Distribution of Aluminum Fractionation in the Acidic Rhizosphere Soils of Masson Pine (Pinus massoniana Lamb)

The modified Tessier’s sequential extraction procedure and rhizobox cultivation were employed to investigate the distribution of aluminum (Al) fractions in the acidic rhizosphere soil of Masson pine (Pinus massoniana lamb) seedlings. The results showed that the Al in soils was fractionated into five operationally defined fractions. Three sets of soil samples used in the rhizoboxes were collected from the three forest sites in the southeast of China: Sichuan, Zhejian, and Jiangsu. At the end of 100-day cultivation, the rhizosphere Al fractions for the original or bulk soils were in the order of residual > iron-manganese (Fe-Mn) oxides > organic > carbonate > exchangeable. However, in rhizosphere soil, the Al fraction follows the order of residual > organic > Fe-Mn oxides > carbonate > exchangeable. On average, the rhizosphere experienced significant increase in organically bound Al and slight decrease in exchangeable Al contents, but had decreases in contents for the other three Al fractions compared to the nonrhizosphere. The correlation analysis indicated that the Al contents accumulated in roots were significantly and positively correlated with exchangeable Al contents in the rhizosphere, and also characterized by the major portion of organically bound Al, which exhibited a bioavailable transformation of Al fractions. Results indicated that decreases in both redox potential and soil pH, as well as increase in dissolved organic carbon (DOC), were observed in the rhizosphere. Exchangeable Al and organic Al fractions were dependent mainly on soil pH (hydrogen ion concentration) and DOC, accordingly. Decreasing rhizosphere pH from 5.93 to 3.42 accelerated the secretion of organic carbon. These data are helpful for understanding the mobility and bioavailability of Al fractions in the acidic rhizosphere soils of Masson pine.     

Potassium Fixation and Release Characteristics in Rhizosphere and Nonrhizosphere Soils for a Rapeseed–Rice Cropping Sequence

Potassium (K) fixation and release in soil are important factors in the long-term sustainability of a cropping system. Changes in K concentration and characteristics of K fixation and release in rhizosphere and nonrhizosphere soils in the rapeseed (Brassica napus L.)–rice (Oryza sativa L.) rotation were investigated using a rhizobox system. The concentrations of different forms of K in both rhizosphere and nonrhizosphere soils decreased with plants compared to without plants, regardless of K fertilizer application. Potassium uptake by crops mainly came from the rhizosphere soil. In the treatment without K fertilizer (–K), the main form of K supplied by the soil to the crops was 1.0 mol L^?1 nitric acid (HNO₃) nonextractable K, followed by nonexchangeable K, and then exchangeable K. In the treatment with K fertilizer (+K), the main K forms supplied by the soil to the crops were exchangeable K and nonexchangeable K. The amount and rate of K fixation after one cycle of the rapeseed–rice rotation was greater in rhizosphere soil than in nonrhizosphere soil. The amount and rate of K fixation of soil in the +K treatment were significantly less than in the –K treatment. The cumulative amounts of K released with 1.0 mol L^?1 ammonium acetate (NH₄OAc) and 1.0 mol L^?1 HNO₃ extraction increased with the increasing numbers of extractions, but the K-releasing power of soil by successive extraction decreased gradually and finally became almost constant. The release of K was less in rhizosphere soil than in nonrhizosphere soil. The release of K in the +K treatment was similar to that in the –K treatment in rhizosphere soil, but the K release in nonrhizosphere soil was greater with the +K than the –K treatment. Overall, the information obtained in this study will be helpful in formulating more precise K fertilizer recommendations for certain soils.     

Transformation and Bioavailability of Selenate and Selenite Added to a Nicotiana tabacum L. Planting Soil

Selenium (Se) is an essential nutrient for humans and is beneficial for plant growth. To investigate the transformation and bioavailability of Se in tobacco planting soil, selenite and selenate were applied. A pot experiment and sequential extraction scheme were used to investigate the Se contents in different forms in soils treated with Se. A series of equations were applied to model the transformation behavior of Se in this study. The results showed that the forms of selenium were increased significantly by applying the different valence state of water-soluble selenium. The carbonate-bound and iron-manganese (Fe-Mn) oxide–bound species were improved in selenite-added soil, whereas the soluble and exchangeable forms were increased in selenate-added soil. Michaelis-Menten equation fitting results indicated that estimated maximal selenium contents of leaves, stems, and roots in selenate-added soils were 1.83, 15.81, and 20.98 times larger than in selenite-added soils. The utilization levels of selenate were 4.3 to 7.9 times larger than selenite for Nicotiana tabacum L. In conclusion, the bioavailability and mobility of selenate were greater than selenite in Nicotiana tabacum L. planting soil.     

