Alfalfa Responses to Combined Use of Lime and Limiting Nutrients on an Acidic Soil

An on-farm field experiment was conducted on an acidic soil to investigate the effects of combined use of lime and deficient nutrients on herbage yield of alfalfa (Medicago sativa L.). Omitting lime and limiting nutrients led to elevated concentrations of aluminium (Al), iron (Fe), and manganese (Mn) in alfalfa leaves and stems and caused severe reductions in herbage yield of alfalfa. Combined use of lime (2 t ha^?1) and nutrients [phosphorus (P): 20 kg ha^?1, sulfur (S): 20 kg ha^?1, zinc (Zn): 4 kg ha^?1, and boron (B): 2 kg ha^?1] had the maximum increase in groundcover, root biomass, nodulation, leaf retention, leaf-to-stem ratio, herbage yield, crude protein, and nutrient composition of alfalfa. These beneficial effects were due to raised soil pH; improved calcium (Ca), P, S, Zn, and B nutrition; and reduced Al, Mn, and Fe toxicity. Aluminium and all the nutrients except copper (Cu) were more concentrated in alfalfa leaves than stems.

Aluminum concentration was about three times greater in the lower leaves than in upper leaves. Lower leaves also had much greater concentrations of Ca, Mg, K, S, Fe, Mn, Cu, and B compared with upper leaves. In contrast, P and Zn concentrations were greater in the upper leaves than in lower leaves. Results suggest that the combined use of lime and all the limiting nutrients may realize potential beneficial effects of alfalfa on acidic soils where more than one essential nutrient is deficient. This may increase growth potential, nitrogen contributions, and groundcover by alfalfa and reduce soil erosion and runoff.     

Related Characteristics and Multivariate Analyses in the Evaluation of White Oat Aluminum Tolerance

Standard white oat genotypes were subjected to different methods and aluminum (Al) levels under hydroponic conditions to verify the relationship between plantlet characteristics and their Al tolerance using multivariate analyses. A completely randomized design with three replications was used, adopting three evaluation protocols: “complete nutrient solution” with 0, 8, 16, and 32 mg L^?1 of Al supplied as aluminum sulfate [Al₂(SO₄)₃·18H₂O]; “complete nutrient solution” with 0, 8, 16 and 32 mg L^?1 of Al supplied as aluminum chloride (Al₂Cl₃?6H₂O); and the “minimum nutrient solution” with 0, 1, 3, and 5 mg L^?1 of Al supplied as Al₂Cl₃?6H₂O. The performance of white oat plantlet genotypes subjected to excess Al in hydroponic conditions is greatly associated with root length, where the nutrient solution composition and the Al sources interfere in these associations. The study based on the joint analysis of characteristics at plantlet level does not allow an efficient discrimination of Al-tolerant and Al-sensitive white oat genotypes.     

The effect of soil pH manipulation on chemical properties of an agricultural soil from northern Idaho

Abstract

Selected chemical properties of an artificially acidified agricultural soil from northern Idaho were evaluated in a laboratory study. Elemental S and Ca(OH)₂were used to manipulate the soil pH of a Latahco silt loam (fine‐silty, mixed, frigid Argiaquic Xeric Argialboll), which had an initial pH of 5.7. A 100 day incubation period resulted in a soil pH manipulation range of 3.3 to 7.0. Chemical properties evaluated included: N mineralization rate, extractable P, AI, Mn, Ca, Mg and K and CEC. N mineralization rate (assessed by anaerobic incubation) decreased with decreasing soil pH. Nitrification rate also decreased as NH₄ ⁺‐N accumulated under acid soil conditions. Sodium acetate extractable P was positively linearly correlated (R²= 0.87) with soil pH over the entire pH range evaluated. Potassium chloride extractable Al was less than 1.3 mg kg^‐1of soil at pH values higher than 4.4. Consequently, potential Al toxicity problems in these soils are minimal. Extractable Mn increased with decreasing soil pH. Soil CEC, extractable Mg, and extractable K all decreased with increasing soil pH from 3.3 to 7.0. Extractable Ca levels were largely unaffected by changing soil pH. It is likely that the availability of N and P would be the most adversely affected parameters by soil acidification     

