利用15N2直接标记法研究水稻种植对稻田固氮量和固氮活性的影响

稻田固氮对土壤维持肥力有着重要的作用,但水稻种植与固氮菌及其活性之间的关系尚不清楚。本试验利用¹⁵N₂直接标记法测定了下位砂姜土发育的简育水耕人为土在种水稻和不种水稻条件下的生物固氮量,及其在土壤不同层次(0～1、1～5、5～15 cm)和水稻中的分配,并通过实时荧光定量PCR技术测定了土壤中固氮菌nifH DNA及RNA基因数量。结果表明:种水稻处理显著提高了土壤各层固氮量,尤其提高了1～5 cm和5～15 cm土层土壤固氮量对总固氮量的贡献;种水稻处理的总固氮量是不种水稻处理的10.3倍;水稻植株中生物固定的氮占总固氮量的31.48%;在0～1 cm土层,种水稻处理显著提高了nifH RNA基因数量,而对nifH DNA基因数量的增加不显著。可见,水稻种植没有增加固氮菌的数量,稻田固氮量的增加是因为水稻种植极大地促进了固氮菌nifH基因的表达,提高了固氮菌的固氮活性。     

水分状况与供氮水平对土壤可溶性氮素形态变化的影响

采用通气培养试验,研究比较了两种水稻土在不同水分和供氮水平下的矿质氮(TMN)和可溶性有机氮(SON)的变化特征。结果表明,加氮处理及淹水培养均显著提高青紫泥的NH4+-N含量;除加氮处理淹水培养第7 d外,潮土NH4+-N含量并未因加氮处理或淹水培养而明显升高。无论加氮与否,控水处理显著提高两种土壤的NO3--N含量,其中潮土始见于培养第7 d,青紫泥则始于培养后21 d;加氮处理可显著提高淹水培养潮土NO3--N含量,却未能提高淹水培养青紫泥NO3--N含量。两种土壤的SON含量从开始培养即逐步升高,至培养21～35 d达高峰期,随后急剧下降并回落至基础土样的水平;SON含量高峰期,潮土SON/TSN最高达80%以上,青紫泥也达60%。综上所述,潮土不仅在控水条件下具有很强硝化作用,在淹水条件下的硝化作用也不容忽视,因此氮肥在潮土中以硝态氮的形式流失的风险比青紫泥更值得关注;在SON含量高峰期,两种土壤的可溶性有机氮的流失风险也应予以重视。     

Growth and Nitrogen Fixation in Dhaincha/Sorghum and Dhaincha/Sunflower Intercropping Systems Using 15Nitrogen and 13Carbon Natural Abundance Techniques

A field experiment on dhaincha, sunflower, and sorghum plants grown in monocropping and intercropping systems was conducted to evaluate growth and nitrogen (N₂) fixation using ¹³carbon (C) and ¹⁵N natural abundance techniques. Intercropping of sesbania/sorghum showed a greater efficiency than monocropping in producing dry matter during the entire growth period, whereas the efficiency of producing dry matter in the sesbania/sunflower intercropping was similar to that in the monocropping system. Moreover, sorghum plants (C4) were more competitive than sesbania (C3) for soil N uptake, whereas sesbania seemed to be more competitive than its associated sunflower (C3). Nitrogen uptake in the mixed stand of sesbania/sorghum was improved as a result of the increase in soil N uptake by the component sorghum and the greater root nodule activity of component sesbania without affecting the amount of N₂ fixed. The Δ ¹³C in plant materials was affected by plant species and the cropping system.     