根际环境中镉的形态转化

用根际箱或根际根际袋试验研究了红壤,黄棕壤植稻或植麦后根际中镉的形态转化状况,并讨论了与铅复合处理对镉形态的影响。结果表明,红壤根际,非根际镉的主要形态为可交换态,黄棕壤则主要为碳酸盐结合态。水稻根际富集铁锰氧化物结合态镉,根际有机结合太镉远远大于非根际。对铅,镉复合污染的研究表明。     

基于通径分析的土壤性质与硒形态的关系——以黑龙江省主要类型土壤为例

黑龙江省是缺硒(Se)比较严重的省份之一,位于全国低Se带的始端。本文选择黑龙江省不同类型土壤,采用连续浸提法测定了土壤中Se的形态,并运用通径分析法研究了土壤理化性质对土壤Se形态、全Se的影响。结果表明:总Se含量在不同类型土壤中差异较大,整体上处于中等偏低水平;各结合态Se中以有机态和残渣态为主,分别占8.16%~50.5%和26.32%~70.90%,酸溶态占0.80%~33.97%,而水溶态与交换态仅占0.70%~7.18%和0.75%~9.37%。通径分析显示,土壤理化性质通过直接和间接作用共同影响着土壤各赋存形态Se的含量和分解转化方向,但其各自的作用机理和影响强度不同。在土壤各性质中,土壤有效铁、锰和黏粒以及它们间的共同作用决定了土壤Se形态分布,其中,土壤有效铁对于除残渣态Se之外的4种形态Se的生成转化起到了主导作用,而土壤有机碳、pH等其他性质主要通过正或负的间接作用影响Se形态。土壤总Se方面,土壤有效铁、锰及黏粒含量对总Se有较强的富集作用,但土壤有机碳和pH等因素间的相互作用也不可忽略。     

Change of Zinc Forms in Rhizosphere and Nonrhizosphere Soils of Maize (Zea mays L.) Plants as Influenced by Soil Drought Condition

A rhizobox experiment was conducted to study the changes of various zinc (Zn) forms in rhizosphere and nonrhizosphere soils of maize (Zea mays L.) plants grown under well-watered and drought conditions. The tested soil was earth-cumulic orthic anthrosol sampled from the Shaanxi Province of China. The experiment was set at two levels of Zn, 0 and 5.0 mg Zn kg^?1 soil, and at two treatments of soil water content, 45%–50% (drought) and 70%–75% (well watered) of soil water-holding capacity. A completely randomized factorial design (2 Zn treatments × 2 water levels × 3 replicates) was set up. Adequate soil water supply enhanced growth and Zn accumulation of maize plants. Applying Zn increased plant biomass and Zn content more notably under well-watered conditions rather than drought conditions. Soil Zn was defined as water-soluble plus exchangeable (WSEXC) Zn, carbonate-bound Zn (CA), iron–manganese oxide–bound Zn (FeMnOX), organic matter–bound Zn (OM), and residual Zn (RES) forms using the sequential extraction procedure. Most of Zn was predominantly in the RES fraction. Zinc application increased the contents of WSEXC Zn, CA Zn, and FeMnOX Zn in soil. When Zn was added to the soil, the concentrations of CA Zn within 0–2 mm and 0–4 mm apart from the central root compartment (CC) were greater than other zones under the conditions of adequate and limited soil water supplies, respectively. Zinc application also resulted in an accumulation of FeMnOX fractions at a distance of 2 mm from CC. The FeMnOX Zn content in this compartment increased with soil drought. Under well-watered conditions, dry-matter weight and Zn concentration of shoots presented better correlations with CA Zn and FeMnOX Zn fractions in and near the rhizosphere as compared with drought conditions. It is suggested that in an earth-cumulic orthic anthrosol, soil moisture conditions affect the transformation of the added Zn into the CA and FeMnOX fractions near the rhizosphere and their bioavailability to maize plants.     

