【目的】针对绿洲灌区玉米生产氮肥用量过高的问题,探究通过密植补偿氮肥减量对玉米产量负效应的可行性。【方法】2019—2021年,以施氮水平为主区,设地方习惯施氮(N_(2),360 kg·hm^(-2))、减量25%施氮(N_(1),270 kg·hm^(-2))两个水平;以种植密度为副区,设传统(M_(1),7.8万株/hm^(2))、中(M_(2),10.4万株/hm^(2),增密33%)、高(M3,12.9万株/hm^(2),增密66%)3个密度水平,进行裂区试验,重点研究氮肥减量条件下增密对玉米产量及其构成因素的影响。【结果】(1)氮肥减量导致玉米籽粒产量、生物产量分别降低4.0%、4.9%。减氮条件下,中密度可以产生籽粒产量补偿效应,N_(1)M_(2)较对照N_(2)M_(1)提高4.1%;高密度处理N_(1)M3生物产量补偿效应最大,较对照提高14.2%。(2)通过回归分析模拟得到:减氮条件下,当种植密度提高至8.4万株/hm^(2)可以与对照N_(2)M_(1)籽粒产量持平,并在10.6万株/hm^(2)时获得最大产量13537kg·hm^(-2),较对照提高4.9%。(3)氮肥减量引起穗数、穗粒数和千粒重分别降低5.0%、3.3%和3.4%;中、高密度分别较传统密度提高穗数27.9%、49.7%,降低穗粒数3.8%、8.4%,降低千粒重5.2%、8.9%。中密度较传统密度对收获指数无显著影响,而高密度使收获指数降低14.2%。N_(1)M_(2)较对照N_(2)M_(1)通过穗数增加补偿了减氮引起穗数、穗粒数及千粒重的下降,从而实现丰产。(4)氮肥减量降低拔节期至抽雄吐丝期的玉米生长率7.2%—8.4%;中、高密度较传统密度提高苗期至大喇叭口期玉米生长率27.3%、60.3%。(5)氮肥减量条件下,N_(1)M_(2)较对照提高叶、茎和鞘干物质转运量达9.6%、13.6%和3.7%,提高叶和茎对籽粒产量的贡献率5.3%和9.0%。【结论】通过合理密植可以补偿减氮引起的玉米产量下降,在施氮量270 kg·hm^(-2)的基础上增密至10.4万株/hm^(2),能够最大化产量补偿效应,是绿洲灌区玉米节氮稳产丰产的可行措施。

基于亏缺灌溉的利津县多目标种植结构优化研究

针对利津县当地灌溉水资源远远不能满足农田灌溉用水的难题,采用亏缺灌溉的调控方式控制作物生育期灌溉用水量,选取作物经济效益、综合水分生产力、生态效益最大为目标,运用多目标优化模型(AE-FOS-MOP)进一步对利津县不同水平年下的农作物进行种植结构调整。研究表明:①亏缺灌溉方式下,灌溉水量仍不能满足农田灌溉用水需求,但显著缓解了灌溉水供需矛盾。②在保证粮食安全生产的前提下,不同水平年下模型优化的结果有效地调整了粮经作物的比例并实现了节约耕地。③现状年(2022年)通过调减冬小麦、水稻、玉米、棉花的播种面积,增加花生的播种面积,可实现经济效益提升1.9%,综合水分生产力提升4.5%,生态效益提升3.1%。④规划年(2025、2035年)进一步增加蔬菜、花生的种植规模,经济效益分别提升9.5%、14.3%,生态效益分别提升16.9%、14.1%,综合水分生产力分别提升2.1%、5.0%,节水率分别为8.2%、5.5%。

