Measurement and Interpretation of Salinity Tolerance in Four Perennial Grasses

Whilst the topic of soil salinity has received a substantive research effort over the years, the accurate measurement and interpretation of salinity tolerance data remain problematic. The tolerance of four perennial grass species (non-halophytes) to sodium chloride (NaCl) dominated salinity was determined in a free-flowing sand culture system. Although the salinity tolerance of non-halophytes is often represented by the threshold salinity model (bent-stick model), none of the species in the current study displayed any observable salinity threshold. Further, the observed yield decrease was not linear as suggested by the model. On re-examination of earlier datasets, we conclude that the threshold salinity model does not adequately describe the physiological processes limiting growth of non-halophytes in saline soils. Therefore, the use of the threshold salinity model is not recommended for non-halophytes, but rather, a model which more accurately reflects the physiological response observed in these saline soils, such as an exponential regression curve.     

Growth,Water Status,and Nutrient Accumulation of Seedlings of Tamarindus indica Linn. in Response to Soil Salinity

Greenhouse experiments in a completely randomized block design were conducted to assess the effect of soil salinity on emergence, growth, water status, proline content, and mineral accumulation of seedlings of Tamarindus indica Linn. (Caesalpiniaceae). Sodium chloride (NaCl) was added to the soil, and the salinity was maintained at 0.2, 3.9, 6.2, 8.1, 10.0, 11.9, and 13.9 dS m^?1. Salinity lowered water content and water potential of tissues, which resulted in an internal water deficit to plants. Consequently, seedling growth significantly decreased and proline content in tissues increased as salinity increased. There were no effective mechanisms to control net uptake of sodium (Na⁺) and its transport to shoot. Potassium (K) and calcium (Ca) contents in tissues significantly decreased, while nitrogen (N) content significantly increased as salinity increased. Changes in tissues and whole-plant accumulation patterns of other nutrients, as well as possible mechanisms for avoidance of Na⁺ toxicity in this species in response to salinity, are discussed.     

Silicon Ameliorates the Adverse Effects of Salinity on Turfgrass Growth and Development

An experiment was conducted to assess the effect of foliar application of potassium silicate on Cynodon dactylon [L.] Pers., Festuca arundinacea Schreb. and Lolium perenne L. With increased salinity level, chlorophyll content and relative water content (RWC) in these three turfgrasses were reduced significantly when compared with the untreated control. Supplementary silicon (Si) ameliorated the adverse effects of salinity on chlorophyll content. Silicon treatments decreased proline at all salinity levels. Moreover, addition of Si increased shoot length and shoot number in all turfgrasses. Sodium (Na) concentration was increased in both leaves and roots of turfgrasses at high salinity level; however, Si treatment significantly reduced Na concentration in all of them. Silicon increased Potassium concentration in shoots and roots (though not significantly) in most cases. It can be concluded that Si alleviated the adverse effects of salt stress in all turfgrasses.     

Growth,mineral composition,leaf chlorophyll and water relationships of two cherry varieties under NaCl-induced salinity stress

Abstract

Growth, mineral nutrition, leaf chlorophyll and water relationships were studied in cherry plants (cv. ‘Bigarreau Burlat’[BB] and ‘Tragana Edessis’[TE]) grafted on ‘Mazzard’ rootstock and grown in modified Hoagland solutions containing 0, 25 or 50 mmol L^?1 NaCl, over a period of 55 days. Elongation of the main shoot of the plants treated with 25 or 50 mmol L^?1 NaCl was significantly reduced by approximately 29–36%, irrespective of the cultivar. However, both NaCl treatments caused a greater reduction in the dry weight of leaves and scion's stems in BB than in TE plants. Therefore, BB was more sensitive to salinity stress than TE. The reduction of leaf chlorophyll concentration was significant only when BB and TE plants were grown under 50 mmol L^?1 NaCl. Osmotic adjustment permitted the maintenance of leaf turgor in TE plants and induced an increase in leaf turgor of BB plants treated with 25 or 50 mmol L^?1 NaCl compared with 0 mmol L^?1 NaCl. Concerning the nutrient composition of various plant parts, Na concentrations in all plant parts of both cultivars were generally much lower than those of Cl. For both cultivars, leaf Cl concentrations were much higher than the concentrations in stems and roots, especially in the treatments containing NaCl. Finally, the distribution of Na within BB and TE plants treated with NaCl was relatively uniform.     