Interrelationship of Organic Acids and Aluminum Concentrations in Rhizosphere and Nonrhizosphere Soil Solution of Rice in Acidic Soil

To study the interrelationship of organic acids and aluminum concentrations in rhizosphere and nonrhizosphere soil solution of rice (var. Satabdi and IR 64) in acidic soil, plants were grown in plastic pots containing 500 g soil. Three organic acids (viz., tartaric, oxalic, and citric acids) were identified and quantified in rice rhizosphere and nonrhizosphere soils. Organic acids were found more in the rhizosphere soil and at early stages of crop growth, decreased sharply after 30 days of germination, and found in negligible quantity after 45 days of germination. Regression analysis revealed a significant and negative relationship between solution aluminum and organic acid. Satabdi showed greater organic acid concentration in rhizosphere soil, leading to significantly lower root and shoot aluminum concentrations and consequently significantly greater dry-matter production as well as root volume, compared to IR 64. The findings established that organic acids can effectively reduce aluminum concentration in soil solution.     

两个水稻品种富硒特性比较研究

以前期田间试验筛选出的富硒能力较强的水稻品种捷丰优629和谷丰优8312为材料,采集硒含量不同的稻田土壤,通过盆栽试验进一步研究了两个水稻品种对土壤硒的吸收、分配及其糙米和精米中无机硒与有机硒含量的组成特点。结果表明:两个水稻品种植株的硒累积量、糙米和精米的硒含量与有机硒含量都是高硒土壤极显著高于低硒土壤,表明高硒土壤有利于稻米硒的累积与有机硒的合成,因此生产优质富硒大米最好选择硒含量较高的稻田土壤。无论在高硒土壤还是低硒土壤上,捷丰优629植株中硒累积量和籽粒中硒累积量与谷丰优8312的差异都不显著,但捷丰优629的糙米和精米中硒含量以及有机硒含量都极显著高于谷丰优8312,表明捷丰优629吸收的硒易分配到可食用部位(糙米和精米),而且其无机硒向有机硒的转化能力较强,因此综合比较来看捷丰优629富硒特性优于谷丰优8312。     

浔郁平原不同作物的硒富集特征及其影响因素

作物中的硒含量是影响食物链硒水平的关键因素。以浔郁平原土地质量地球化学评价项目中的农作物调查结果和多年定位试验结果为基础,探究不同作物对土壤硒的富集特征及其影响因素。结果表明:浔郁平原的覃塘、港南、桂平市和平南县等4个县(市、区)的水稻富硒率均高于86%。花生、黄豆、玉米和水稻的天然富硒率最高,富硒率依次为100%、100%、100%和89%。水稻根、茎、籽粒的生物富集系数依次下降,分别为0.663、0.130和0.108,水稻籽粒的生物富集系数远高于龙眼、荔枝和甘蔗。根系土与水稻籽粒硒含量的相关系数为0.660,远高于龙眼和荔枝。港南区作物硒与土壤pH相关系数为0.342,在碱性土壤中甘蔗茎的硒含量(0.012 1 mg/kg)最高,在酸性土壤中水稻的硒含量(0.0653mg/kg)最高。本研究中,以种子为可食部分的作物其天然富硒率较高,土壤硒含量和土壤酸碱性对水稻籽粒硒含量影响较大。     

基于路径分析的土壤性质与硒形态的关系

选择我国15种不同类型土壤,采用连续浸提法测定了土壤中硒的形态,并以Amos18.0路径分析法研究了土壤理化性质对土壤硒形态的影响。结果表明,除江西红壤(水田和旱田)和黑龙江黑土中硒主要是以残渣态存在外,其余土壤中硒主要以有机结合态为主,可溶态硒仅占土壤硒总量的0.4%～14.6%。土壤可交换态及碳酸盐结合态、有机结合态和残渣态硒含量间呈显著正相关(p<0.01),而可溶态和铁锰氧化物结合态硒含量与其他形态硒含量间无显著相关。路径分析表明,土壤有机质含量对铁锰氧化物结合态硒有负影响作用,而对其他四形态硒均为正影响作用。无定形铁含量对可溶态硒含量无影响作用,但对其他四形态硒的正影响作用大于有机质含量的。除可溶态硒外,土壤有机质和无定形铁含量分别对有机结合态和铁锰氧化物结合态硒的影响最大。pH和黏粒分别通过对土壤有机质和无定形铁的负和正作用而影响硒形态。有机质和无定形铁对硒在土壤中的分配起直接决定作用,而pH和黏粒也是不可忽略的影响因素。     