冬小麦-夏玉米周年“四密一稀”浅埋滴灌水肥药一体化绿色生产技术

本研究针对黄淮海冬小麦-夏玉米两熟区面临的出苗质量、播种—出苗期水分供应、灌溉施肥及时性及技术粗放等问题,并就进一步提高光温水肥资源利用效率是实现该区域粮食单产提升和绿色发展的重要途径等,从2018年起开展了一系列创新研究。通过实施冬小麦“四密一稀”条带种植配套卫星导航播种技术、冬小麦-夏玉米周年浅埋滴灌水肥药一体化技术等关键核心技术,结合配套现代化农机与信息技术装备,形成了一套集成的“冬小麦-夏玉米周年‘四密一稀’浅埋滴灌水肥药一体化绿色生产技术”。2010—2023年田间示范表明,该技术有效解决了上述生产难题,达到了小麦玉米周年增产和水肥资源高效利用的目标。与农民传统相比,小麦增产9%~17%,玉米增产12%~14%,周年节水450~750 m^(3)/hm^(2),节肥20%,节约人工成本2250~3000元/hm^(2)。该技术为黄淮海区冬小麦-夏玉米周年绿色高产提供了新的可行性方案。

日光温室长期施肥条件下耕层土壤计量化学变化特征

【目的】施肥是保持设施蔬菜地土地生产力的重要措施,但长期高量水肥条件下土壤中碳、氮和磷的化学计量特征并不清楚。【方法】本试验采用室外调查采样结合化验分析的方法,研究褐土区蔬菜保护地不同年限(5、15、20、30a)和大田土壤主要养分碳、氮和磷的化学计量特征。【结果】(1)不同种植年限随着年限增加土壤表层有机质量先增加后降低并趋于稳定,15 a时有机质量达到最大值,比大田增加99.4%;土壤全氮量和全磷量随年限增加整体变化趋势类似有机质量,各年限土壤全氮量和全磷量分别是大田的1.4~2.6倍和1.7~4.5倍,全氮量15 a达最高,而20 a种植年限的全磷量最高。(2)与大田相比,不同种植年限土壤C∶N、N∶P和C∶P化学计量比均随年限增加而递减并趋于稳定,变化分别在8.7~10.3、1.2~1.6和7.7~15.6范围内。土壤表层C、N、P量的增加速度排序为P>N>C,表现为化学计量比C∶P变异最大,N∶P次之,C∶N变异较小。【结论】尽管大棚内肥料投入较高,但目前该褐土区域土壤C∶N、C∶P和N∶P化学计量比在一定范围内维持相对稳定。从长远来看,针对本研究设施蔬菜地磷的持续快速积累而碳相对不足的问题,应采取降低磷肥施用量、控制氮肥、增施有机肥尤其是C∶N比高的有机肥等措施,以阻控C∶P进一步下降,维持C∶N和N∶P的平衡。

The priority of management factors for reducing the yield gap of summer maize in the north of Huang-Huai-Hai region, China

Understanding yield potential, yield gap and the priority of management factors for reducing the yield gap in current intensive maize production is essential for meeting future food demand with the limited resources. In this study, we conducted field experiments using different planting modes, which were basic productivity(CK), farmer practice(FP), high yield and high efficiency(HH), and super high yield(SH), to estimate the yield gap. Different factorial experiments(fertilizer, planting density, hybrids, and irrigation) were also conducted to evaluate the priority of individual management factors for reducing the yield gap between the different planting modes. We found significant differences between the maize yields of different planting modes. The treatments of CK, FP, HH, and SH achieved 54.26, 58.76, 65.77, and 71.99% of the yield potential, respectively. The yield gaps between three pairs: CK and FP, FP and HH, and HH and SH, were 0.76, 1.23 and 0.85 t ha^(–1), respectively. By further analyzing the priority of management factors for reducing the yield gap between FP and HH, as well as HH and SH, we found that the priorities of the management factors(contribution rates) were plant density(13.29%)>fertilizer(11.95%)>hybrids(8.19%)>irrigation(4%) for FP to HH, and hybrids(8.94%)>plant density(4.84%)>fertilizer(1.91%) for HH to SH. Therefore, increasing the planting density of FP was the key factor for decreasing the yield gap between FP and HH, while choosing hybrids with density and lodging tolerance was the key factor for decreasing the yield gap between HH and SH.

