旱改水对砂姜黑土中锌含量的影响研究

本文用连续分级浸提法,研究了旱改水对砂姜黑土中锌的含量、赋存形态和有效性的影响。砂姜黑土中的锌绝大部分以残留态存在,晶态铁结合态约占１０％,其余形态锌一般小于＃％。这些形态锌可以分为三类;一类为土壤锌的强度因子,即代换态锌,另一类是土壤锌的容量因子,即有机态、无定形铁结合态的晶形铁结合态锌;第三类为残留态 有效态锌主要来自代换态。旱改水后,晶形铁结合态锌向有机态和无定形铁结合态锌转化,使得土壤中锌     

铜锌镍锰赋存形态的土体变化特征研究

本文用逐步连续分级法研究了砂姜黑土中铜锌镍锰的化学形态在土壤剖面中的变化特征以及耕作措施等对其的影响力。结果表明，砂姜黑土中代换态、有机态和无定形铁结合态铜锌镍锰的相对含量随剖面深度增加而降低；氧化锰态和残留态则随剖面加深而提高；碳酸盐结合态因元素种类和耕种方式而异，抑或增加抑或降低；晶形氧化铁态可以分成两类，铜镍变化不很明显，锌锰随剖面深度增加而增加。早耕熟化尤其是水旱轮作后，土壤中铜锌镍锰由植物无效的残留态或者有效性较低的晶形铁态（锌和锰）向有效性较高的代换态、有机态和无定形铁态转化，从而提高了土壤中铜锌镍锰的可移动性和有效性.     

铜锌镍锰赋存形态的土体变化特征研究

本文用逐步连续分级法研究了砂姜黑土中铜锌镍锰的化学形态在土壤剖面中的变化特征以及耕作措施等对其的影响力，结果表明，砂姜黑土中换态，有机态和无定形铁结合态铜锌镍锰的相对含量随剖面深度增加而降低，氧化锰态和残留态则随剖面加深而提高；碳酸盐结合态因元素种类的耕种方式而异，抑或增加抑或降低；晶形氧化铁态可以分类两类，铜镍变化不很明显，锌锰随剖面深度增加而增加，旱耕熟化尤其是水旱轮作后，土壤中铜锌镍锰由植物     

旱改水对土壤铜含量及其有效性的影响研

旱改水对土壤Cu含量及其有效性的影响研究结果表明 ,代换态铜是土壤中Cu的强度因子 ,而晶形铁结合态铜和残留态铜为植物无效态铜且需经形态转化才有效 ,其他形态铜既是容量因子也是强度因子 ,其有效程度大致为无定形铁结合态铜 >有机结合态铜 >氧化锰结合态铜 >碳酸盐结合态铜。旱改水促进碳酸盐结合态铜、氧化锰结合态铜尤其是残留态铜向代换态铜、无定形铁结合态铜和有机态铜转化 ,提高土壤铜有效性和可移动性 ,并使Cu淋溶损失 ,导致水旱轮作土壤耕层全Cu贫化     

耕作改制对砂姜黑土微量元素的影响研究

研究旱作改水旱轮作对砂姜黑土中微量元素含量、有效性和赋存形态等的影响结果表明,砂姜黑土旱作改水旱轮作后,微量元素的总含量除Mo外,均呈贫化趋势且达显著水平;Cu、Fe、Mn和Mo的有效性明显提高,Zn的有效性降低,严重缺Zn可能限制作物产量提高;残留态、晶形铁态和碳酸盐态微量元素含量随旱作改水旱轮作时间的延续而降低,有机态和无定形铁态微量元素的含量则不断增加,代换态微量元素含量变化与有效态微量元素相似,呈两极分化,Cu和Ni增加,而Zn和Mn降低.     