水稻根际中铁的形态转化

本文以熟化红壤性水稻土、淀浆白土、红壤和赤红壤为样品,研究了植稻后根际中铁的形态转化.结果表明,两种水稻土根际中无定形氧化铁、游离氧化铁、络合态铁、土壤中氧化铁的活化度及两种红壤上根际中的络合态铁均低于非根际土;而两种红壤上其余各项在根际内外分布趋势均与水稻土相反.用穆斯堡尔谱仪分析表明,所有根际土与非根际土相比,四极矩分裂增大,内磁场下降,说明根际中氧化铁被活化.同时,水稻土上根际中Fe²⁺增多,赤红壤中根际出现新矿物磁赤铁矿.根际中铁被活化,可能会影响根际中重金属等污染物的吸附和解吸特性、植物的铁素营养及对其它养分的吸收.     

Mitrification-Denitrification Loss of Added Nitrogen in Flooded RiceRhizosphere

Nitrification-denitrification losses of 15N-labelled nitrate and ammonium applied to the rhizos phere and nonrhizosphere of flooded rice were evaluated in 2 greenhouse rhizobox experiments.The loss of added N via denitrification was estimated directly by measuring the total fluxes of (N2O N2)12N,It was found that 67% and 51%-56% of 15N-nitrate added to rice rhizosphere were lost as (N2O N2)-15N in the 2 experiments,respectively,which were comparable to that added to norhizosphere soil(70%and 47%,respectively),implying that the denitrifying activity in rice rhizosphere was as high as that in nonrhizosphere soil.However,only trace amounts (0-0\3% of added N)were recovered as (N2O N2)-15N when 15N-ammonium was applied to either rhizosphere or nonrhizosphere,which seems to indicate that the nitrifying activity in the either rhizosphere of nonrhizosphere soils was quite low.The apparent denitrification calculated from 15N balance studies was 10%-47% higher than the total flux of (N2O N2)-15N.Reasons for the large differences can not be explained satisfactorily.Though the denitrifying activity in rhizosphere was high and comparable to that in nonrhizosphere soil.presumably due to the low nitrifying activity and /or the strong competition of N uptake against denitrification.the nitrification-denitrification taking place in rhizosphere could not be an important mechanism of loss of ammonium N in flooded rice-soil system.     

田间旱育条件下不同化感潜力水稻根际土壤酚酸类和萜类物质分析

酚酸类和萜类是水稻化感作用研究中研究较多、争议较大的2大类化感物质,但目前有关水稻根系分泌物的研究多在实验室条件下进行。本文以国际公认的强化感水稻‘PI312777’和弱化感水稻‘Lemont’为材料,以未种植水稻的土壤为对照,研究了其在田间旱育条件下,不同土壤水分状态(旱地和湿地)时,根际土壤酚酸类和萜类物质的差异。结果表明,不同水分条件下不同化感潜力水稻品种和对照根际土壤中酚酸类物质和萜类物质的组成较为相似,但各物质含量存在一定差异。适度旱胁迫下,各处理根际土壤中所检测到的咖啡酸、对羟基苯甲酸、香草酸、阿魏酸和肉桂酸5种酚酸类物质及总量均有提高,其中强化感水稻‘PI312777’根际土壤中5种酚酸类物质提高最显著,比CK湿地处理提高2.84倍;在各处理根际土壤共检测到的27种萜类物质中,17种是含氧单萜;干旱胁迫导致各处理根际土壤单萜烯、含氧单萜、含氧倍半萜和总萜变化程度和变化趋势不同,单萜烯相对含量在强化感水稻‘PI312777’根际土壤中明显提高,而在弱化感水稻‘Lemont’和对照根际土壤中则降低。本文在此基础上讨论了由此导致2种水稻田间化感抑草效果差异的原因与机制。     