Cotton Response to Variable Nitrogen Rate Fertigation through an Overhead Irrigation System

Recent increases in irrigated hectares in the Southeastern US have enabled growers to obtain higher yields through applying nutrients through irrigation water. Therefore, many growers apply nutrients through irrigation systems, known as fertigation. Currently, there are no practical decision-making tools available for variable-rate application of nitrogen (N) through overhead sprinkler irrigation systems. Therefore, field tests were conducted on cotton (Gossypium hirsutum L.) during the 2016 and 2017 growing seasons to 1) adapt the Clemson sensor-based N recommendation algorithms from a single side-dress application to multiple applications through an overhead irrigation system;and 2) to compare sensor-based VRFS with conventional nutrient management methods in terms of N use efficiency (NUE) and crop responses on three soil types. Two seasons of testing Clemson N prediction algorithms to apply multiple applications of N were very promising. The multiple applications of N compared to the grower’s conventional methods (even though less N was applied) had no impact on yields in either growing season. There was no difference in cotton yields between 101 and 135 kg/ha N applications in either management zone. Also, there were no differences in yield between sensor-based, multiple N applications and conventional N management techniques. In relation to comparisons of the sensor methods only applying N in three or four applications, statistically increased yields compared to single or split applications in 2016. Applying N in four applications, statistically increased yields compared to single, split or triple applications in 2017. When the sensor-based methods were compared to the grower’s conventional methods averaged over four treatments, the sensor-based N applications reduced fertilizer requirement by 69% in 2016 and 57% in 2017 compared to grower’s conventional methods. When comparing N rates among the four sensor-based methods (three or four) applications, increased N rates by 22 kg/ha in 2016 and 26 kg/ha in 2017 compared to single or split applications but increased the cotton lint yields by 272 and 139 kg/ha, for 2016 and 2017, respectively.

不同种植密度对施氮条件下玉米灌浆期叶片光合特性的影响

明确不同种植密度对施氮条件下玉米灌浆期叶片光合特征的影响,对通过种植密度调控玉米个体光合作用与群体产量关系,实现玉米稳产丰产具有理论和实践指导意义。在甘肃河西走廊,通过3 a田间试验,以施氮360 kg/hm^(2)(N360)和不施氮(N0)为主区,玉米种植密度75000株/hm^(2)(D1)、87000株/hm^(2)(D2)和99000株/hm^(2)(D3)为副区,研究施氮条件下玉米灌浆期叶片光合特征对不同种植密度的响应。结果表明,试区玉米灌浆期光合有效辐射和大气温度最大值出现在14:00,最小值出现在6:00,而空气相对湿度最大值出现在6:00,最小值出现在14:00。施氮能够显著增加玉米灌浆期叶片净光合速率(P_(n))、叶片蒸腾速率(T_(r))和气孔导度(G_(s)),N360较N0在8:00-18:00的P_(n)平均增加19.5%~41.7%、T_(r)平均增加27.4%~44.1%、G_(s)平均增加27.4%~44.1%,但叶片胞间CO_(2)浓度(C_(i))显著降低;随着种植密度的增大,玉米灌浆期8:00―18:00的P_(n)、T_(r)、G_(s)呈降低趋势;N360D2与N360D1玉米灌浆期P_(n)差异不显著,显著大于其他处理。施氮水平和种植密度对玉米灌浆期8:00―16:00的叶片水分利用效率均无显著影响。N360较N0同时增加玉米籽粒产量和生物产量,但使玉米收获指数降低3.5%~5.3%;在N0中D2玉米籽粒产量大于D1和D3,而在N360中D2玉米籽粒产量与D3无显著差异,均显著大于D1;N360D2与N360D1的玉米籽粒产量无显著差异,均大于其他处理。总之,在施氮360 kg/hm^(2)条件下,种植密度从75000株/hm^(2)增加到87000株/hm^(2),能够使玉米灌浆期叶片光合速率保持在较高水平,提高收获指数,促进生物产量向籽粒产量的转化效率,获得最大籽粒产量。

