不同耕作方式与秸秆还田对稻田氮磷养分径流流失的影响

为明确自然降雨条件下稻田田面水氮磷养分径流流失特征,寻求秸秆还田和耕作方式结合下较为有效的减排农艺措施,通过田间试验研究自然降雨条件下不同耕作方式和秸秆还田对稻田田面水氮磷养分径流流失的影响。结果表明:秸秆还田处理较秸秆不还田处理更能够有效减少稻田氮磷养分径流流失总量;秸秆不还田条件下,翻耕、旋耕、免耕总氮径流流失量分别为6.78,8.50,11.09kg/hm2,总磷流失量分别为0.50,0.63,0.78kg/hm2;秸秆还田条件下,翻耕、旋耕、免耕总氮流失量分别为4.82,6.44,8.87kg/hm2,总磷流失量分别为0.39,0.51,0.70kg/hm2;整个稻季氮素径流流失率以免耕秸秆不还田为最高,达3.70%,翻耕秸秆还田为最低,仅为1.61%,磷素径流流失率也是免耕秸秆不还田最高,翻耕秸秆还田最低,分别为1.31%和0.65%。     

养分缺乏下外源有机酸对暗棕壤磷有效性及落叶松幼苗吸收积累磷的影响

用不同比例A1和B层暗棕壤混合(A1∶B=1∶2)制造土壤养分缺乏条件,栽植落叶松幼苗,通过模拟我国东北林区代表性森林凋落物淋洗液中有机酸的种类和数量,系统研究养分缺乏下,不同浓度外源有机酸对暗棕壤磷有效性和落叶松幼苗吸收、运输磷素养分的影响及机理,以探讨利用有机酸提高养分缺乏下落叶松幼苗抗土壤贫瘠能力的可行性及机制。结果表明,A1层与B层混合土壤速效磷含量降低,落叶松幼苗根系和叶片磷累积量和磷吸收效率降低,但磷利用效率增加。外源有机酸处理后,混合土壤的速效磷含量有不同程度提高,3种有机酸的作用强弱表现为琥珀酸>柠檬酸>草酸,一般以浓度5.0mmol/L和处理20d时提高效果最显著。有机酸不同程度提高了根系和叶片的磷累积量和磷吸收效率,但降低了磷利用效率。有机酸对磷累积量和磷吸收效率的提高程度因处理时间、有机酸浓度和种类而异:对于根系,20d和30d的结果高于10d,叶片则为10d和20d的结果高于30d,说明处理前期磷被吸收后向叶片的转移量较多,而后期则更多地在根中积累;3种有机酸大多在浓度为10.0mmol/L时提高幅度最大;不同有机酸的促进程度为琥珀酸>柠檬酸>草酸。因此,外源有机酸能通过提高落叶松幼苗对养分缺乏土壤中磷的吸收能力,促进磷的积累,进而提高苗木对养分缺乏土壤的耐性和适应能力。     

Effect of Lime and Flooding on Phosphorus Availability and Rice Growth on Two Acidic Lowland Soils

Abstract

Loss of soil‐water saturation may impair growth of rainfed lowland rice by restricting nutrient uptake, including the uptake of added phosphorus (P). For acidic soils, reappearance of soluble aluminum (Al) following loss of soil‐water saturation may also restrict P uptake. The aim of this study was to determine whether liming, flooding, and P additions could ameliorate the effects of loss of soil‐water saturation on P uptake and growth of rice. In the first pot experiment, two acid lowland soils from Cambodia [Kandic Plinthaqult (black clay soil) and Plinthustalf (sandy soil)] were treated with P (45 mg P kg^?1 soil) either before or after flooding for 4 weeks to investigate the effect of flooding on effectiveness of P fertilizer for rice growth. After 4 weeks, soils were air dried and crushed and then wet to field capacity and upland rice was grown in them for an additional 6 weeks. Addition of P fertilizer before rather than after flooding depressed the growth of the subsequently planted upland rice. During flooding, there was an increase in both acetate‐extractable Fe and the phosphate sorption capacity of soils, and a close relationship between them (r²=0.96–0.98). When P was added before flooding, Olsen and Bray 1‐extractable P, shoot dry matter, and shoot P concentrations were depressed, indicating that flooding decreased availability of fertilizer P. A second pot experiment was conducted with three levels of lime as CaCO₃ [to establish pH (CaCl₂) in the oxidized soils at 4, 5, and 6] and four levels of P (0, 13, 26, and 52 mg P kg^?1 soil) added to the same two acid lowland rice soils under flooded and nonflooded conditions. Under continuously flooded conditions, pH increased to over 5.6 regardless of lime treatment, and there was no response of rice dry matter to liming after 6 weeks' growth, but the addition of P increased rice dry matter substantially in both soils. In nonflooded soils, when P was not applied, shoot dry matter was depressed by up to one‐half of that in plants grown under continuously flooded conditions. Under the nonflooded conditions, rice dry matter and leaf P increased with the addition of P, but less so than in flooded soils. Leaf P concentrations and shoot dry matter responded strongly to the addition of lime. The increase in shoot dry matter of rice with lime and P application in nonflooded soil was associated with a significant decline in soluble Al in the soil and an increase in plant P uptake. The current experiments show that the loss of soil‐water saturation may be associated with the inhibition of P absorption by excess soluble Al. By contrast, flooding decreased exchangeable Al to levels below the threshold for toxicity in rice. In addition, the decreased P availability with loss of soil‐water saturation may have been associated with a greater phosphate sorption capacity of the soils during flooding and after reoxidation due to occlusion of P within ferric oxyhydroxides formed.     

