华北平原高产粮区不同水氮管理下农田氮素的淋失特征

为了降低集约化种植制度下华北平原农田硝酸盐的淋失,该研究选择华北平原高产粮区,开展了为期2 a （2006－2008年）的田间试验,试验设计了2个灌溉处理（常规灌溉处理和基于土壤水分实时监控的优化灌溉处理）和2个施氮处理（传统施氮处理和优化施氮处理）,利用张力计结合土壤溶液提取器对土体2 m处的水分和硝酸盐通量进行了监测和计算。研究结果显示,在相同施氮条件下,优化灌溉能够有效降低农田水分的渗漏量,渗漏量仅为传统灌溉渗漏量的50%左右。优化施氮能够有效降低2.1 m土体硝态氮含量,在相同灌溉条件下2.1 m土体硝态氮的残留量都在传统施氮的60%以下,而灌溉方式对硝态氮累积的影响不大。优化水氮管理相比传统水氮管理氮素的淋失量下降了60%,淋失率也下降了50%左右,粮食产量略有提高。     

Water drainage and nitrate leaching under traditional and improved management of vegetable‐cropping systems in the North China Plain

Traditional irrigation and nitrogen (N) fertilization in North China may elevate water drainage and nitrate concentrations in soil and groundwater. A field experiment was conducted in an intensively irrigated vegetable (cauliflower, amaranth, and spinach) field for three consecutive years (1999–2002). The main objective was to test to what extent an improved water and fertilizer management, based on the maintenance of field capacity a defined range of the water content in the 0–50 cm soil layer and an N expert system, could reduce drainage and nitrate leaching without impairing vegetable yield. Rates of water drainage and related nitrate leaching were calculated based on measurements of soil water potential and soil‐water nitrate concentrations. Soil water potential was monitored with tensiometers at depths of 75 cm and 105 cm. Nitrate concentrations were analyzed in soil leachates collected at 90 cm soil depth using ceramic suction cups. The results revealed that the average annual drainage related to the cultivation season for cauliflower, amaranth, and spinach was reduced from 275 mm in the traditional system to 29 mm with improved management practice. The average annual cumulative nitrate leaching during the vegetable‐growing period amounted to 301 kg ha^–1 and 13 kg ha^–1 in the traditional and improved management practices, respectively. Vegetable yields were not significantly different under the traditional and improved management practices.     

华北平原不同种植制度对粮食作物氮素利用和土壤氮库的影响

冬小麦-夏玉米一年两熟是华北平原粮食作物的主要种植制度,存在氮肥利用率低、土壤氮素过量累积问题。为探索华北平原氮素高效利用的适宜种植制度,采用15N示踪技术,基于3 a田间定位试验,对一年两熟冬小麦-夏玉米的常规水氮和优化水氮、两年三熟冬小麦-夏玉米-春玉米与冬小麦-夏大豆-春玉米及一年一熟春玉米3种种植制度的作物产量、15N利用率、氮素去向和土壤氮库表观平衡进行研究。结果表明,两年三熟的冬小麦-夏玉米-春玉米产量为32 248.52 kg/hm2,分别比一年两熟和一年一熟提高22.16%和52.88%;15N利用率为33.36%,比一年一熟提高26.12%。3种种植制度的氮肥去向最高为土壤残留,其次为作物吸收和损失,两年三熟冬小麦-夏玉米-春玉米的作物吸氮量最高为151.82 kg/hm2,土壤氮库表观盈余量为21.22 kg/hm2,显著低于其他种植制度。综合分析,冬小麦-夏玉米-春玉米两年三熟在稳产高产和提高氮素利用率上具有可持续的潜力,是华北平原未来较为理想的种植制度。     

不同施氮量对夏玉米产量、氮肥利用率及氮平衡的影响

通过田间小区试验研究了不同施氮量对夏玉米产量、氮肥利用率、硝酸盐淋溶及氮平衡的影响。结果表明，施氮对夏玉米子粒有显著的增产作用，但随施氮量的增加产量变化不大。氮肥利用率在9．2％-22．6％之间，随施氮量的增加而降低。施氮可明显提高0-160cm剖面土壤NO3^--N含量，而且随深度的增加NO3^--N含量呈降低趋势，累积峰主要在20—60cm之间。玉米收获后，随着施氮量的增加氮素的损失量增加，各施氮处理的硝态氮残留量在121～221kg／hm^2之间，以N250处理的残留量最高，残留率近65％。     

