川西北高寒草地沙化过程中土壤氮素变化特征

草地沙化是我国最严重的环境问题之一,但关于草地沙化过程中氮素变化特征的研究报道多集中于干旱半干旱地区,而半湿润地区的相关报道还比较缺乏。通过野外调查,研究了川西北半湿润地区高寒沙质草地沙化过程中土壤氮素变化特征。结果表明,草地沙化对0—100cm土层土壤氮素具有显著影响,全氮、碱解氮、铵态氮(NH_4~+-N)、硝态氮(NO_3~--N)和微生物量氮(MBN)均呈现极显著下降的变化特征,极度沙化阶段较未沙化阶段分别减少了73.95%、77.72%、76.75%、79.77%和84.12%。其中,0—20cm土层变化最显著,全氮、碱解氮、NH_4~+-N、NO_3~--N和MBN含量分别减少了86.43%、83.52%、82.11%、88.82%和91.77%。随着土层深度增加,不同程度沙化草地土壤氮素含量及其变化量逐渐减少;草地沙化过程中,不同沙化阶段土壤氮素损失数量不尽相同,其中,以轻度沙化阶段氮素损失最严重,全氮、碱解氮、NH_4~+-N、NO-3-N和MBN含量分别降低了41.18%、35.17%、46.74%、43.46%和46.88%。草地沙化过程中,土壤全氮、碱解氮、NH_4~+-N、NO_3~--N和MBN含量与土壤粉粒、粘粒含量和植被群落盖度均呈极显著正相关特征,与土壤沙粒含量呈极显著负相关特征。研究区土壤氮素损失与风蚀选择性吹蚀土壤粉粒、粘粒及地表植物覆盖状况逐渐变差密切相关,因此该区域治沙的关键是采取措施降低风蚀对地表土壤吹蚀作用,提高沙化草地地表植被覆盖。同时,还应及时对沙化前期阶段及潜在沙化的草地进行生态治理,从而避免草地沙化继续恶化。     

冻融循环对温带3种林型下土壤微生物量碳、氮和氮矿化的影响

为了解冻融过程对森林土壤有机氮转化的影响,以长白山地区硬阔叶林、红松阔叶林和次生白桦林温带3种典型林型下的0—10 cm层(上层)和10—20 cm层(下层)土壤为试验材料,采用模拟冻融循环过程(-15—5℃)研究了冻融循环中3种林型下土壤微生物量和有效氮素的动态变化。结果表明:冻融培养过程中,多数情况下,3种林型上层土壤微生物量碳(SMBC,Soil Microbial Biomass Carbon)和土壤微生物量氮(SMBN,Soil Microbial Biomass Nitrogen)含量高于冻融循环前的对照处理(5℃恒温培养4 d后的土壤,记为CK)。冻融循环过程中3种林型下0—10 cm土层的SMBC和SMBN均显著高于10—20 cm土层(P0.05),表现出明显的SMBC和SMBN空间异质性特征。冻融过程对土壤NO_3~--N含量影响不明显,每种林型同层次不同冻融频次的土壤NO_3~--N含量间均无显著差异(P0.05)。3种林型0—10 cm层土壤的NH_4~+-N含量随冻融频次的增加表现相似的动态变化趋势,均在第3、4、5次冻融循环时表现出明显的NH_4~+-N释放特征。3种林型氮素矿(硝)化作用对冻融过程的响应明显,冻融温度变化、冻融频次和土壤层次对土壤净硝化率和净氮矿化率影响显著。3种林型下的土壤净硝化率波动偏大,0—10cm层在第2次冻融后出现最大峰值,其次为第7和第5次冻融循环。在3种林型0—10 cm层土壤中,土壤净硝化率与净氮矿化率均表现为:在短期冻融循环后达到峰值,而后呈现不同程度减小的趋势。     