耕作改制对砂姜黑土微量元素的影响

研究旱作改水旱轮作对砂姜黑土中微量元素含量、有效性和赋存形态等的影响结果表明,砂姜黑土旱作改水旱轮作后,微量元素的总含量除Ｍｏ外,均呈贫化趋且达显著水平;Ｃｕ、Ｆｅ、Ｍｎ和Ｍｏ的有效性明显提高,Ｚｎ的有效性降低,严重缺Ｚｎ可能限制作物产量提高,残留态、晶形铁态和碳酸盐态微量元素含量随旱作改水旱轮时间的延续而降低,有机态和无定形铁态微量元素的含量则不断增加,代换态微量元素含量变化与有效态微量元素相似     

湖南省主要茶园土壤锌的形态及其有效性

采用野外调查采样分析和田间试验方法研究了湖南省主要茶园生态系统中土壤Zn的形态及其有效性.结果显示:①成土母质明显影响土壤中各种形态Zn的含量,与母质本身的特性有关;②生物 秸秆和秸秆覆盖处理能明显提高茶园土中有效态Zn与有机态Zn的含量,而对其他形态Zn的含量影响不太明显;③土壤中对有效态Zn(AZn)含量影响最大的是交换态Zn(ExZn)与无定形氧化铁结合态Zn(AFeZn),其次为氧化锰结合态Zn(MnOZn)、有机态Zn(OMZn)及晶形氧化铁结合态Zn(CFeZn).     

有机肥与植物种类对铁肥形态转化及其有效性的影响

通过盆栽试验的方法，研究了牛粪和植物种类对石灰性土壤中铁肥形态转化及其有效性的影响。结果表明，牛粪施用改变了土壤中铁（含外源铁）的有效性及其在各形态铁间的分配，从长期的观点来看，牛粪施用能提高土壤铁的有效性，有利于土壤铁有效供给的维持，与花生相比，油菜对土壤铁具有更高的利用和活性能力，种植油菜后，土壤交换态铁被耗竭，而有效铁、氧化锰结合态铁和无定形氧化铁结合态铁的含量明显提高。有机肥的合理施用和铁效率差异性植物间的轮作或间作是增加、维系土壤铁有效性的重要农艺措施。     

几种土壤组分对原有土壤中锌的富集能力的研究

本文研究了我国部分自然土壤中氧化铁、氧化锰及有机质三种组分对原有土壤中锌的富集能力。并比较了不同土壤类型中各组分对锌的富集能力,探讨了土壤环境条件主要为pH对组分富集能力的影响。结果表明,土壤中这三种组分其单位含量对锌的富集能力为:氧化锰>氧化铁>有机质;三:种组分对锌的富集能力在土壤间的变化以氧化铁最为明显,其顺序为石灰性土壤>中性土壤>酸性土壤;土壤pH对土壤氧化铁富集锌能力的影响也很明显。氧化铁对锌的富集分配比例为:酸性土壤<5,中性土壤5—15,石灰性土壤≥15,各土壤组分对锌的富集容量次序为:氧化铁>有机质>氧化锰,氧化铁中,晶形铁>无定形铁。     

黄土高原旱地连续施用锰肥的土壤效应研究

采用连续浸提形态分级方法，研究了连续施用锰肥17a后锰的土壤化学特性变化。结果表明：经过长期连续施用锰肥，土壤全锰和DTPA—Mn含量增加不多。土壤DTPA—Mn含量随试验时间的延长呈增加趋势，施锰土壤有效锰提高不多，土壤DTPA—Mn含量只增加了0．4～1．7mgkg^-1。土壤中的锰主要以矿物态存在，占土壤全锰含量的比例为87．3％～91.8％。碳酸盐态、氧化锰态和紧结有机态锰占全锰的比例相当，土壤中各形态锰按含量大致呈矿物态〉碳酸盐态〉氧化锰态〉紧结有机态〉松结有机态〉交换态的顺序。施入土壤的锰肥有91．1％～98．6％进入碳酸盐结合态、氧化锰结合态、紧结有机态和矿物态，只有很少一部分仍留在有效态锰库中。交换态和松结有机态锰对土壤锰的有效性起着主要作用，可以反映土壤锰的供给状况，碳酸盐态和紧结有机态锰不能反映土壤锰的有效性。     

Inclusion of upland crops in rice‐based rotations affects chemical properties of clay soil