不同施氮量对夏玉米产量、氮肥利用率及氮平衡的影响

通过田间小区试验研究了不同施氮量对夏玉米产量、氮肥利用率、硝酸盐淋溶及氮平衡的影响。结果表明,施氮对夏玉米子粒有显著的增产作用,但随施氮量的增加产量变化不大。氮肥利用率在9.2%~22.6%之间,随施氮量的增加而降低。施氮可明显提高0~160 cm剖面土壤NO3--N含量,而且随深度的增加NO3--N含量呈降低趋势,累积峰主要在20~60 cm之间。玉米收获后,随着施氮量的增加氮素的损失量增加,各施氮处理的硝态氮残留量在121~221 kg/hm2之间,以N250处理的残留量最高,残留率近65%。     

华北平原不同降水年型和作物种植模式下的产量和耗水模拟

华北平原是中国重要的粮食生产基地,在国家粮食产业中地位较高,但长期灌溉造成了华北平原地下水资源的严重亏损,地下水位持续下降。该研究利用APSIM模型对华北平原1986－2015年不同种植模式下的产量和耗水情况进行模拟研究,为华北平原调整作物种植模式、农业水资源管理以及农业发展政策的制定提供科学依据。研究结果表明：APSIM模型能够较好地模拟冬小麦和夏玉米的生育期、产量及水分利用特征,其中生育期模拟结果的误差在5 d之内,产量、ET和下渗量模拟结果的R2均在0.84以上,表明该模型在华北平原具有较好的适用性;在华北平原地区,冬小麦-夏玉米一年两熟种植模式（M2Y1）年均产量（13 445 kg/hm2）最高,但耗水量（724 mm）也是最大,水分亏损（233 mm）最为严重;一年一熟种植模式（M1Y1）年均耗水量（534 mm）较小,水分亏损量（43 mm）最少,但产量（9 215 kg/hm2）较低;两年三熟种植模式（M3Y2）兼顾产量和耗水,在保证一定产量的前提下减少了耗水量,产量耗水综合效果最好,适合在华北平原推广实行。此外,该研究对栾城站丰水年、平水年和枯水年等不同降水年型下的3种种植模式产量耗水特征进行了对比分析,研究表明在华北平原降水资源对于作物生长有重要意义,年降水量越大,作物产量越高,水分亏损量越少。     

Modeling nitrate leaching and organic‐C build‐up under semi‐arid cropping conditions of N India

Nitrate leaching, overall N balance, and organic‐C build‐up in a semi‐arid agro‐ecosystem in NW India was estimated from the results of a long‐term manurial trial with farmyard manure (FYM) and mineral‐N fertilizer in operation since 1967 at the Research Farm of CCS Haryana Agricultural University, Hisar, India. The model LEACHN was calibrated for the wheat‐growing period November 2000 to April 2001 and the leaching of nitrate during this period was predicted to 48 kg N ha^–1 without mineral‐N fertilization and 59 kg N ha^–1 with addition of 120 kg mineral‐N fertilizer, both with the addition of 15 t ha^–1 FYM. The N balance for the simulation period showed that the 120 kg N ha^–1–mineral N fertilization compared to zero mineral N, both plus FYM, resulted in only slightly higher crop uptake, leaching losses, and NH₃ volatilization, and a negligible increase of N in organic matter. The largest amount remains as an additional build‐up of mineral N in the profile (84.3 kg N ha^–1) which is prone to losses as ammonia or nitrate. The model was used to simulate organic‐C build‐up with FYM and a decrease of organic C without FYM for a period of 33 y (1967–2000). The simulated C build‐up to about 0.1 g kg^–1 agreed very well with the measured values and showed that additional mineral‐N fertilization will not have any significant effect on organic‐C content. Simulations with the assumption of no FYM application showed a gradual decrease of organic C from its starting value of 0.046 g kg^–1 in 1967 down to almost half of this. This agreed well with the observed organic‐C values of 0.028 g kg^–1 as measured for unmanured plots.     