碳纤维复合芯导线的性能与应用研究

阐述碳纤维复合芯导线（ACCC）的基本结构,将ACCC与传统钢芯铝绞线（ACSR）在结构、材料性能、弧垂-温升曲线、安装曲线方面进行对比。结果表明,ACCC铝线截面积、最高工作温度、载流量均高于ACSR,在工程中应用ACCC可有效提高线路的送电能力。     

外源有机酸对铝毒胁迫下大豆根系形态的影响

通过添加三种不同浓度的有机酸(柠檬酸、草酸和苹果酸) ,测定铝毒胁迫下大豆的根系活力及主要根系 性状,研究了三种外源有机酸对大豆铝毒害的缓解效应。实验结果显示,三种有机酸在适当低浓度条件下,对大豆 铝毒害都有一定的缓解效果,其中以柠檬酸的缓解效果最好,草酸和苹果酸的缓解效果相当;但当有机酸浓度较高 时,反而会使大豆根系活力降低,根伸长受到抑制;有机酸对浙春2号的缓解作用强于浙春3号, 15d处理的缓解效 果优于30d。     

外源低分子量有机酸对碳酸钙预处理的酸性土壤中活性铝钙镁影响的研究

通过在所研究的第四纪红黏土发育的红壤中混入CaCO3,研究在pH缓冲体系中外加低分子量有机酸对土壤中Al、Ca和Mg的影响。结果表明:无论加CaCO3与否,在pH 4.5的条件下外源草酸、柠檬酸、苹果酸的加入均使土壤可溶性Al显著提高,交换性Al显著下降和交换性Ca显著升高;加入CaCO3的情况下,3种有机酸处理的交换性Mg均显著提高。3种有机酸促进Al溶解能力的大小顺序为:柠檬酸>草酸>苹果酸,这一结果与有机酸和Al形成络合物的稳定常数大小一致。另一方面,3种有机酸处理下,CaCO3预处理均引起可溶性Al的显著升高和交换性Al的下降。双因素方差分析表明,有机酸通过络合作用或沉淀作用对可溶性和交换性Al、Ca和Mg均具有绝对的影响优势,CaCO3仅对可溶性和交换性Al、交换性Ca有显著影响,由于实验中pH缓冲体系的控制,这种影响主要通过Al与Ca、Mg的竞争交换作用实现。总体来说,外源低分子量有机酸的加入使土壤活性Al显著升高,活性Ca、Mg略有升高,有机酸在酸性土壤中的作用需从有机酸溶解阳离子的角度进一步评价。     

胃舒平片剂中铝含量测定方法研究

研究了胃舒平片剂中铝含量的测定方法。样品消解后,先在pH值为7~8时,用稀NaOH溶液将Al3+沉淀为Al(OH)3,再加入KCl,反应中生成的游离KOH溶液,以酚酞为指示剂,用HCl标准溶液滴定至终点。加标回收率(R)在96.8%~100.1%,测定结果的相对标准偏差(RSD)<1.0%。结果表明,改进后的方法,操作方便、测定快捷,其准确度和精密度与标准法一致。     

Energy dispersive X‐ray fluorescence for rapid potassium,calcium, and chloride diagnosis in barley