水稻根际固氮量及根系不同部位的固氮活性

采用乙炔还原法测定水稻根际原状土粒的固氮活性,以3∶1的换算比例推算为田间固氮量。每季水稻根际固氮量早稻为0.4-0.45斤氮/亩/66天;晚稻为0.6-0.79斤氮/亩/72天。其中早稻80—90%的氮素在抽穗至成熟期固定,而晚稻在这段期间固定的氮素占总数的40—52%。经多次测定表明:水稻根系不同部位固氮活性的趋势是,埋入土中带根基茎段2.5厘米活性最高,根基以下3厘米根段次之,3厘米以下根段活性很低,水稻根系结合的腐生性细菌以固氮菌占优势,同时也含有少量的丁酸固氮梭菌。     

Inhibition of nitrogen uptake by rice after wheat straw application determined by tracer NH4 +-15N

This experiment was carried out to determine whether the delay in rice growth associated with wheat straw application, especially at the early stage, was due to the acceleration of N assimilation or N uptake inhibition.

Tracer ¹⁵N was used for rice plants cultivated in pots. After 24 h of tracer application the plants and soils were sampled for analysis. Seventeen days after transplanting, N uptake of rice decreased and the amount of unavailable tracer remaining in soil increased by wheat straw application. At the booting stage, 6 d before heading, N uptake was larger and the amount of remaining tracer was lower in the plots in which wheat straw was applied than in the control.

It was obvious that the decrease of N uptake by wheat straw application was caused by N uptake inhibition and not by N starvation for a period of time at the early stage. The inhibition was removed at the booting stage.     

受固氮活性制约的蓝藻固氮去铵阻抑及其与生理条件的关系

在不同气体环境中培养的蓝藻Ａｎａｂａｅｎａ７１２０固氮活性各异，Ａｒ＋ＣＯ２中最大，空气中次之，Ａｒ中最小。固氮活性高者去铵阻抑速率大，反之则小。它们对各种生理条件的反应不一样，固氮活性高者，其去铵阻抑速率受氧和氮的抑制小。在氢和氧加合条件下，三种活性的蓝藻去铵阻抑均加快，但活性低者慢而小些。光强减弱或加光合抑制剂时，固氮活性低者去铵阻抑速率显著小于活性高者，而添加外源的蔗糖或丙酮酸时，也是固氮活     

Determination of top-dressing for rice in the field by the detection of asparagine

It is well known that an increase of and better grain can be obtained by the application of an adequate amount of quick-acting nitrogen fertilizers such as ammonium sulphate, thirty to twenty five days before heading, and this is a common practice of top-dressing, being called “Hogoe” in Japanese. It is also well known that excess of nitrogen supplied at this time makes plants weak against mechanical injury, insects and disease. For the application of “Hogoe”, therefore, an accurate diagnosis of the nitrogen nutrient condition of rice is required. In a series of investigations on the nitrogen metabolism, the author found that asparagine appeared in parallel with the increase of nitrogen concentration in rice plants, and considered that the detection of asparagine would be a good indicator for assessing the nitrogen requirement of rice lantst^l).     

Uptake of carbon and nitrogen through roots of rice and corn plants,grown in soils treated with 13C and 15N dual-labeled cattle manure compost

Nitrogen and carbon dynamics in paddy and upland soils for rice cultivation and in upland soil for corn cultivation was investigated by using ¹³C and ¹⁵N dual-labeled cattle manure compost (CMC). In a soil with low fertility, paddy and upland rice took up carbon and nitrogen from the CMC at rates ranging from 0.685 to 1.051% of C and 17.6–34.6% of N applied. The ¹³C concentration was much higher in the roots than in the plant top, whereas the ¹⁵N concentration differed slightly between them, indicating that organic carbon taken up preferentially accumulated in roots. The ¹³C recovery in the plant top tended to be higher in upland soil than in paddy soil, whereas ¹⁵N applied was recovered at the same level in both paddy and upland soils. In the experiment with organic farming soil, paddy rice took up C and N from the CMC along with plant growth and the final recovery rates of ¹³C and ¹⁵N were 2.16 and 17.2% of C and N applied. In the corn experiment, a very large amount of carbon from the CMC was absorbed, accounting for at least 7 times value for rice. The final uptake rates of ¹³C and ¹⁵N reached about 13 and 10% of C and N applied, respectively. Carbon emission from the CMC sharply increased by 2 weeks after transplanting and the nitrogen emission was very low. It is concluded that rice and corn can take up an appreciable level of carbon and nitrogen from the CMC through roots.     