华北平原冬小麦/夏玉米轮作体系对氮素环境承受力分析

通过田间试验研究了华北地区冬小麦/夏玉米轮作体系对氮素的环境承受力。结果表明,冬小麦和夏玉米达到最高产量时的施氮量分别是112和180.kg/hm2。氮肥利用率和农学利用率随施氮量的增加而降低,生理利用率表现出抛物线的趋势。在农户习惯施氮条件下,冬小麦和夏玉米的氮肥利用率分别是10%和6%,每千克氮肥分别增产2和3千克。灌水和集中降雨是引起土壤硝态氮明显下移的主要因素。氮素平衡计算的结果表明,低施氮量时,氮素盈余以残留Nmin为主,高量施氮则以表观损失为主。将收获后090.cm土壤中的硝态氮的量控制到150kg/hm2,可以在兼顾环境的前提下获得较高的产量;此时冬小麦季的施氮量是122.kg/hm2,产量(干物重)达到最高产量4331.kg/hm2;夏玉米季的施氮量是145.kg/hm2,产量(干物重)是7965.kg/hm2,达到最高产量的97%。     

华北平原典型冬小麦农田生态系统能量平衡与闭合研究

准确量化分析地气之间的物质和能量交换对于水资源管理和农业可持续发展是十分重要的。能量平衡闭合是评估观测数据准确性和分析地表能量平衡的一个重要的评价指数。本研究利用开路涡度相关系统和全要素自动气象站对华北平原典型冬小麦农田生态系统2013—2014年度的能量通量及常规气象要素进行了连续观测,分析了冬小麦农田各能量通量的日变化和年变化特征,计算冬小麦在4个生育时期(出苗期、越冬期、拔节期和灌浆期)的能量闭合和波文比。结果表明:在日尺度上,选取的4个生育时期净辐射和各能量分量的日变化趋势均为单峰二次曲线,净辐射、显热通量和潜热通量的峰值出现在12:00—13:00,土壤热通量的峰值出现在14:00—15:00。在年尺度上,净辐射和潜热通量的变化趋势较为一致,均在越冬期达到最低值114.51 W·m~(-2)和13.47 W·m~(-2),而在灌浆期达到最大值327.02 W·m~(-2)和116.56 W·m~(-2)。选取的4个生育时期的代表性观测日期能量闭合良好,能量闭合率分别为0.49、0.77、0.81和0.76。4个生育时期内波文比值日变化趋势均呈倒"U"型,出苗期波文比在14:00达到最大值2.12;越冬期、拔节期和灌浆期在10:00左右达到最大值,分别为1.48、0.31和0.58。本文的定量化结果可为华北平原农田生态系统水热通量等研究提供依据。     

华北山前平原农田土壤硝态氮淋失与调控研究

本文依托中国科学院栾城农业生态系统试验站小麦-玉米一年两熟长期定位试验, 应用土钻取土和土壤溶液取样器取水的方法, 研究了不同农田管理措施下土壤硝态氮的累积变化, 计算了不同氮肥处理通过根系吸收层的硝态氮淋失通量。结果表明, 小麦-玉米生长季土壤硝态氮累积量和淋失量随着施氮量的增加显著增加, 相同氮肥水平下增施磷、钾肥增加了作物的收获氮量, 施磷肥增加的作物收获氮量最高可达123kg·hm^-2·a^-1, 施钾肥增加的作物收获氮量最高为31 kg·hm^-2·a^-1。不同灌溉水平下0~400 cm 土体累积硝态氮随着灌溉量的增加而降低, 控制灌溉(小麦季不灌水, 玉米季灌溉1 水)、非充分灌溉(小麦季灌溉2~3 水, 玉米季按需灌溉)、充分灌溉(小麦季灌溉4~5 水, 玉米季按需灌溉)各处理剖面累积硝态氮量分别为1 698 kg·hm^-2、1148 kg·hm^-2 和961 kg·hm^-2。与非充分灌溉和充分灌溉处理相比, 控制灌溉在100~200 cm 土层硝态氮累积量显著高于其他层次, 2003~2005 年间控制灌溉剖面增加的硝态氮量占施肥总量的23%; 非充分灌溉处理剖面增加的硝态氮量占施肥总量的22%; 充分灌溉处理剖面增加的硝态氮量占施肥总量的47%。免耕措施降低了作物产量, 影响土壤水的运移, 增加了硝态氮的淋失风险。根据作物所需降低氮素投入(N 200 kg·hm^-2·a^-1), 增施磷、钾肥, 控制灌溉量是减少华北山前平原地区硝态氮淋失, 保护地下水的有效措施。     