土壤优先流运动的活动流场模型分形特征参数计算

活动流场模型分形特征参数控制着优先流的产生和发展,因此准确获得活动流场模型分形特征参数值对提高模型的模拟预测精度具有重要意义。该研究采用染色示踪方法,将优先流流场从流动背景中显示出来,通过数字图像分析和采样分析获得优先流流场和流场内土壤含水率的分布模式,根据活动流场模型本构方程拟合活动流场模型分形特征参数值;针对3种常见的入渗后染色区内土壤含水率分布模式,分别提供了相应的活动流场模型分形特征参数的计算方法。研究结果显示,1）由于入渗后土壤水重分布的影响,活动流场区域和染色区域在整个入渗深度范围并不完全重合,因此仅可选择活动流场与染色区域相重合深度范围内受土壤初始含水率影响较小的数据来拟合活动流场模型分形特征参数值;2）土壤质地对入渗后染色区内土壤含水率的分布模式有显著影响,细质地土壤中入渗后染色区土壤含水率沿入渗方向逐渐减小,粗质地土壤中入渗后染色区土壤含水率沿入渗方向先增大后减小。     

模拟酸雨胁迫对赤红壤磷素形态特征的影响

通过田间小区模拟酸雨实验,研究酸雨胁迫下赤红壤不同磷素形态变化的方向和程度。结果表明,原位模拟酸雨影响下,一定强度（pH≥4.0）的酸雨胁迫能有效促进有效磷的释放,而当pH〈4.0强度酸雨胁迫时有效磷的释放随pH值降低逐渐受到抑制。随酸雨酸度的增强,土壤酸性磷酸酶和微生物量磷均呈现先升高后降低的变化趋势,可见一定强度酸雨胁迫能促进溶磷微生物和磷酸酶活性,而当高强度酸雨胁迫时土壤微生物活动逐渐受到抑制。无机磷组分中Al-P、Ca-P和Fe-P含量均随酸雨酸度的增强而降低,土壤O-P含量没有显著变化。相关分析发现,有效磷含量与微生物量磷、酸性磷酸酶呈极显著正相关,表明此时土壤有效磷变化与有机磷矿化关系最为密切。有效磷含量与各种形态无机磷（Al-P、O-P、Ca-P和Fe-P）含量之间也有较强的正相关性,表明土壤生态系统磷素转化是一个自我调节的动态平衡过程,且在一定条件下可以相互转化。     

畜禽废水磷回收产物的磷素释放特性及肥效试验研究

以畜禽废水沼气发酵液为磷回收对象,采用曝气沉淀结晶法磷回收工艺,对回收产物进行水溶性磷连续浸提试验和玉米盆栽试验,考察畜禽废水磷回收产物的磷素动态释放情况、玉米盆栽的肥效以及磷素利用情况。浸提试验表明,磷回收产物经6次浸提,水溶性磷的释放量呈缓慢下降的趋势,第6次与第1次相比只下降了1.42%,总释放量占总磷的57.97%,证明磷回收产物（RPP）具有良好的缓释性,作为肥料使用时不易被水淋失。盆栽试验表明,用RPP以不同比例代替磷酸一铵作为肥料对玉米均能起到显著的增产作用,最佳的质量替代比例为40%;RPP较磷酸一铵的地上部分和地下部分磷素利用率分别高出19.14%和2.50%,显示其具有较高的磷吸收效率。因此,从畜禽废水沼气发酵液中回收得到的磷回收产物具有较高的肥效价值,是一种节约资源、保护环境、缓解磷资源危机的新型肥料。     