氮磷钾肥不同组合对植烟土壤细菌群落结构的影响

施用氮磷钾肥能提高植烟土壤速效养分含量并影响土壤细菌多样性和群落结构。本研究采用高通量测序和RDA方法研究氮磷钾不同施肥组合对植烟土壤细菌多样性的影响,以期为施用氮磷钾肥调控土壤细菌多样性、改善土壤微环境提供理论依据。结果表明,移栽后30 d,施肥处理显著提高土壤细菌丰富度和多样性。移栽后90 d,NK处理相比于CK显著降低细菌多样性。移栽后30 d,在门水平上,施肥处理提高了放线菌门(Actinobacteria)、酸杆菌门(Acidobacteria)和芽单胞菌门(Gemmatimonadetes)等优势菌门的相对丰度,降低变形菌门(Proteobacteria)相对丰度。在属水平上,施肥处理提高罗河杆菌属(Rhodanobacter)、朱氏杆菌属(Chujaibacter)和Granulicella等优势菌属的相对丰度,降低新鞘氨醇杆菌属(Novosphingobium)和马赛菌属(Massilia)相对丰度。RDA分析表明,土壤pH值和速效养分对细菌群落结构组成影响显著,其中pH、碱解氮和速效磷是主要影响因子。关联分析表明,土壤细菌多样性与烟草农艺性状相关指标呈显著或极显著正相关,细菌群落结构组成与烟草生长发育密切相关。其中,放线菌门(Actinobacteria)相对丰度与烟草农艺性状相关指标呈显著或极显著正相关,苔藓杆菌属(Bryobacter)相对丰度与烟草农艺性状相关指标呈显著或极显著正相关,Ramlibacter属相对丰度与烟草农艺性状相关指标呈显著或极显著负相关。综上,氮磷钾肥不同组合对移栽后30 d土壤细菌的多样性影响较大,施肥提高了土壤细菌多样性和丰富度;施肥通过改变土壤pH值和速效养分影响细菌群落结构,细菌群落结构与烟草生长发育密切相关。

水肥耦合对南疆滴灌骏枣生长生理及产量的影响

为探索适宜滴灌骏枣提质增效的水肥耦合方案,以南疆典型自压灌区昆玉市224团10 a成龄骏枣为研究对象,基于当地实践生产,以灌水量770 mm、施肥量1125 kg/km^(2)为对照,采用水(W1,540 mm;W2,630 mm;W3,720 mm)、化肥(F1,562.5 kg/hm^(2);F2,810 kg/hm^(2);F3,1080 kg/hm^(2))双因素三水平进行小区试验,探索南疆滴灌骏枣的新梢、枣吊、光合特性及产量品质对水肥耦合的响应规律。结果显示:灌水、施肥和水肥交互作用对叶片净光合速率(Pn)、蒸腾速率(Tr)、气孔导度(Gs)、胞间CO_(2)浓度(Ci)、新梢和枣吊的影响均表现为灌水>施肥>水肥交互作用;对产量、灌溉水分利用效率(IWUE)的影响均表现为水肥交互作用>灌水>施肥;对肥料偏生产力(PFP)影响表现为水肥交互作用>施肥>灌水;对单果质量、骏枣纵横径表现为施肥>灌水>水肥交互作用;对果形指数影响表现为施肥>水肥交互作用>灌水。结果表明:W3F2处理的骏枣新梢、枣吊最优,W2F3处理的产量、IWUE最优,W2F2处理的Pn、Tr、Gs、单果质量、骏枣纵横径、果形指数最优,W3F1处理的PFP最优。