In the Mekong Delta, alluvial clay soils have been used intensively over many generations for rice monoculture. Currently, farmers are confronted by problems of declining land productivity. Rotations comprising rice and upland crops can increase soil quality, but appropriate cropping systems for paddy soils have received relatively little attention. We therefore established a multiyear field experiment to evaluate the long‐term effects of cropping systems with different rotations on soil chemical quality. Systems laid out in a randomized complete block design with four replications were as follows: (i) traditional rice monoculture with three rice crops per year (R‐R‐R), (ii) rotation with two rice crops and maize (R‐M‐R), (iii) rotation with two rice crops and mung bean (R‐Mb‐R) and (iv) rotation with one rice crop and two upland crops – mung bean and maize (R‐Mb‐M). We hypothesized that systems with rotations of upland crops and their temporary beds improve chemical quality of paddy rice soil. Soil chemical parameters were determined to better understand and evaluate the sustainability of the cropping systems. Results showed an improvement in soil chemical quality for cropping systems with rotations of rice and mung bean or maize grown on temporary beds (R‐M‐R, R‐Mb‐R and R‐Mb‐M), particularly the content of soil organic carbon and a presumed hydrolysable labile carbon fraction compared with rice monoculture. Less pronounced improvements in EC, CEC and total acidity were also found with inclusion of upland crops. Cropping systems of rice with upland crops improved rice grain and straw yield in subsequent season in contrast with rice monoculture.     

Effect of Cropping System on Physical Properties of Clay Soil Under Intensive Rice Cultivation

Cropping systems are thought to alter soil quality in paddy rice fields. This study was conducted to quantify the long‐term effects of continuous crop production under different cropping systems with different crop rotations on physical properties of alluvial clay soil in the Mekong Delta, Vietnam. Soil samples were collected from four treatments: (i) traditional intensive rice monoculture with three rice crops per year (R–R–R); (ii) rotation with two rice crops and maize (R–M–R); (iii) rotation with two rice crops and mung bean (R–Mb–R); and (iv) rotation with one rice and two upland crops, mung bean and maize (R–Mb–M). We hypothesized that cropping systems with rotations of upland crops and their temporary beds improve the physical quality of paddy rice soil; hence, they are better options towards sustainable agriculture. Results show an improvement of soil physical quality for systems with two rice crops and one upland crop (R–M–R and R–Mb–R) and those with one rice crop with two upland crops (R–Mb–M) compared with intensive rice monoculture (R–R–R). This was translated in decreased bulk density and soil strength, increased soil organic carbon and total porosity, and higher aggregate stability index, plant‐available water capacity, and Dexter's S index, especially at depths of 10–20 and 20–30 cm. The systems with different upland crops (maize or mung bean) showed similar high physical quality improvement. To maintain soil quality in future seasons, introducing a cropping system with at least one upland crop in rotation with rice is recommended. Copyright © 2014 John Wiley & Sons, Ltd.     

植稻年限对土壤铁锰氧化物的影响

以浙江不同耕作年限水田和旱地为研究对象,探讨了植稻年限对土壤铁锰氧化物的影响,并揭示了水稻土发育过程中铁锰氧化物的剖面运移规律和诊断意义。结果表明:①土壤剖面中,全Fe、游离Fe及全Mn的变异随着种稻时间的延长而增大。种植达到一定年限时,全Fe、全Mn以及游离Fe在土壤剖面下层出现淀积。在各种铁锰氧化物中,对水稻土最具诊断意义的是游离Fe和全Fe。②无定形Fe以及络合态Fe、Mn与有机质呈显著正相关。植稻年限对它们的影响是通过对有机质的影响达到的。     

Chemical Speciation of Heavy Metals in the Fractionated Rhizosphere Soils of Sunflower Cultivated in a Humic Andosol