RZWQM模拟小麦 玉米轮作系统氮素运移及损失特征

本文以位于华北平原的河北省农林科学院大河试验站冬小麦-夏玉米轮作系统为研究对象,应用RZWQM(Root Zone Water Quality Model)模型对华北地区2010年冬小麦-夏玉米的1个轮作周期内土壤剖面水分和剖面硝态氮累积、作物产量、硝态氮淋失以及氨挥发进行模型模拟。本文利用并通过RZWQM模型在不同梯度施肥情况下讨论了施肥量对小麦-玉米轮作体系中硝态氮淋溶和氨挥发特性,并尝试通过拟合出的回归曲线来确定施氮量和硝态氮淋失和氨挥发之间的关系。设置冬小麦-夏玉米轮作周期施纯氮量分别为575 kg-hm-2(N3)、400 kg-hm-2(N2)、215 kg-hm-2(N1)和0 kg-hm-2(N0)4个处理,应用轮作周期中玉米数据进行模型参数率定,应用小麦进行模型参数的验证。结果表明:模型的玉米率定以及小麦验证的过程中结果偏差均在可接受范围内,剖面水分率定均方误差(RMSE)最高为0.019 cm3-cm-3,平均相对误差(MRE)最高为15.98%;剖面硝态氮累积验证结果 RMSE平均值为4.580 mg-kg-1,MRE平均值为52.63%。在模型验证的小麦-玉米季土壤基础上,硝态氮淋溶和氮挥发都与施氮量呈一定线性相关关系。综上结论,本试验结果能较好地模拟华北地区土壤剖面水分、硝态氮积累,以及施氮量对土壤硝态氮淋失和氨挥发的影响,为预测和估算土壤适宜施氮量提供了便捷可靠的方法。但RZWQM模型验证参数过程还需要进一步的校正与完善。     

华北平原典型干旱年土壤水分及灌溉特征遥感分析

华北平原作为我国的粮食主产区,土壤水分是制约作物生长的主要限制因子.本文首次运用土壤水分指数数据,对华北平原土壤水分以及灌溉特征进行空间分析,旨在为区域尺度农田旱情以及农作物产量的实时监测与预报提供相关参考.研究基于1993-2002年华北平原逐旬降雨数据和主动微波遥感反演的土壤水分指数数据,应用地统计分析方法,分析典型干旱年(1999年)该区表层土壤水分时空变异特征,并提取和分析小麦生长期内的灌溉信息;通过对逐句的降水和土壤水分数据的空间叠置分析,提取区域内的灌溉信息.结果表明:1999年降水量比多年(1993-2002年)平均量少约140mm;1999年土壤水分变化与降水变化整体保持一致,低于多年平均水平,春季和夏季,土壤水分减少尤为明显,土壤干旱非常普遍;小麦生长期内,大部分地区均存在不同程度的灌溉,其中中部地区灌溉次数最少,占研究区面积的65％左右的南部和北部地区灌溉次数多为2～3旬次.采用降水量和遥感水分监测数据,可以分析土壤水分变化的原因,提取灌溉的范围和时间特征,并可为旱情遥感监测提供科学参考.     

基于RS/GIS和RUSLE的华北平原土壤侵蚀现状分析

对华北平原的土壤侵蚀状况进行分析,可为粮食主产区的生态保护及土壤侵蚀防治提供重要依据。在GIS技术支持下,利用遥感影像解译资料、数字高程模型(DEM)及土壤、降雨等数据,对修正土壤流失方程(RUSLE)中的各因子进行了量化,实现了对华北平原土壤侵蚀量的估算,并对结果进行土壤侵蚀强度分级。分析结果表明,华北平原多年平均土壤侵蚀模数为2 674.26t/(km2.a),最大值可达8 302.11t/(km2.a),总体上属中度侵蚀。发生轻度以下侵蚀面积占总面积的82.94%,表明华北平原的水土流失在总体上得到了较好的控制。但仍有占总面积7.33%的区域属于较强以上的侵蚀等级,说明局部水土流失严重,尤以沿太行山、燕山、泰山和大别山的低山丘陵地带的土石山区最为严重,是华北平原土壤侵蚀治理的重点地区。     