灌水和氮肥基追比对旱区马铃薯产量、水肥利用效率和酶活性影响评价

为探明水氮基追施用对马铃薯产量、灌溉水肥利用效率和土壤酶活性等方面的综合影响,以获取最优水氮基追施用方案。大田试验设置3个灌水水平W1(900 m^(3)/hm^(2))、W2(1350 m^(3)/hm^(2))和W3(1800 m^(3)/hm^(2))以及3个氮肥基追比水平F1(N_(2∶1))、F2(N_(1∶1))和F3(N1∶2),共9个处理,利用熵权TOPSIS法构建宁夏中部旱区马铃薯综合生长评价体系,并以高产、节水节肥为目标建立马铃薯水氮基追施交互响应数学模型。结果表明,灌水量和氮肥基追施对马铃薯单株产量、产量、iWUE(灌溉水利用效率)、PFP(肥料偏生产力)、土壤碱性磷酸酶、土壤蔗糖酶均影响显著;利用熵权TOPSIS法建立马铃薯综合评价体系,得到最优综合响应评分0.1761,即为A7处理(1800 m^(3)/hm^(2),N_(2∶1));由马铃薯综合生长对水氮基追施交互响应模型得出,水氮基追施单因素对马铃薯综合生长影响均呈开口向下的二次抛物线,水氮基追施交互影响显著。当施肥编码为-0.7723(基肥∶追肥=1.6553∶1)、灌水编码为0.6553(1697.535 m^(3)/hm^(2))时,综合评分最高。以综合评分0.16划分闭合区域得出马铃薯生产上最佳的灌水区间和氮肥的基追施比例分别为1440~1935 m^(3)/hm^(2)、1∶1~2.3∶1,此区间最有利于实现马铃薯水氮协同效应最优。

绿洲灌区水肥耦合对连作饲用型高粱‘近甜1号’生长的调控效应

以荒漠绿洲沙荒地饲用型‘近甜1号’(BJ0601)高粱(Sorghum bicolor)头茬种植的最佳水肥需求(灌溉量7800 t·hm^(−2);施肥量600 kg·hm^(−2))和栽培模式(株距×行距:23 cm×40 cm)为依据,以头茬和轮作为对照,对连作3年的‘BJ0601’生长适应性(生长发育、茎秆鲜重、种子产量和质量等)、茎秆糖含量及土壤地力(有机碳、矿质养分)变化等进行分析。结果表明:与头茬相比,‘BJ0601’轮作茎秆鲜重无显著差异(P>0.05),但种子产量(925.1 kg·hm^(−2))显著低于头茬(2029.5 kg·hm^(−2))(P<0.05)连作3年后‘BJ0601’生长适应性受到明显抑制;与头茬相比,‘BJ0601’连作3年后出苗数、成苗率及株高分别降低了11.5%、11.4%和43.7%,茎秆鲜重(57.8 t·hm^(−2))和种子产量(677.2 kg·hm^(−2))分别降低了26.4%和71.5%;各处理茎秆可溶性糖含量无显著差异。‘BJ0601’连作3年后土壤地力显著下降。与头茬和轮作相比,连作3年后‘BJ0601’根区10-20 cm土层有机碳含量降低了34.4%和36.7%,碱解氮、速效磷和速效钾含量降低了71.9%和43.9%、85.7%和38.8%、30.9%和16.9%(其他耕作层养分变化同10-20 cm土层)。然而,在高水肥耦合(灌溉量9000 t·hm^(−2);施肥量825 kg·hm^(−2))下,‘BJ0601’连作3年茎秆鲜重(74.9 t·hm^(−2))和种子产量(962.6 kg·hm^(−2))与最佳水肥下连作3年相比分别提高了29.6%和66.3%,且茎秆鲜重和茎秆可溶性糖含量与头茬和轮作相比无显著差异。连作显著影响‘BJ0601’的生长适应性及土壤地力状况,但高水肥耦合和轮作能够减轻连作对‘BJ0601’生长的抑制作用,减缓土壤地力衰退。在荒漠绿洲区须对‘BJ0601’的灌溉施肥方式、耕作措施和栽培管理等进行综合改善,以减缓连作障碍对‘BJ0601’生长及土壤肥力造成的不利影响,才能保证‘BJ0601’高生产力和水肥资源的高效利用。