Modeling aerobic decomposition of rice straw during the off-rice season in an Andisol paddy soil in a cold temperate region of Japan: Effects of soil temperature and moisture

Submerged rice paddies are a major source of methane (CH₄) which is the second most important greenhouse gas after carbon dioxide (CO₂). Accelerating rice straw decomposition during the off-rice season could help to reduce CH₄ emission from rice paddies during the single rice-growth season in cold temperate regions. For understanding how both temperature and moisture can affect the rate of rice straw decomposition during the off-rice season in the cold temperate region of Tohoku district, Japan, a modeling incubation experiment was carried out in the laboratory. Bulk soil and soil mixed with 2% of δ¹³C-labeled rice straw with a full factorial combination of four temperature levels (?5 to 5, 5, 15, 25°C) and two moisture levels (60% and 100% WFPS) were incubated for 24 weeks. The daily change from ?5 to 5°C was used to model the freezing–thawing cycles occurring during the winter season. The rates of rice straw decomposition were calculated by (i) CO₂ production; (ii) change in the soil organic carbon (SOC) content; and (iii) change in the δ¹³C value of SOC. The results indicated that both temperature and moisture affected the rate of rice straw decomposition during the 24-week aerobic incubation period. Rates of rice straw decomposition increased not only with high temperature, but also with high moisture conditions. The rates of rice straw decomposition were more accurately calculated by CO₂ production compared to those calculated by the change in the SOC content, or in its δ¹³C value. Under high moisture at 100% WFPS condition, the rates of rice straw decomposition were 14.0, 22.2, 33.5 and 46.2% at ?5 to 5, 5, 15 and 25°C temperature treatments, respectively. While under low moisture at 60% WFPS condition, these rates were 12.7, 18.3, 31.2 and 38.4%, respectively. The Q₁₀ of rice straw decomposition was higher between ?5 to 5 and 5°C than that between 5 and 15°C and that between 15 and 25°C. Daily freezing–thawing cycles (from ?5 to 5°C) did not stimulate rice straw decomposition compared with low temperature at 5°C. This study implies that to reduce CH₄ emission from rice paddies during the single rice-growth season in the cold temperate regions, enhancing rice straw decomposition during the high temperature period is very important.     

Responses of soil phosphorus pools accompanied with carbon composition and microorganism changes to phosphorus-input reduction in paddy soils

In rice-wheat rotation systems, changes in soil phosphorus(P) pools and microorganisms in rice-growing seasons have been studied;however, further investigations are required to test whether these indexes exhibit different responses in wheat-growing seasons. Additionally, such studies need to include potential variations in soil carbon(C) structure and microbial community composition. In this study, a long-term rice-wheat rotation P-input reduction experiment was conducted to observe the variations in soil P pools and C composition in the 7th wheat season and to investigate the responses of soil enzyme activity and microbial communities. Four P fertilization treatments were included in the experiment, i.e., P application for rice season only(PR), for wheat season only(PW), and for both rice and wheat seasons(PR+W) and no P application in either season(Pzero). Compared with PR+W treatment, Pzero treatment significantly decreased(P < 0.05) labile and stable P pools. Different P fertilization regimes altered soil microbial community composition and enzyme activity, whereas C composition did not vary. However, PW treatment resulted in relatively more O-alkyl-C than PR treatment and the highest number of microorganisms. Besides, the higher ratios of fungi/bacteria and Gram-positive bactetia/Gram-negative bactetia were related to labile C pools, particularly O-alkyl-C, as opposed to recalcitrant C. Our results clarified the status of soil P pools, C chemistry, and the response of microorganisms under dry-farming conditions in the P input-reduced rice-wheat rotation system.     