Chemical speciation and bioaccumulation factor of iron (Fe), manganese (Mn), and zinc (Zn) were investigated in the fractionated rhizosphere soils and tissues of sunflower plants grown in a humic Andosol. The experiment was conducted for a period of 35 days in the greenhouse, and at harvest the soil system was differentiated into bulk, rhizosphere, and rhizoplane soils based on the collection of root-attaching soil aggregates. The chemical speciations of heavy metals in the soil samples were determined after extraction sequentially into fractions classified as exchangeable, carbonate bound, metal–organic complex bound, easily reducible metal oxide bound, hydrogen peroxide (H₂O₂)–extractable organically bound, amorphous mineral colloid bound, and crystalline Fe oxide bound. Iron and Zn were predominantly crystalline Fe oxide bound in the initial bulk soils whereas Mn was mainly organically bound. Heavy metals in the exchangeable form accumulated in the rhizosphere and rhizoplane soils, comprising <4% of the total content, suggesting their relatively low availability in humic Andosol. Concentrations of organically bound Fe and Mn in soils decreased with the proximity to roots, suggesting that organic fraction is the main source for plant uptake. Concentrations of Mn and Zn in the metal–organic complex also decreased, indicating a greater ability of sunflower to access Mn from more soil pools. Sunflower showed bioaccumulation factors for Zn, Fe, and Mn as large as 0.39, 0.05, and 0.04 respectively, defining the plant as a metal excluder species. This result suggests that access to multiple metal pools in soil is not necessarily a major factor that governs metal accumulation in the plant.     

Mycorrhizal (Rhizophagus Intraradices) Symbiosis and Fe and Zn Availability in Calcareous Soil

Greenhouse experiment was conducted to assess the iron (Fe) and zinc (Zn) fractionation patterns in soils of arbuscular mycorrhizal (AM) fungus-inoculated and uninoculated maize plants fertilized with varying levels of Fe and Zn. Soil samples were collected for Fe and Zn fractions and available Fe, Zn and phosphorus (P) contents besides organic and biomass carbon (BMC), soil enzymes and glomalin. Major portion of Fe and Zn fractionations was found to occur in the residual form. Mycorrhizal symbiosis increased the organically bound forms of Fe and Zn while reducing the crystalline oxide, residual Fe and Zn fractions, indicating the transformation of unavailable forms into available forms. Soil enzymes, viz. dehydrogenase and acid phosphatase activities in M+ soils, were significantly higher than M? soil consistently. Overall, the data suggest that mycorrhizal symbiosis enhanced the availability of Fe and Zn as a result of preferential fractionation and biochemical changes that may alleviate micronutrient deficiencies in calcareous soil.

Abbreviations: AM: arbuscular mycorrhiza; Fe: Iron; Zn: Zinc; P: Phosphorous; Amox-Zn: amorphous oxide bound zinc; Cryox-Zn: crystalline oxide bound zinc; DAS: days after sowing; DTPA: diethylene Triamine Penta Acetic Acid; MnO₂-Zn: manganese oxide bound zinc; OC-Zn: organically bound zinc; WSEX: water soluble plus exchangeable zinc; MnO₂ Fe: manganese oxide bound iron; OC-Fe: Organically bound iron; WSEX Fe: water soluble plus exchangeable iron.     

关于集约农作制下的土壤结构问题——Ⅰ.有机物料及其利用方式对土壤结构的影响

对稻草、紫云英有机物料不同用量和混施、单施或沤制后施用等不同施用方式对土壤结构的影响进行了四年模拟试验。四年培育期中的水分条件和其他物理条件均控制一致。测定表明,有机物料能明显改善土壤的结构性和孔隙性,降低原状土核的破裂系数。有机质、重组有机质、无定形氧化铁、氧化铁的活度与团聚体的稳定性呈正相关;而与原状土的破裂系数呈负相关。看来,无定形氧化铁的含量可以作为高产水稻土具有良好结构性的一个间接指标。施加有机物料的土壤,当脱水时其中大孔隙显著增多,这对粘质水稻土回旱种旱作十分有利。稻草直接施入土中的改土效果优于沤制后施入土中,且不亚于高用量稻草和紫云英混施的效果。可见,如绿肥施用量减少时,只要保持一定量的稻草回田,亦能改善土壤的结构。