Barley (Hordeum vulgare L. cv Doriru) leaf samples were collected from a field comprising three plots, plot F chemical fertilizer treated, plot S receiving sewage sludge and sawdust mixed compost, and plot H receiving sewage sludge and rice husk mixed compost. Relative concentrations of selected elements, potassium (K), calcium (Ca), and chloride (Cl) of young, mature, and old barley leaves were determined by microscopic energy dispersing X‐ray fluorescence (EDXRF). The objective of this investigation was to verify the applicability of EDXRF for rapid nutrient element diagnosis of plants. Typically whole leaves were washed in deionized‐distilled water and dried by ironing for analysis. Intact dried barley leaf sample irradiation was accomplished with X‐rays obtained from an X‐ray tube focused on an area <100 μm of the respective sample specimen surface. The EDXRF provided sufficient sensitivity for relative concentrations of K, Ca, and Cl. Element content data of all the elements investigated, specifically K, resulted in adequate plant nutrient element values to diagnose K insufficiency in barley leaves taken from plants in the sewage sludge receiving plots. Potassium was more densely accumulated in the new leaf than in mature and old leaves in case of plants from the S and H plots. In contrast, such K accumulation was more dense in old and mature leaves than young leaves in case of plants from the F plot. However, Cl and Ca coupling in barley leaves from all of the F, S, and H plots had shown the similar pattern of distribution and followed the order: old > mature > young. Therefore, EDXRF can be an easy, rapid, and practical method for diagnosing the elemental content of plant tissues and thereby help to aid plant growth and development through timely supplements of the required element(s).     

Diurnal patterns of nitrate assimilation in Kentucky bluegrass

Kentucky bluegrass (Poapratensis L.) is a major C₃‐type forage and turfgrass, but it is less efficient than many grasses in utilizing nitrogen(N). To determine how this grass can accommodate its greater N need, diurnal patterns of nitrate reductase activity (NRA) and nitrite reductase activity (NiRA) in its leaves and roots were examined and compared with those in barley (Hordeum vulgare L.). Plants were grown under greenhouse or growth room conditions and assayed for NRA and NiRA by optimized in vivo methods. The diurnal patterns of NRA and NiRA indicated that Kentucky bluegrass could assimilate nitrate during the night at rates greater than or similar to those during the day. Leaf NRA of Kentucky bluegrass was minimal approximately 4 and 10 h after illumination commenced and increased at night. The diurnal pattern of leaf NRA among Kentucky bluegrass cultivars did not differ significantly. In roots, NRA of Kentucky bluegrass was high in the morning and decreased sharply during the afternoon and evening, but increased again late at night. Unlike Kentucky bluegrass, barley exhibited greater leaf NRA during the day than during the night and exhibited the greatest activity 6 or 10 h after illumination commenced. In both species, the equilibrium leaf nitrate pool was 20 to 30 times larger than the ammonium pool and 3, 000 to 13, 000 times larger than the nitrite pool. Leaf nitrate pool size showed a diurnal pattern complementary to that of leaf NRA. Our results suggest that a nighttime N use strategy might exist in Kentucky bluegrass.     

Specific and non-specific adsorption of inorganic ions I. Evaluation of specific adsorbability by means of minimum concentration for specific adsorption

The Minimum Concentration for Specific Adsorption (MCSA) was defined as a reversal of the charge concentration of the ion at the infinite dilution of sol (adsorbent), or practically at such concentration of sol that equilibrium of the ion Is but negligibly affected by adsorption of the ion.

The MCSAs of 15 species of cations were measured with respect to SiO₂ at pH 4,6,5, and 10; the MCSAs of 10 species of anions were measured with respect to Fe(OH)₃ at pH 4, and 6.5; and the MCSAs of 10 species of anions were measured with respect to Al-coated-SiO₂ at pH 6.5. Relative specificities of the inorganic ions based on the MCSAs at pH 6.5 were as follows:

The MCSAs of cations with respect to SiO₂ and of anions to Fe(OH)₃ and Al-coated-SiO₂ at pH 6.5 had close relationships to ionic potentials and general solubility of the elements in water. Based on these results, the authors concluded that the MCSA could be used u an index of specificity (i.e. covalent bond-forming tendency) of an Jon at adsorption reactions.

The values corresponding to the apparent stability constants of surface complexes formed by adsorption reaction with SiO₂ and cations at pH 4 were calculated from the values of the MCSAs.