Nitrogen fixation and balance studies of rice soil

Summary A nitrogen balance study conducted in ceramic pots under net house conditions for four seasons showed that flooded rice soil leaves a positive nitrogen balance (N increase) in soil after rice cropping in both fertilized and unfertilized soil. Recovery of nitrogen from rice soil was more than its input in unfertilized soil, but it was reverse in fertilized soil. Incorporation of Azolla or BGA twice as basal and 20 days after transplanting (DAT) alone or in combination showed higher nitrogen balance and N₂-fixation (N gain) in soil than in that where it was applied once either as basal or 20 DAT. Planted soil showed more N₂-fixation than that of fallow rice, and flooded soil fixed more nitrogen in comparison to non-flooded soil in light but less in dark. Soil exposed to light fixed more nitrogen than that of unexposed soil in both flooded and non-flooded conditions.     

减氮配施有机物质对土壤氮素淋失的调控作用

采用室内土柱模拟试验方法,研究不同氮肥施用下1m土体中氮素的分布和移动特征,揭示土壤氮素动态变化规律。结果表明:FN(农民习惯施无机氮用量)、RN(根据土壤养分供应和作物需求确定的推荐无机氮用量)显著增加了土壤上层NH_4^+-N和NO_3^--N向下层淋失。RN+HA(与推荐无机氮纯养分相等的锌腐酸尿素)和RN40%+OMB(推荐无机氮肥减60%基础上配施自制有机调理物质)可延长上层土壤NH_4^+-N峰值出现时间,降低下层NH_4^+-N。淋溶结束后,等氮量下增施HA较RN降低60cm以下NH_4^+-N残留29.7%～54.2%;降低60—80cm NO_3^--N累积17.4%。RN40%+OMB处理无机氮肥用量最小,0—20cm的NH_4^+-N最高,40—100cm稳定在2.0mg/kg左右;0—20,20—40cm土层NO_3^--N较RN+HA增加12.3%和2.0%,显著降低40cm以下NO_3^--N残留。RN+HA和RN40%+OMB较RN的土壤总无机氮残留分别减少7.4%和20.2%,降低表观淋失率。因此,RN40%+OMB可较好地抑制氮素下移,降低氮素淋失风险,为减少氮素淋失、明确合理氮肥施用方式提供科学依据。     

Conversion of forest to agricultural land affects the relative contribution of bacteria and fungi to nitrification in humid subtropical soils

Land-use and management practices can affect soil nitrification. However, nitrifying microorganisms responsible for specific nitrification process under different land-use soils remains unknown. Thus, we investigated the relative contribution of bacteria and fungi to specific soil nitrification in different land-use soils (coniferous forest, upland fields planted with corn and rice paddy) in humid subtropical region in China. ¹⁵N dilution technique in combination with selective biomass inhibitors and C₂H₂ inhibition method were used to estimate the relative contribution of bacteria and fungi to heterotrophic nitrification and autotrophic nitrification in the different land-use soils in humid subtropical region. The results showed that autotrophic nitrification was the predominant nitrification process in the two agricultural soils (upland and paddy), while the nitrate production was mainly from heterotrophic nitrification in the acid forest soil. In the upland soils, streptomycin reduced autotrophic nitrification by 94%, whereas cycloheximide had no effect on autotrophic nitrification, indicating that autotrophic nitrification was mainly driven by bacteria. However, the opposite was true in another agricultural soil (paddy), indicating that fungi contributed to the oxidation of NH₄⁺ to NO₃^?. In the acid forest soil, cycloheximide, but not streptomycin, inhibited heterotrophic nitrification, demonstrating that fungi controlled the heterotrophic nitrification. The conversion of forest to agricultural soils resulted in a shift from fungi-dominated heterotrophic nitrification to bacteria- or fungi-dominated autotrophic nitrification. Our results suggest that land-use and management practices, such as the application of N fertilizer and lime, the long-term waterflooding during rice growth, straw return after harvest, and cultivation could markedly influence the relative contribution of bacteria and fungi to specific soil nitrification processes.     