冷凉灌区马铃薯施肥量与种植密度对马铃薯生长及产量的影响

为了明确不同施肥量(复合肥)和种植密度对冷凉灌区马铃薯生长的影响。试验以‘冀张薯12号’为供试品种,开展施肥量与种植密度二因素试验,设3个施肥量(600、1100、1600 kg/hm^(2))与4个种植密度(5.25万、6万、6.75万、7.5万株/hm^(2)),研究不同施肥量与种植密度对马铃薯生长、产量与水分利用效率的影响。结果表明:增加施肥量能延缓马铃薯生育期,提高种植密度能缩短生育期;随施肥量增大,马铃薯株高、茎粗、叶面积指数及叶片SPAD值均显著增大;随种植密度增加,马铃薯株高、茎粗、叶面积指数及叶片SPAD值与产量均表现为先增后减趋势,施肥量与种植密度对马铃薯株高、SPAD值与产量的影响顺序为施肥量>密度;随施肥量和群体种植密度的增加,马铃薯大薯产量、大薯数、产量、水分利用效率均呈先增后减的变化趋势,产量要素之间呈极显著正相关关系,其中,以处理F2D3的马铃薯产量与水分利用效率最大。通过二元二次回归分析表明,当施肥量达到1065.366 kg/hm^(2),种植密度达到6.746万株/hm^(2)时,马铃薯能够获得最大的产量50255.98 kg/hm^(2)。施肥量达到1044.312 kg/hm^(2),种植密度6.582万株/hm^(2)时水分利用效率达到最大110.456 kg/(hm^(2)·mm)。适宜的施肥量与种植密度能够促进马铃薯生长,有利于马铃薯产量与水分利用效率的提高,当施肥量(复合肥)介于1044.312~1065.366 kg/hm^(2)时,种植密度介于6.582万~6.746万株/hm^(2)时能实现增产和水分利用协同增加,是冷凉地区马铃薯种植推荐的高产高效模式。

半干旱区夏玉米的水肥空间耦合效应

通过大田试验就半干旱区非充分灌溉条件下水肥的空间耦合 (水肥异区、水肥同区、固定灌水、交替灌水 )对夏玉米的产量影响进行了研究 ,并通过对某些生理指标的测定 ,探讨了影响产量的原因。结果表明 ,与常规灌水施肥方式相比 ,非充分灌溉条件下不同水肥空间耦合灌水量减少一半 ,籽粒产量下降 7%— 16% ,根系吸收养分能力、光合速率、蒸腾效率明显增加 ,而叶面积、蒸腾速率和硝酸还原酶活性均无明显变化。其中以水肥异区交替灌水的产量降低最小 ,表明这是非充分灌溉条件下较好的一种水肥耦合形式。

不同品种类型花生精播肥料与密度的产量效应及优化配置研究

采用二次饱和D-最优设计建立了精播条件下不同类型花生品种N肥用t和密度与产t的教学模型，探讨肥料与密度的产量效应及优化配置。分析表明：（1）大花生花育22号在产量潜力、最优措施组合方面与小花生鲁花12号有一定差异。花育22号最高产量可达到6498．6kg／hm^2，最优措施组合为：N肥115．8kg／hm^2＋密度20．9万株脯；鲁花12号最高产量可达到5792．9kg／hm^2，最优措施组合为：N肥101．9kg／hm^2＋密度22．2万株。（2）大花生对肥料更为敏感，而小花生对密度反应更为强烈。当N肥用t和密度低于最优组合值时，N肥每增加1kg，花育22号平均增产18．2kg，比鲁花12号高6．3kg；密度每增加1万株，鲁花12号平均增产92．3kg，比花育22号高24．5kg。因此，小花生精播更要注意发挥密度的增产作用。（3）大花生产量在5000kg／hm^2以上的措施组合为：N肥109．0～156．2kg／hm^2，密度17．5-25．7万株／hm^2；小花生鲁花12号产t在4000kg／hm^2以上的措施组合为：N肥86．6～147．2kg／hm^2，密度18．5～25．8万株／hm^2。