横垄耕作的面源污染截留效应研究

为了解横垄耕作的面源污染截留效应,选取吉林省长春市莫家沟小流域横垄耕作坡耕地为研究区,应用210Pbex核素示踪技术得到研究区土壤侵蚀模数为2 268 t/(km2.a),吸附态氮、磷流失负荷分别为4 889、2 022 kg/a;运用RU-SLE2.0模型,模拟在同等立地条件下顺坡耕作土壤侵蚀模数约为6 200 t/(km2.a)。对比结果表明:横垄耕作较顺坡耕作可减少约63%的土壤流失量及随土壤流失的吸附态氮磷负荷。     

保护性耕作对小麦-土壤系统综合效应研究

采用长期定位试验与短期田间试验相结合的方法,通过室内化验分析和数理统计,研究了河南省不同土壤类型区保护性耕作对土壤理化性质、土壤微生物生物量碳氮及小麦(Triticum aestivum L.)籽粒产量和产量构成因素的影响。结果表明,与传统耕作相比,保护性耕作显著提高土壤有机质、碱解氮、有效磷及交换性钾含量,分别提高24.8%、14.3%、7.8%和24.8%;而对小麦增产效果并不显著。4种不同保护性耕作方式下,免耕、浅耕相比旋耕、深耕,提高小麦穗数15.0%～32.2%,提高穗粒数2.6%～12.6%,但4种处理间小麦千粒重及籽粒产量效果无显著差异;免耕、浅耕较旋耕、深耕可以一定程度上提高苗期和灌浆期土壤含水率、以及土壤碱解氮和有效磷,并显著提高小麦不同生育时期的土壤微生物生物量碳氮。免耕与浅耕是较为适宜河南省小麦生产及土壤可持续利用的保护性耕作方式。     

GENOTYPIC DIFFERENCES IN ROOT MORPHOLOGY AND PHOSPHORUS UPTAKE KINETICS IN BRASSICA NAPUS UNDER LOW PHOSPHORUS SUPPLY

Application of phosphorus (P) fertilizer is important in crop production because of the low bioavailability of phosphorus to plants in both acidic and calcareous soils. Although rapeseed (Brassica napus) is generally sensitive to P deficiency, different cultivars differ widely in this respect. Differences in P uptake and utilization between two rapeseed cultivars, one P-efficient (‘97081’) and one P-inefficient (‘97009’), were evaluated in solution culture by studying the changes in root morphology and parameters of P uptake kinetics in response to low-P stress. The P-efficient cultivar had lower Km and Cmin values and higher Vmax and developed longer and denser lateral root hair with greater number of root tips and branches under low-P stress, which resulted in a better developed root system and more efficient uptake of P. That, in turn, led to higher concentration and accumulation of P in the plants, culminating in higher biomass production. However, P utilization efficiency (biomass production per unit P accumulated in plant) of the P-efficient ‘97081’ was lower than that of ‘97009’ when P was deficient. These results suggest that P efficiency in rapeseed is due to a better developed root system as well as efficient uptake of P.     

Arbuscular mycorrhizal fungi improve the growth and phosphorus uptake of mung bean plants fertilized with composted rock phosphate fed dung in alkaline soil environment

Abstract

Inoculation effect of arbuscular mycorrhizal fungi (AMF) on phosphorus (P) transfer from composted dung of cattle with a diet supplemented with powdered rock phosphate (RP) and their successive uptake by mung bean plants was assessed in alkaline soil. The efficacy of composted RP fed dung alone or/and in combination with AMF inoculums containing six different species were compared with SSP in six replicates per treatment in pots. The results showed that the association of AMF with composted RP fed dung had a positive effect on mung bean shoot (3.04?g) and root (2.62?g) biomass, chlorophyll (a, b), carotenoid contents and N (58.38?mg plant^?1) and P (4.61?mg plant^?1) uptake. Similarly, the percent roots colonization (56%) and nodulation of mung bean plant roots and their post-harvest soil properties were also improved by the inoculation of AMF together with composted RP fed dung. It is concluded that the combined application of AMF with composted RP fed dung has almost the same effect as SSP for improving mung bean plants growth and their nutrients uptake. Moreover, AMF inoculants can be used as a suitable biofertilizer in combination with locally available organic sources of fertilizers for improving P status and growth of plants in alkaline soils.