Changes in acetylene reduction activities and effects of inoculated rhizosphere nitrogen-fixing bacteria on rice

Acetylene reduction activities (ARAs) of soils and rice plants during rice-growing season were monitored in temperate region in northeast China. This activity was significantly higher in rhizosphere soil than that in inter-row soil after rice seedlings were transplanted. The ARA was high for most of growing season, suggesting that the native N₂-fixing bacteria responded to rice roots very quickly. Sixteen strains of free-living N₂-fixing bacteria were isolated from three different soils. The ARAs of these strains were correlated with the averaged soil ARAs, suggesting that the isolated strains were likely the active flora responsive to rice roots. The strains were inoculated by soaking seedling roots into the liquid culture for 2 h, and the seedlings were transplanted into pots. Most strains tested did not show any growth-promoting effects except Azotobacter armeniacus and Azotobacter nigricans, which showed growth-promoting effects only at late rice growth stage and only when inoculated in combination but not separately. Present data indicated the promising future applications of these two strains in combination in the region, but further research is needed to understand the underlying mechanisms.     

连续翻压紫云英对福建单季稻产量与化肥氮素吸收、分配及残留的影响

【目的】紫云英翻压后在一定程度上可改善土壤理化性状,并提高后作水稻的产量,但是该机理是由于紫云英翻压矿化后提供的氮素还是由于与翻压紫云英后化肥氮素利用率的提高有关尚不清楚,因此,本项目通过连续4年紫云英翻压还田的定位试验与原状土柱模拟及15N示踪,研究了福建单季稻区紫云英压青回田对水稻产量与化肥15N吸收、 分配及残留的影响。【方法】采用单季稻田间定位试验,设5个处理: 1）对照,不翻压紫云英,不施化肥（CK）;2）不翻压紫云英,常规化肥施用量（100%H）;3）紫云英＋常规化肥用量（Z+100%H）;4）紫云英＋60%的常规化肥（Z+60%H）;5）只翻压紫云英,不施化肥（Z）。常规化肥用量（100%H）为施氮量N 135 kg/hm2,N∶P2O5∶K2O=1∶0.4∶0.7,每年紫云英翻压量为18000 kg/hm2。每个处理3次重复,小区面积15 m2,种植水稻为每小区2015丛。于定位试验的第4年,在田间定位试验小区中,采用15N-尿素（丰度10%）示踪法与原状土柱模拟水稻植株的氮素吸收及分配情况。PVC管直径25 cm,长35 cm,其中压入田面下20 cm,每小区埋两个土柱,每个土柱中种植两株水稻。【结果】紫云英年翻压18000 kg/hm2并结合施用100%化肥（Z+100%H）,水稻子粒4年平均产量比单施100%化肥（100%H）增产6.5%,同时在18000 kg/hm2 的紫云英翻压量下,主作物水稻化肥减量40%（Z+60%H）的产量与100%H的处理基本相当。Z+100%H处理对提高水稻分蘖期植株氮含量最为明显,尤其是茎叶氮含量较100%H提高7.0%,差异显著。虽然不同施肥处理水稻生育期的化肥氮素利用率无明显变化,但Z+100%H处理分蘖期与成熟期植株氮素吸收量分别较100%H提高23.0%与18.0%,说明绿肥与化肥配施有利于水稻植株吸收外源氮素,且植株吸收氮的差异主要来自于紫云英矿化的氮源。Z+60%H 与100%H处理的分蘖期与成熟期植株氮素吸收量则基本相当。不同施肥处理均有提高土壤全氮含量的趋势;Z+60%H 处理的耕层土壤化肥氮素的残留率最高,并显著高于Z+100%H处理。【结论】连续4年翻压紫云英明显提高了福建单季稻区黄泥田的农田生产力,在减少40%常规化肥用量的情况下仍可维持产量稳定。翻压绿肥减肥增效的主要机制之一是紫云英矿化的养分替代了化肥。     