棉花密植、化调、水肥综合配套高产栽培技术研究

利用密植、化调、水肥等综合栽培技术。进行了协调棉株生育的研究。试验结果表明,10.5万株/hm^2,DPC 90g/hm^2,N、P_2O_5、K_2O 为225、180、135kg/hm^2,盛蕾期浇头水的处理,可以达到株高65～70cm、果枝数10个、果节数3个的株型,形成铃期不封垄、通风透光好的群体结构;叶片的同化能力和根系的活性均较强,在棉株群体、生态环境和棉株体内库源流之间形成了协调的关系。因此,群体的成铃强度达到了4.68万个/hm^2·日,皮棉产量达到了1875kg/hm^2,经济系数达到了0.4以上。

不同种植制度下长期施钾与秸秆还田对作物产量和土壤钾素的影响

【目的】研究施钾和秸秆还田对华北地区不同种植制度下作物产量和耕层土壤钾素状况的影响。【方法】在华北平原的河北潮土和山西褐土上进行连续13年的施钾和秸秆还田试验。【结果】施钾和秸秆还田能增加小麦和玉米产量,处理之间表现为:NPK+St>NPK>NP+St>NP,施钾处理的作物产量与NP处理的产量差异显著,轮作制度下玉米的施钾效应高于小麦。与山西单作制度相比,河北轮作制度下的土壤钾素损耗严重,除NPK+St处理外土壤钾素均表现亏缺。秸秆还田和施用钾肥较NP处理可不同程度提高河北潮土和山西褐土耕层土的水溶性钾、非特殊吸附钾、非交换性钾、矿物钾及全钾含量,且降低矿物钾比例的同时提高其余几种形态钾的比例。与定位开始相比,两种类型土壤各形态钾含量和比例随时间变异特点不同,两定位点土壤矿物钾和全钾含量均表现下降。【结论】整体看直接施用化肥钾的效果优于秸秆还田。但从提高作物产量和缓解土壤钾素下降来看,小麦秸秆还田是一个有效的补钾措施。

不同水分条件下分层施磷对冬小麦根系分布及产量的影响

研究不同水分条件下分层施磷对冬小麦根长分布、水分利用效率（water use efficiency，WUE）及产量的影响，旨在找出旱地农业最佳水肥处理方式。试验设不施磷（CK）、表施磷（surface P, SP）、深施磷（deep P, DP）和侧深施磷（deep-band P, DBP）4种处理，每个施磷水平下设补充灌溉（W1）和干旱（整个生育期无补充灌溉）（W2）2种水分处理。结果表明，施磷位置及补充灌溉显著（P〈0.05）影响冬小麦孕穗期根长分布、WUE 及产量，同时会改变根系空间分布。干旱胁迫使冬小麦0～〈30 cm土层根长密度下降，降低17.5%，却促进了30 cm以下土层根长发育，增加13.3%，促进对土壤水分和磷素的吸收，从而提高产量。无论灌溉与否，施磷处理0～〈30 cm土层根长密度、吸磷量、WUE及产量均显著高于CK（P〈0.05）。施磷位置对冬小麦WUE和产量的影响随土壤水分而异，无补充灌溉时，与磷肥表施相比，磷肥深施显著增加WUE和产量（P〈0.05），分别平均增加28.5%和16.0%，且深层根长（30～100 cm）与吸磷量、WUE和产量的变化趋势一致；而在补充灌溉时，与磷肥表施相比，磷肥深施却显著降低WUE（P〈0.05），平均降低13.3%，且深层根长与WUE、产量的关系缺乏规律性。该试验结果表明，土壤水分供应不足时，磷肥深施有利于促进冬小麦深层土壤根系生长发育，提高对土壤水分吸收利用能力，从而利于形成高产。该研究可为理解作物生长及产量对水分养分空间耦合的响应提供理论依据。