华北平原冬小麦–夏玉米轮作体系秋季一次基施牛粪氮素损失与利用研究

为对我国华北平原冬小麦-夏玉米轮作体系秋季一次基施有机肥的氮素环境效应提供评估依据,本文分别在山东陵县和天津蓟县以不施肥、分次施用硫酸铵为对照,对秋季一次基施牛粪的产量水平、氮素损失及利用等进行了研究。其中,山东陵县试验采用15N示踪技术。结果表明,秋季一次基施牛粪15N在冬小麦夏玉米轮作周期的损失率为30%～38%,与硫酸铵15N损失率无显著差异。牛粪氮施用N 300 kg/hm2时,损失量为N 89 kg/hm2;牛粪氮施用量增加50%,其氮损失量增加91%。冬小麦、夏玉米收获后,施牛粪处理080cm土壤硝态氮含量分别为N 38～95、18～28 kg/hm2,低于分次施用硫酸铵处理。长期施用有机肥农田,秋季一次基施牛粪处理冬小麦、夏玉米子粒产量与分次施硫酸铵处理无显著差异,因此从环境角度分析,秋季一次基施有机肥可继续应用和大力推广,但施用量以不超过N 300 kg /hm2为宜。     

有机种植条件下水肥管理对氮素淋洗和氮素平衡的影响研究

利用自流式农田地下淋溶收集装置,研究设施蔬菜有机种植中有机肥与水的不同管理模式下氮素淋洗的变化特征,并对土壤-作物体系的氮素表观平衡进行评估。结果表明,有机肥施肥量对淋洗液中NO3--N浓度有明显影响,并在施肥后60 d左右出现峰值,种植期间的淋溶液中NO3--N的平均浓度最高达到61.57 mg/L。施肥量明显影响氮素累积淋洗量,常规水肥管理(施有机肥N量718.2 kg/hm2,灌溉量1 200 mm)下氮素淋失量最大,为17.32 kg/hm2;而水肥减量管理(施有机肥N量359.1 kg/hm2,灌溉量700 mm)下,氮素淋失量明显降低,为10.78 kg/hm2。在0~90 cm的作物-土壤体系中,常规施肥管理下的氮素平衡值超过300 kg/hm2,而减半量施肥的平衡值在15.0 kg/hm2以下,有效地维持了系统氮素平衡。     

Tillage effects on soil aggregation,organic carbon fractions and grain yield in Eum‐Orthic Anthrosol of a winter wheat–maize double‐cropping system,Northwest China

Conservation tillage has been applied in vast semi‐arid regions of the Guanzhong Plain, Northwest China. The tillage effects on soil aggregation, organic carbon (OC) stabilization and grain yield on this plain have not been fully elucidated. A 9‐year field experiment was established from 2002 on a silty clay loam soil (Eum‐Orthic Anthrosol) growing winter wheat–maize in a double‐cropping system. Six conservation tillage treatments were applied by different combinations of rotary tillage (RT), subsoiling (SS) and no‐till (NT), with or without finely chopped straw retention. Conventional tillage (CT) acted as the control. Results showed that in the surface (0–10 cm) soil, the proportion of water‐stable aggregates (WSA) <0.05 mm was 18% less while that for WSA >2 mm was 98% more under NT treatments compared with CT. Additionally, the oxidizable OC content in WSA 0.25–2 mm was 27% greater under NT treatments compared with CT. The OC stocks increased under SS by 17%, RT by 16% and NT by 15% relative to CT. Grain yield (wheat + maize) showed similar increasing trends in all the tillage treatments compared with CT. Both OC stocks and grain yield were larger in treatments with than without straw retentions. These results indicate that NT is beneficial for OC accumulation in WSA but is limited in its ability to improve soil structure in this region. SS plus straw retention (fine‐chopped or as a mulch) is an effective practice to improve soil structural stability, OC accumulation and soil productivity of Eum‐Orthic Anthrosols in Northwest China.     