河岸带不同植被类型土壤氮素转化过程对冻融交替的响应

河岸带是水陆交错地带氮素生物地球化学循环的热点区域,春季融雪时期的气温变化引起的冻融交替是影响土壤氮素转化过程和氮素流失重要因素之一.通过室内模拟,研究了河岸带珍珠梅、落叶松和农田3种植被类型土壤可溶性氮含量与净氮矿化速率对不同冻结温度和冻融频次的响应.结果表明,冻融频次对3种植被类型河岸带土壤可溶性氮影响显著(P＜0.05),不同植被类型土壤可溶性氮含量变化趋势相似,在第1次冻融之后达到峰值,在第10次冻融之后稳定.3种植被类型土壤无机氮含量受冻融交替影响显著升高(P＜0.05).冻融温度对土壤净氮矿化速率影响显著(P＜0.05),土壤净氮矿化速率在第1次冻融之后达到最大值,随冻融次数增加而下降.3种植被类型土壤受冻融交替影响均有一定程度的氮素流失风险,农田土壤无机氮含量本底值较高,土壤氮素随冰雪融水流失风险较大.     

免耕稻田氮肥运筹对土壤NH3挥发及氮肥利用率的影响

通过大田试验,设置5种不同的施肥比例(基肥:分蘖肥:拔节肥:穗肥-2:2:3:3(R1)、3:2:2:3(R2)、4:2:2:2(R3)、4:3:1:2(R4)与0:0:0:0(CK)),研究氮肥运筹对稻田NH₃挥发和氮肥利用率的影响。结果表明,(1)相对于不施肥,施肥显著提高了稻田NH₃挥发量。氮肥施用后,NH₃挥发损失量占施氮量的6.2%-8.5%,其中,以分蘖期NH₃挥发损失量最大,齐穗期次之,苗期和拔节期最小。施肥处理间,处理R1稻田累积NH₃挥发量最小,显著低于其它施肥处理,比处理R2、R3和R4分别低9.1%(P<0.05)、10.9%(P<0.05)和17.7%(P<0.05)。(2)相关分析表明,田面水NH₄⁺、pH值和土壤NH₄⁺和pH值均与稻田土壤NH₃挥发通量呈显著或者极显著相关;(3)处理R1水稻氮肥利用率相对于处理R2、R3和R4增加了28.4%(P<0.05)、55.4%(P<0.05)和74.9%(P<0.05)。研究表明,氮肥后移能有效降低免耕稻田NH₃挥发,提高水稻的氮肥利用率。     

天山林区不同类型群落土壤氮素对冻融过程的动态响应

季节性冻融过程对北方温带森林土壤氮素的转化与流失具有重要影响,但不同类型群落对冻融过程响应的差异尚不明确。通过在林地、草地、灌丛上设置系列监测样地,采用原位培养的方法,利用林冠遮挡形成的自然雪被厚度差异,监测分析了冻融期天山林区不同群落表层土壤(0—15 cm)的氮素动态及净氮矿化速率间的差异。结果表明:(1)不同类型群落土壤的铵态氮(NH+4-N)含量、微生物量氮(MBN)含量基本与土壤(5 cm)温度呈正相关,深冻期林地土壤铵态氮含量低于其他群落类型而硝态氮含量高于其他群落类型;(2)硝态氮(NO-3-N)为天山林区季节性冻融期间土壤矿质氮的主体,占比达78.4%。灌丛土壤硝态氮流失风险较大,融化末期较融化初期灌丛土壤硝态氮含量下降了64.6%;(3)冻融时期对整体氮素矿化速率影响显著,群落类型对氨化速率影响显著;(4)天山林区土壤氮素在冻结期主要以氮固持为主。通过揭示不同类型群落土壤氮素对冻融格局的响应,能够助益于对北方林区冬季土壤氮素循环的认识。     