湘中紫色丘陵区不同植被类型根际与非根际土壤理化特征

[目的]探索湘中紫色丘陵区不同植被类型根际与非根际土壤的理化特征,为湘中地区生态修复提供理论依据。[方法]以典型抽样方法调查湘中丘陵区草丛(G)、草灌(GS)、灌木(S)和乔灌(AS)4种典型植被,研究其根际与非根际土壤理化性质的差异,通过典型相关分析揭示根际与非根际土壤理化指标间的耦合关系。[结果]研究区草丛和灌木根际土壤中细砂粒(0.25~0.05mm)含量分别显著(p0.05)低于乔灌63.84%和76.97%;粉粒(0.02~0.002mm)含量表现为草和灌木分别显著高于乔灌的38.48%和37.66%。根际土壤0.25~0.05mm微团聚体含量均表现为乔灌高于其他植被,0.02~0.002mm微团聚体含量均表现为灌木高于其他植被。草灌与灌木非根际土壤有机质含量显著(p0.05)低于根际土壤148.05%和121.92%,灌木和草灌根际土壤有机质含量显著(p0.05)高于乔灌土壤84.28%和92.08%;草灌根际土壤全氮含量显著(p0.05)高于非根际土壤83.33%,草灌根际土壤碱解氮含量显著(p0.05)高于乔灌土壤200.83%;不同植被类型根际/非根际土壤磷含量差异不明显,总体来看,同一植被根际土壤全磷含量低于非根际土壤,而有效磷表现为乔灌最低;乔灌根际土壤速效钾含量分别显著(p0.05)低于草丛和草灌土壤125.15%和137.71%,除草灌外,其余植被类型根际土壤全钾含量均低于非根际土壤。典范相关分析表明土壤有机质和全量养分含量,2~1,1~0.5,0.25~0.05mm土粒含量,2~1,1~0.5mm团聚体3组理化性状间相互关系密切。[结论]改善土壤理化性质,促进湘中丘陵地区生态恢复,应注重协调土壤养分、颗粒组成及团聚体之间的耦合关系。     

Interaction of silicon,iron, and manganese in rice (oryza sativa L.) rhizosphere at low ph in relation to rice growth

Rice (Oryza Sativa L.) nutrition is influenced by the interactions of (Iron) Fe, (Manganese) Mn, and (Silicon) Si in the rhizosphere. A greenhouse experiment was carried out with rice grown in four low‐pH soils (a granitic lateritic red earth, a paddy soil from the red earth, a basaltic latosol, and a paddy soil from the latosol). Rice was grown in pots with the roots confined in rhizobags and the rhizosphere soil and nonrhizosphere soil were analyzed separately for active Si, Fe, and Mn by Tamm's solution. Silicon and Mn concentrations were lower in the rhizosphere soil indicating a depletion which was higher for the basaltic soils and for the paddy soils. Iron concentrations were higher in the rhizosphere soil indicating an accumulation that was higher for granitic soils and for the upland soils. Plant growth response was due mostly to Mn with the basaltic soils supplying toxic amounts and the granitic soils being deficient. Iron accumulation in the rhizosphere caused lower plant uptake of Si, phosphorus (P), and calcium (Ca) and higher Fe and aluminum (Al) absorption leading to the conclusion that Fe deposition on plant roots and in rhizosphere may block the uptake of other nutrients.     

旱改水对水稻幼苗生长的影响及秸秆的改良作用

本研究以江汉平原旱改水为研究背景,采用土壤盆栽试验和室内淹水培养相结合的方法,以多年水稻土为对照,研究了多年棉田土旱改水及添加秸秆(9 g·kg-1)对水稻幼苗生长和矿质元素吸收的影响以及土壤氧化还原电位和有效态铁、锰、铜、锌含量变化,为旱改水水稻的种植提供参考。结果表明,棉田土旱改水后,水稻幼苗生长缓慢并出现失绿黄化症状,其地上部干重和叶绿素含量仅分别约为水稻土处理的30%和20%。旱改水处理水稻植株Fe含量显著低于、而Cu和Zn含量则显著高于水稻土处理。棉田土旱改水土壤氧化还原电位(Eh)显著高于水稻土;淹水处理10 d,土壤DTPA-Fe含量仅为水稻土的7%左右,而DTPA-Cu和DTPA-Zn含量则分别是水稻土的1.4~2.5倍和1.6~1.8倍。随着淹水时间的延长,棉田土旱改水土壤有效态铁含量逐渐增加,有效态锰、铜和锌含量呈先升高后降低趋势;到淹水处理的第28 d,棉田土旱改水土壤有效态铁、锰、铜和锌含量与水稻土之间的差异逐渐缩小。Fe不足及Cu过量可能是导致旱改水水稻幼苗生长缓慢、失绿黄化的主要原因。旱改水条件下添加秸秆可以降低土壤的Eh值,提高土壤DTPA-Fe含量及降低土壤DTPA-Cu和DTPA-Zn含量,显著提高旱改水初期水稻幼苗叶绿素含量,但对水稻生物量无显著影响。添加秸秆并不能完全消除旱改水对水稻幼苗生长的抑制作用。     