Effect of optimal irrigation,different fertilization,and reduced tillage on soil organic carbon storage and crop yields in the North China Plain

The objective was to evaluate the effect of different agricultural managements on soil organic C (SOC) storage and crop yields in the North China Plain (NCP). The study was conducted at five experimental stations. Different agricultural managements were designed, including optimal (OPT) and conventional (CON) irrigation and fertilization treatments, different amounts of fertilization application and residue‐return treatments, and different tillage practices. Compared to the CON treatment, SOC storage in the 1 m soil profile under the OPT treatment increased by 2 t ha^–1, 8 t ha^–1, and 4 t ha^–1 at Quzhou, Wuqiao, and Dongbeiwang sites, respectively. The annual increasing rate of SOC storages in the topsoil (0–30 cm) under the OPT treatments at Wuqiao (0.88 t ha^–1 y^–1), Quzhou (0.93 t ha^–1 y^–1), and Dongbeiwang (1.86 t ha^–1 y^–1) were higher than those in the CON treatments at Wuqiao (0.15 t ha^–1 y^–1), Quzhou (0.54 t ha^–1 y^–1), and Dongbeiwang (0.28 t ha^–1 y^–1), but the difference of grain yields between the two treatments was not significant. The SOC storage in 1 m soil profile in the no‐tillage treatment with standing residue return (NT1) at Luancheng increased by 5 t ha^–1 and 7 t ha^–1 compared with rotary‐tillage (RT) and conventional‐tillage (CT) treatments, respectively, but the crop yield under no‐tillage treatment was the lowest. While at Quzhou site, it increased by 3 t ha^–1 in the top 40 cm soil under the NT treatment compared to the CT treatment. The annual increasing rate of SOC storage in the top 30 cm under NT treatment was also the highest (1.08 t ha^–1 y^–1 at Luancheng, 1.86 t ha^–1 y^–1 at Quzhou), compared to the other tillage treatments. At Henghsui site, the combination of the highest fertilization application and highest residue‐return treatments got the highest SOC storage and the highest crop yields. We concluded that the agricultural management practices, such as optimal irrigation and fertilization treatment, the higher fertilization, residue return and RT, has significant impact on the SOC storage and agricultural sustainability in the NCP.     

不同灌溉施肥措施对夏玉米-冬小麦农田N2O排放和产量的影响

为明确不同灌溉施肥措施下夏玉米-冬小麦轮作农田N_2O的排放特征,寻求既能减少N_2O排放又保证粮食产量的灌溉施肥方法,以华北地区夏玉米-冬小麦轮作农田为研究对象,利用静态暗箱-气相色谱法对土壤N_2O排放特征进行了周年(2015年6月15日-2016年6月12日)观测,探讨了常规施氮量(夏玉米:205.5 kg/hm2;冬小麦:250 kg/hm2)下传统灌溉施肥(FP100%)、滴灌+传统施肥(DN100%)、滴灌水肥一体化(FN100%)以及滴灌水肥一体化下不同施氮量(减氮60%(FN40%)、减氮30%(FN70%)、常规氮量(FN100%)和增氮30%(FN130%))下农田N_2O排放特征及土壤温湿度对农田N_2O排放的影响,另设滴灌+不施氮肥(CK)为对照。结果表明:在夏玉米-冬小麦轮作体系中小麦季农田土壤N_2O排放通量高于玉米季,夏玉米季土壤N_2O阶段排放峰值出现在拔节期和抽雄期;而冬小麦季土壤N_2O阶段排放峰值出现在冬前苗期和拔节期。与FP100%处理相比,FN40%处理在夏玉米和冬小麦季的N_2O平均排放通量分别降低了70.8%和66.7%,N_2O排放总量分别减少了58.7%和66.3%;整个轮作季周年产量没有显著减少,N_2O排放总量显著降低了62.9%(P0.05)。FN40%处理夏玉米季和冬小麦N_2O排放系数分别为0.06和0.01,显著低于其他施肥处理(P0.05)。土壤温湿度均影响农田N_2O排放,但不同处理在夏玉米和冬小麦生长季与土壤温度和土壤湿度的相关性并不相同。综合考虑N_2O排放量和作物产量,研究认为,在华北地区夏玉米-冬小麦轮作系统下,若采用滴灌,则根据作物需肥规律同时采用水肥一体化方式进行施肥才既有增产,又减少农田N_2O排放的效果,并且在滴灌水肥一体化技术下,减少60%施氮量在保障粮食产量的同时,可以有效地减少N_2O排放,是兼顾作物产量及大气环境的推荐管理措施。