不同生境盐地碱蓬对氮饥饿的响应

为了探讨不同生境盐地碱蓬对低氮生境的适应机制,测定了盐渍环境下(200 mmol/L Na Cl)不同浓度硝态氮(0.3、5 mmol/L NO~-_3-N)预处理两种生境盐地碱蓬经氮饥饿后的NO~-_3含量、硝酸还原酶(NR)活性、光合特性及生长状况。结果表明,0.3和5 mmol/L NO~-_3-N处理以及进行氮饥饿时,潮间带生境盐地碱蓬叶片NO~-_3含量均高于内陆生境盐地碱蓬。与内陆生境盐地碱蓬相比,氮饥饿后,潮间带生境盐地碱蓬叶绿素含量、NR活性和光合放氧速率下降幅度均小于内陆生境盐地碱蓬,在0.3mmol/L NO~-_3-N预处理进行氮饥饿时趋势更加明显。0.3 mmol/L NO~-_3-N预处理后氮饥饿对潮间带生境盐地碱蓬根冠比没有影响,却降低内陆生境盐地碱蓬根冠比。上述结果表明,低氮条件下潮间带生境盐地碱蓬具有较高的NO~-_3储存能力,在环境持续氮素缺乏时具有较高的NO~-_3-N再利用能力,能更好地维持氮代谢以及光合性能。说明潮间带生境盐地碱蓬能更好地适应低氮生境。     

应用15N示踪研究欧美杨对PM2.5无机成分NH4+和NO3-的吸收与分配

通过气溶胶发生系统模拟PM2.5颗粒的发生,运用15N示踪技术研究了欧美杨107(Populus euramericana Neva.)对PM2.5中水溶性无机成分NH+4和NO-3的吸收与分配规律。结果表明,欧美杨能够有效吸收PM2.5中的NH+4和NO-3。轻度和重度污染下,欧美杨叶片对NH+4和NO-3的吸收速率均于处理后第1天达到峰值,之后,轻度污染下对NH+4和NO-3的吸收速率迅速降低以后趋于稳定,而重度污染下对NH+4和NO-3的吸收速率缓慢下降至趋于稳定。轻度污染下的欧美杨叶片的15N含量在处理后第1天达到峰值,15N(NH+4)的含量为0.11 mg/g,干重,15N(NO-3)的为0.14 mg/g,干重,之后15N含量迅速下降至趋于稳定。重度污染下的叶片15N含量在处理第1天迅速增长,之后缓慢增长至处理后第7天达到最高值,15N(NH+4)的含量为0.11 mg/g,干重,15N(NO-3)的为0.13 mg/g,干重。处理7 d后,欧美杨不同组织器官吸收或通过再分配获取的15N含量存在差异。轻度污染下,细根对NH+4和NO-3的吸收量最高,树皮、叶柄、叶片次之,髓最低。而重度污染下,叶片对NH+4和NO-3的吸收量最高,细根、叶柄、树皮次之,髓最低。欧美杨各组织器官中NH+4和NO-3的含量均表现为重度污染大于轻度污染,且两种污染程度下的欧美杨各组织器官对NO-3的吸收均大于对NH+4的吸收。重度污染下,欧美杨茎木质部对15N(NH+4和NO-3)的吸收征调能力(Ndff,Nitrogen derived from fertilizer)最大,其次为髓,叶片最小;欧美杨各组织器官中的15N分配率表现为叶片细根叶柄树皮粗根茎木质部髓。研究结果对进一步揭示植物吸收PM2.5的机制及有效利用植物降低颗粒物污染、净化环境提供了重要的科学理论依据。     