红壤区不同肥力水稻土根际硝化作用特征

通过根际培养箱(三室)——速冻切片技术研究了红壤地区高、低两种肥力下水稻苗期根表、根际和土体土壤矿质态氮含量和硝化强度,以及水稻生长、氮素积累的差异。结果表明,肥力水平对水稻根表和根际土壤铵态氮(NH4+-N)含量无显著影响,但高肥力显著提高土体土壤NH4+-N含量,以及根表、根际和土体土壤硝态氮(NO3--N)含量及硝化强度。两种肥力水稻土硝化强度最大值均出现在距根表2 mm处,分别为0.20和0.31μmol kg-1 h-1。土体土壤硝化强度随距根表距离增加而降低,低肥力土壤在距根表10～40mm处时硝化强度接近本底值,而高肥力土壤在距根表20～40 mm处时接近本底值。与不种水稻的CK相比,种植水稻显著提高根际土壤硝化强度。高肥力能显著改善水稻生长,增加植株氮素积累量,尤其显著促进根系生长及通气组织发育。由于红壤稻田肥力水平的差异造成水稻根际硝化强度以及水稻吸收NO3-的差异,导致高肥条件下水稻显示出更强的生长势和氮素吸收利用能力。因此,合理提高红壤稻田肥力水平对改善红壤区水稻根际土壤硝化作用及水稻氮素营养具有重要意义。     

Rhodanese activity of flooded and nonflooded soils

Rhodanese activity (RA) was studied in 4 soils, incubated under flooded and nonflooded (60% water-holding capacity) conditions. RA in 3 soils including an acid sulphate soil pokkali increased 2.5–6.0-fold (over respective nonflooded soils), while activity of the enzyme decreased markedly in flooded alluvial soil. Similarly, anaerobic incubation of nonflooded soils under N₂ decreased RA in an alluvial soil, but increased it in pokkali soil. RA was negligible in soils, that had been reduced by flooding for 30 days and then sterilized by autoclaving. Rice rhizosphere soil exhibited significantly higher RA than the nonrhizosphere soil samples under flooded or nonflooded conditions. RA in aerobic soils was related to the microbial oxidation of S° to SO^2?₄. But, no relationship could be established between RA and S-oxidation in flooded soils and in rhizosphere soil suspensions of flooded rice plants.     

氨基酸增值尿素对水稻苗期生长及根际微生物菌群的影响

[目的]研究氨基酸增值尿素(AU)对不同稻作水稻生长、根际养分与微生物群落的影响机制,以期为水稻早期水氮合理调控及氨基酸增值尿素合理施用提供依据.[方法]以'两优华6'水稻和氨基酸增值尿素(AU)为试材,开展了水作/旱作盆栽试验.试验共设旱作不施尿素(GCK)、旱作施普通尿素(GU)、旱作施氨基酸增值尿素(GAU)、水...     

水网地区水稻土的含硒量及根外施硒对糙米硒含量的影响

本文通过对嘉善县平原水稻土硒含量特征和该区水稻硒含量之间关系的调查研究表明：（１）嘉善县平原水稻土,水溶态硒含量低于一般水稻土水溶态硒的临界值（０．０１０μｇ／ｇ）,这与该区的土壤母质、地形等因素相关;（２）低硒水稻土了水稻对硒的吸收积累,因此该县出产的稻米硒含量亦普遍较低,平均含硒量低于粮食硒的正常含量范围（０．０４０～０．０７０μｇ／ｇ）;（３）水稻地上各部分含硒量存在差异,糠、秸杆中的含硒量