宁夏引黄灌区稻田氮素浓度变化与迁移特征

过量施氮与不合理灌水是农田面源污染加剧的主要原因。为了寻求较优的水氮管理模式以促进农业生产和减少农田退水对黄河水体的污染, 在宁夏引黄灌区典型稻田中开展了不同水氮条件下稻田氮素迁移转化规律研究。结果表明: 不同水氮条件下稻田田面水NH₄⁺-N 与NO₃^--N 浓度伴随施肥出现明显峰值, NO₃^--N 峰值出现时间较NH₄⁺-N 晚, 且变化较平缓。3 次追肥时期和整个生育期田面水NH₄⁺-N 平均浓度与施氮量和灌水量都呈显著相关, 田面水NO₃^--N 平均浓度与施氮量呈显著正相关, 与灌水量相关性不显著。稻田30 cm与60 cm 深度的直渗水NH₄⁺-N 浓度受施肥影响较大, 与田面水NH₄⁺-N 浓度变化规律相似, 90 cm 处直渗水NH₄⁺-N 浓度峰值出现较为滞后, 且浓度较上层土体低, 120 cm 处直渗水NH₄⁺-N 浓度大体呈现持续上升趋势,整个生育期直渗水NH₄⁺-N 平均浓度与施氮量呈显著相关, 仅30 cm 处NH₄⁺-N 平均浓度与灌水量呈负相关, 其他土层深度不显著。30 cm 与60 cm 直渗水NO₃^--N 浓度在首次灌水后急剧下降, 在施肥后有较小幅度上升, 90 cm 与120 cm 直渗水NO₃^--N 浓度下降缓慢, 仅30 cm 处NO₃^--N 平均浓度与施肥量显著正相关。总的结果表明减少施肥或灌水均可达到减少农田氮素淋失的目的。     

Paddy System with a Hybrid Rice Enhances Cyanobacteria Nostoc and Increases N2 Fixation

Biological nitrogen(N) fixation(BNF) plays a significant role in maintaining soil fertility in paddy field ecosystems. Rice variety influences BNF, but how different rice varieties regulate BNF and associated diazotroph communities has not been quantified. Airtight,field-based ~(15)N_2-labelling growth chamber experiments were used to assess the BNF capacity of different rice varieties. In addition,both the 16 S rRNA and nifH genes were sequenced to assess the influence of different rice varieties on bacterial and diazotrophic communities in paddy soils. After subjecting a rice-soil system to 74 d of continuous airtight, field-based ~(15)N_2 labelling in pots in a growth chamber, the amounts of fixed N were 22.3 and 38.9 kg ha~(-1) in inbred japonica(W23) and hybrid indica(IIY) rice cultivars planted in the rice-soil systems, respectively, and only 1%–2.5% of the fixed N was allocated to the rice plants and weeds. A greater abundance of diazotrophs was found in the surface soil(0–1 cm) under IIY than under W23. Sequencing of the 16 S rRNA gene showed significantly greater abundances of the cyanobacterial genera Nostoc, Anabaena, and Cylindrospermum under IIY than under W23.Sequencing of the nifH gene also showed a significantly greater abundance of Nostoc under IIY than under W23. These results indicate that the hybrid rice cultivar(IIY) promoted BNF to a greater extent than the inbred rice cultivar(W23) and that the increase in BNF might have been due to the enhanced heterocystous cyanobacteria Nostoc.     

外源水稻根系和茎叶碳氮在稻田土壤中释放的特征

东北地区气候寒冷,稻田土壤休耕期长,多处于冻结状态;水稻生长期短,土壤温度高且季节性淹水。外源水稻秸秆碳氮在东北地区稻田土壤休耕期和水稻生长期不同水热条件下的释放特征尚不完全清楚。通过室外培养试验方法,利用双标记(~(13)C和~(15)N)水稻根系和茎叶示踪技术和稳定同位素质谱分析技术,研究水稻根系和茎叶在稻田土壤中的腐解率、有机碳(氮)释放率的动态变化特征。结果表明:水稻茎叶、根系于秋季添加稻田土壤后,经过寒冷漫长的土壤休耕期(11月至次年5月),S1(标记根系+不标记茎叶)和S2(不标记根系+标记茎叶)处理的秸秆腐解率分别达30.2%和34.5%,水稻根系和茎叶碳释放率分别达30.9%和38.2%,氮释放率分别达7.4%和35.0%。添加一年时,S1和S2处理的秸秆腐解率分别达66.5%和66.6%,水稻根系和茎叶碳释放率分别为63.7%和65.8%,氮释放率分别为28.6%和51.1%,水稻根系氮释放率显著低于水稻茎叶氮释放率(P0.05)。本试验条件下,水稻根系和茎叶添加稻田土壤1年,水稻根系和茎叶的腐解率达65%左右,其碳释放与腐解几乎同步,但氮释放相对缓慢,水稻根系氮释放速度显著低于茎叶氮释放速度,温度升高明显促进了水稻根系和茎叶的腐解及其碳氮释放。     