关中地区小麦/玉米轮作农田硝态氮淋溶特点

通过田间原位淋溶装置研究了不同施氮量和秸秆覆盖对关中地区小麦/玉米轮作农田90cm深处硝态氮(NO3--N)淋溶量、0～1m土层硝态氮累积及作物产量和氮平衡的影响.试验设不施氮(N1,0kg·hm-2·a-1)、常规施氮(N2,471kg·hm-2·a-1)、推荐施氮(N3,330kg·hm-2·a-1)、减量施氮(N4,165kg·hm-2·a-1)、增量施氮(N5,495kg·hm-2·a-1)和推荐施氮+秸秆覆盖(N3+S)6个不同施肥处理.结果表明:NO3--N淋溶量随施氮量的增加而增大,氮肥的过量施用及秸秆覆盖易造成NO3--N淋溶.N3+S处理90cm处年NO3--N流失量最大,为22.32kg·hm-2,施肥造成的氮流失量为16.44kg·hm-2,比相同施氮量不覆盖处理(N3)高158.9%.NO3--N主要累积在20～60cm土层,年施氮量330kg·hm-2(N3)时,秸秆覆盖与否不影响NO3--N的剖面分布.各施肥处理对作物产量没有显著影响,但减量施氮处理(N4)有减少作物产量的趋势.在本试验条件下,推荐施肥量(小麦施氮150kg·hm-2,玉米施氮180kg·hm-2)在保证作物产量的同时,可减少土壤NO3--N的淋溶和累积.     

天山林区土壤总氮矿化过程对季节性冻融的响应

森林土壤总氮矿化对冻融过程的响应机制尚不明确,氮矿化速率和转化情况尚缺乏定量刻画。通过土壤原位法与室内培养分析相结合,利用¹⁵N同位素稀释技术,研究冻融期间天山林区乔木林地、灌丛、草地3种群落类型土壤总氮矿化及转化累积量的动态,分析土壤总氮矿化速率与土壤温度、含水率及微生物量氮(MBN)的相互关系。结果表明:(1)冻融过程及群落类型对总氮矿化速率和MBN含量有极显著的影响(P<0.01),秋、春季冻融期的总氮矿化速率相比冻结期更高;(2)季节性冻融期间,乔木林地土壤总氨化累积量在3种群落类型中最高(163.9 kg N hm^-2 a^-1),秋、春冻融期占整个时期的比值约为66%;而总硝化累积量在3种群落类型中相差较小,秋、春冻融期占比均约为77.4%;(3)土壤温度和含水率显著影响总氮矿化速率、净氮矿化速率和MBN速率,随土壤温度增加,总氨化速率(林地和灌丛)显著升高(P<0.05);随土壤含水率增加,净氨化速率(灌丛)和净硝化速率(灌丛)显著降低(P<0.05)。通过揭示天山林区土壤总氮矿化速率(总氨...     

武夷山不同海拔高度土壤氮矿化对温度变化的响应

采集了武夷山4个不同海拔的植物群落（常绿阔叶林、针叶林、亚高山矮林和高山草甸）的土壤样品,在实验室条件下, 将含水量调节为田间持水量60%,置于5 ℃、15 ℃、25 ℃和35 ℃人工气候箱中培养30 d,以测定土壤净氮矿化对温度的敏感性。结果表明：相同海拔植物群落的土壤净氮矿化量和氮矿化速率均随温度的升高显著增加;不同海拔间土壤氮矿化量和氮矿化速率大小均表现为：亚高山矮林>常绿阔叶林>高山草甸>针叶林。土壤氮矿化的Q₁₀在1.03～1.54,并且15 ℃升高到25 ℃时的Q₁₀比5 ℃升高到15 ℃和25 ℃升高到35 ℃时的Q₁₀高,表明土壤氮矿化对温度的敏感性在15 ℃～25 ℃较高。     

Effects of macro elements and nitrogen source on adventitious root growth and ginsenoside production in ginseng (Panax ginseng C. A. Meyer)

We investigated the effects on ginseng adventitious root growth and ginsenoside production when macro-element concentrations and nitrogen source were manipulated in the culture media. Biomass growth was greatest in the medium supplemented with 0.5-strength NH₄PO₃, whereas ginsenoside accumulation was highest (9.90 mg g^-1 DW) in the absence of NH₄PO₃. At levels of 1.0-strength KNO₃, root growth was maximum, but a 2.0 strength of KNO₃ led to the greatest ginsenoside content (9.85 mg g^-l). High concentrations of MgSO₄ were most favorable for both root growth and ginsenoside accumulation (up to 8.89 mg g^-1 DW). Root growth and ginsenoside content also increased in proportion to the concentration of CaCI₂ in the medium, with the greatest accumulation of ginsenoside (8.91 mg g^-1 DW) occurring at a 2.0 strength. The NH₄/NO₃ ^-- ratio also influenced adventitious root growth and ginsenoside production; both parameters were greater when the NO₃ ^- concentration was higher than that of NH₄ ⁺. Maximum root growth was achieved at an NH₄ ⁺/NO₃ ^- ratio of 7.19/18.50, while ginsenoside production was greatest (83.37 mg L^-1) when NO₃ ^- was used as the sole N source.     

增温和CO2浓度加倍对川西亚高山针叶林土壤可溶性氮的影响

采用全自动微气候控制的"人工模拟气候实验系统"研究了增温和CO2浓度加倍对川西亚高山针叶林土壤硝态氮(NO_3~--N)、铵态氮(NH_4~+-N)、游离氨基酸(FAA)、可溶性有机氮(DON)和可溶性总氮(TSN)的影响。结果表明:1在种植油松苗木组,增温处理显著降低了土壤NO_3~--N含量,不同处理0—15 cm土层NO_3~--N含量均显著小于15—30 cm层;而在未种树组,增温处理显著增加了土壤NO_3~--N含量,0—15 cm土层NO_3~--N含量显著高于15—30 cm层,这表明增温促进了油松苗对NO_3~--N的吸收。2在种植油松苗木组,增温(ET)、增CO_2(EC)及两者的共同作用(ETC)均显著增加了土壤NH_4~+-N、DON和TSN含量;在未种树组,ET显著增加了土壤NH_4~+-N、FAA、DON和TSN含量,EC和ETC对NH_4~+、FAA、DON和TSN含量具有微弱影响或没有显著影响。不同处理0—15cm层土壤NH_4~+-N、FAA、DON和TSN的含量显著大于15—30 cm层。3种植油松苗木组土壤NO_3~--N、NH_4~+-N、FAA、DON和TSN含量均显著低于未种树组,这是由植物对氮素的吸收消耗造成的。研究结果表明,EC、ETC主要通过植物根系作用促进了NH_4~+-N、DON和TSN含量增加,而ET处理通过影响土壤微生物和植物根系来促进NH_4~+-N、FAA、DON和TSN含量的增加。     

Sources of N uptake by wheat (Triticum aestivum L.) and N transformations in soil treated with a nitrification inhibitor (nitrapyrin)

Rates of N uptake by spring wheat as ammonium and as nitrate, and rates of nitrification, gross N immobilization and gross N mineralization were measured in a pot experiment during 84 days of growth in a clay soil. Soil treatments included an unfertilized control and addition of ¹⁵NH₄NO₃ or NH₄ ¹⁵NO₃ in the absence and presence of N-serve 24E. Incorporation of ammonium into the soil organic N pool was considerably higher in the presence compared to the absence of nitrapyrin, but the processes contributing to this effect could not be positively identified. Both dry matter and grain yield as well as N uptake by wheat were enhanced in the presence of the inhibitor in N fertilized soil, despite the increased immobilization of N. On the other hand, inhibitor application had a detrimental effect on yield and N uptake by wheat in unfertilized soil. Both ammonium and nitrate forms of inorganic N were absorbed by wheat, but nitrate uptake was dominant in the absence of the inhibitor. The uptake of N as ammonium was higher and the uptake of N as nitrate was less, both in absolute and proportional terms, in the presence compared to the absence of inhibitor. In addition, the proportion of N taken up as ammonium was higher than the proportion of N as ammonium in the available N pool up to day 56 in the inhibitor treatment, which indicated a preference for ammonium uptake by wheat. Evidence was obtained which suggested that several factors may have contributed to the positive response of wheat to inhibitor application in N fertilized soil, including reduced N losses, higher gross N mineralization and a physiological response due to the proportional increase in uptake of inorganic N as ammonium.     