利用15N揭示滴灌区盐旱胁迫对土壤氮素分布与棉花生长的影响

为了探究盐旱胁迫对土壤中氮素分布和棉花生长的影响,通过测坑试验研究滴灌区不同盐分、干旱条件下土壤全氮、硝氮、氨氮的分布和棉花生长情况。试验设置3种盐分梯度的土壤（电导率,EC）：3,6,9 dS/m,分别用T1、T2、T3表示;3个灌水量：2 700,3 600,4 500 m³/hm²,分别用W1、W2、W3表示（4 500 m³/hm²为当地推荐灌水量）。结果表明：当土壤盐分梯度> 3 dS/m时土壤全氮累积量显著高于低盐土壤（P<0.05）,且土壤盐分对棉花花期生长影响较大。土壤的氨氮挥发量和土壤盐分梯度成正比。土壤硝态氮的淋失与灌水量呈正比,与正常灌水量的硝态氮淋失相比,水分胁迫对棉花产量的影响更为严重（P<0.01）。随土层深度的增加,土壤碱解氮以每20 cm土层8%的速度减少。各处理土壤¹⁵N残留率为11%~40%,随土壤盐度增加而增加,随灌水量增加而减少,与土壤全氮含量呈正比,与棉花产量呈反比。综上所述,T1W3处理更有利于棉花对氮肥的利用和产量的提高,推荐滴灌区棉花土壤盐度<3 dS/m,灌水量4 500 m³/hm²,可在花期适当提高施肥量以稳定产量。     

黄绵土与淋溶土含水量与施肥方法对铵固定和肥料氮回收率的影响

Ammonium fixation and the effects of soil moisture and application methods on fertilizer N recovery were investigatedin two soils of Shaanxi Province, China, a Luvisol and an Entisol, through two experiments performed in the laboratoryand in a glass shelter, respectively, by using ammonium bicarbonate (NH4HCO3). The laboratory closed incubationbox experiment was conducted using the Luvisol to study NH fixation rate at soil moisture levels of 10.1%, 22.7% and 35.3% water filled pore space (WFPS). The fixed NH -N increased dramatically to 51% and 66%, 67% and 74%,and 82% and 85% 1, 2 and 36 h after fertilizer incorporation at moisture levels of 10.1% and 22.7% WFPS and 35.3% WFPS, respectively. The rapid NH fixation rates at all moisture levels could help prevent NH losses from ammonia volatilization. In the glass shelter pot experiment, N fertilizer was applied by either banding (in a concentrated strip)or incorporating (thoroughly mixing) with the Entisol and the Luvisol. An average of 74.2% of the added N fertilizerwas recovered 26 days after application to the Luvisol, while only 61.4% could be recovered from the Entisol, due tohigher NH fixation capacity of the Luvisol. The amount of fixed NH decreased with increasing WFPS. The amountof fixed NH in the incorporated fertilizer treatment was, oll average, 10% higher than that in the banded treatment.Higher NH fixation rates could prevent N loss and thus increase N recovery. The results from the Luvisol showed lowernitrogen recovery as soil moisture level increased, which could be explained by the fact that most of the fixed NH wasstill not released when the soil moisture level was low. When the fertilizer was incorporated into the soil, the recovery ofN increased, compared with the banded treatment, by an average of 26.2% in the Luvisol and 11.2% in the Entisol, whichimplied that when farmers applied fertilizer, it would be best to mix it well with the soil.