季节性冻融期间川西亚高山/高山森林土壤净氮矿化特征

气候变暖情景下季节性冻融格局的改变可能显著影响高寒森林土壤氮素矿化过程.本文采用原状土壤移位培养的方法,以海拔梯度形成的温度差异模拟气候变暖,研究了川西亚高山/高山森林在生长季节和季节性冻融期间土壤的净氮矿化量和净氮矿化速率.结果表明： 在川西亚高山/高山森林,土壤铵态氮和硝态氮含量均表现为从生长季节至冻结初期明显下降,完全冻结期明显增加,而在融化初期明显降低的变化过程.季节性冻融期土壤的净氮矿化量和净氮矿化速率显著低于生长季节,并且出现明显的氮素固持现象.与低海拔相比,中海拔森林土壤的氮素固持作用相对较大,高海拔相对较小,可能与不同海拔梯度土壤温度变化及引起的冻融循环密切相关.在生长季节,土壤净氮矿化量和矿化速率均随海拔的降低呈明显增加趋势,尤其在低海拔处土壤的氮素矿化作用最为强烈.在气候变暖背景下,温度的增加明显促进了生长季节土壤氮素矿化,并且通过提高冻融循环频次、缩短冻结时间来影响土壤氮素矿化速率.这一过程可能受到微环境的影响.     

The influence of nitrogen concentration and ammonium/nitrate ratio on N-uptake,mineral composition and yield of citrus

In short-term water culture experiments with different ¹⁵N labeled ammonium or nitrate concentrations, citrus seedlings absorbed NH₄ ⁺ at a higher rate than NO₃ ^–. Maximum NO₃ ^– uptake by the whole plant occurred at 120 mg L^–1 NO₃ ^–-N, whereas NH₄ ⁺ absorption was saturated at 240 mg L^–1 NH₄ ⁺-N. ¹⁵NH₄ ⁺ accumulated in roots and to a lesser degree in both leaves and stems. However, ¹⁵NO₃ ^– was mostly partitioned between leaves and roots.Adding increasing amounts of unlabeled NH₄ ⁺ (15–60 mg L^–1 N) to nutrient solutions containing 120 mg L^–1 N as ¹⁵N labeled nitrate reduced ¹⁵NO₃ ^– uptake. Maximum inhibition of ¹⁵NO₃ ^– uptake was about 55% at 2.14 mM NH₄ ⁺ (30 mg L^–1 NH₄ ⁺-N) and it did not increase any further at higher NH₄ ⁺ proportions.In a long-term experiment, the effects of concentration and source of added N (NO₃ ^– or NH₄ ⁺) on nutrient concentrations in leaves from plants grown in sand were evaluated. Leaf concentration of N, P, Mg, Fe and Cu were increased by NH₄ ⁺ versus NO₃ ^– nutrition, whereas the reverse was true for Ca, K, Zn and Mn.The effects of different NO₃ ^–-N:NH₄ ⁺-N ratios (100:0, 75:25, 50:50, 25:75 and 0:100) at 120 mg L^–1 total N on leaf nutrient concentrations, fruit yield and fruit characteristics were investigated in another long-term experiment with plants grown in sand cultures. Nitrogen concentrations in leaves were highest when plants were provided with either NO₃ ^– or NH₄ ⁺ as a sole source of N. Lowest N concentration in leaves was found with a 75:25 NO₃ ^–-N/NH₄ ⁺-N ratio. With increasing proportions of NH₄ ⁺ in the N supply, leaf nutrients such as P, Mg, Fe and Cu increased, whereas Ca, K, Mn and Zn decreased. Yield in number of fruits per tree was increased significantly by supplying all N as NH₄ ⁺, although fruit weight was reduced. The number of fruits per tree was lowest with the 75:25 NO₃ ^–-N:NH₄ ⁺-N ratio, but in this treatment fruits reached their highest weight. Rind thickness, juice acidity, and colour index of fruits decreased with increasing NH₄ ⁺ in the N supply, whereas the % pulp and maturity index increased. Percent of juice in fruits and total soluble solids were only slightly affected by NO₃ ^–:NH₄ ⁺ ratio.