Improved Nutrient Uptake Enhances Cotton Growth and Salinity Tolerance in Saline Media

Two experiments were conducted to determine if improved nutrient uptake increases salinity tolerance of cotton (Gossypium hirsutum L.). A transgenic cotton line (CMO3) with increased salt tolerance and its wild line (SM3) were grown in pots containing substrate (peat:vermiculite = 1:1, v/v) in the first experiment, while cotton (‘SCRC 28’) was cultured in hydroponics with a split-root system in the second experiment. Contents of essential nutrient elements and Na⁺ in plant tissues, leaf photosynthesis (Pn) and chlorophyll (Chl) concentration and plant biomass were determined after salinity [sodium chloride (NaCl)] treatment in both experiments. In the first experiment, salinity stress with 150 mM NaCl reduced plant biomass and photosynthesis (Pn) of both SM3 and CMO3 compared with their non-stressed controls, but the CMO3 suffered significantly lower reductions than SM3, suggesting an increased salinity tolerance of CMO3 relative to SM3. Total uptake and contents of main nutrient elements [nitrogen (N), phosphorus (P), potassium (K), calcium (Ca), magnesium (Mg), iron (Fe), manganese (Mn), copper (Cu), and zinc (Zn)] in CMO3 were higher than those in SM3. Also, less sodium (Na⁺) accumulation and lower extreme ratios of Na/N, Na/P, Na/K, Na/Ca, Na/Mg, Na/Fe, Na/Mn, Na/Cu, and Na/Zn were observed in CMO3 than in SM3. Increased salt tolerance in transgenic AhCMO cotton was probably attributed to its superior nutrient uptake compared with SM3. In the second experiment, the non-stressed root half fed with moderate level of nutrient solution and salt-stressed half fed with low level of nutrient solution (CMN/SLN) exhibited higher salinity tolerance than salt-stressed root half fed with moderate level of nutrient solution and non-stressed root half fed with low nutrient solution (CLN/SMN). Plants absorbed more nutrients but less Na⁺ under CMN/SLN than CLN/SMN. The overall results suggest that improved nutrient uptake played an important role in the enhanced salt tolerance of cotton.     

Silicon-Induced Growth and Yield Enhancement in Two Wheat Genotypes Differing in Salinity Tolerance

Silicon (Si) is known to alleviate a number of abiotic stresses in higher plants including salinity stress. Two independent experiments were conducted to evaluate the role of Si in alleviating salinity stress in two contrasting wheat (Triticum aestivum L.) genotypes, Auqab-2000' (salt sensitive) and SARC-3 (salt tolerant). In the first experiment, genotypes were grown in hydroponics with two levels of salinity (0 and 60 mM NaCl) with and without 2 mM Si in a completely randomized design with four replications. Salinity stress significantly (P < 0.01) decreased all of the growth parameters, increased sodium (Na⁺) concentration, and decreased potassium (K⁺) concentration in shoots of both genotypes grown in hydroponics. Silicon significantly improved growth of both genotypes. The increase in growth was more prominent under salt stress (75%) than under normal condition (15%). In the second experiment, both genotypes were grown in normal [electrical conductivity (EC) = 1.23 d Sm^–1] and natural saline field (EC = 11.92 d Sm^–1) conditions with three levels of Si (0, 75, and 150 g g^–1 Si) with three replications in a randomized complete block design. Silicon significantly (P < 0.05) decreased growth reduction in both genotypes caused by salinity stress. The grain yield under salt stress decreased from 62% to 33% and from 44% to 20% of the maximum potential in Auqab-2000 and SARC-3, respectively, when 150 g g^–1 Si was used. Auqab-2000 performed better in normal field conditions, but SARC-3 produced more straw and grain yield in saline field conditions. Addition of Si significantly (P < 0.05) improved K uptake and reduced Na⁺ uptake in both of wheat genotypes and increased the K⁺/Na⁺ ratio in shoot. Enhanced salinity tolerance and improved growth in wheat by Si application was attributed to decreased Na⁺ uptake, its restricted translocation toward shoots, and enhanced K⁺ uptake.     

Genetic variability for responses to short‐ and long‐term salt stress in vegetative sunflower plants

Sunflower (Helianthus annuus L.) has been rated as moderately salt‐resistant, and variability for salt resistance has been detected within this crop. However, variability in salt‐resistance mechanisms has not been assessed. Osmotic tolerance, the relation of salt resistance with whole‐plant Na⁺ and K⁺ distribution and tissue Na⁺ tolerance were investigated in several sunflower inbred lines. Plants were grown under controlled conditions, in pots with sand and perlite irrigated with salinized (NaCl, –0.65 MPa) nutrient solution. Osmotic tolerance was assessed from the initial effects of the salt treatment on plant elongation in eleven sunflower lines. Long‐term salinity responses were evaluated in four of those lines, by assessing whole‐plant growth. A principal components analysis (PCA) was run on relative‐to‐control growth data, and this information was used to establish a relative resistance ranking, which indicated lines HAR2 > HAR1 > HA64 > HAR5. Osmotic tolerance was observed in HA64 and HAR2. The lines showed different degrees of Na⁺ accumulation, it was very low in some of them, but relative salt resistance was not associated to this trait. Tissue Na⁺ tolerance was deduced by comparing the percentage of dead leaves as a function of leaf blade Na⁺ accumulation, and it was higher in HAR1 than in the rest. These results indicate that variability for salt‐resistance mechanisms exists in sunflower. Osmotic tolerance and tissue Na⁺ tolerance were detected in different lines, highlighting that such variability may be exploited for increasing salt resistance in this crop.     

Effect of Mixed-Salt Salinity on Growth and Ion Relations of a Barnyardgrass Species

ABSTRACT

Recent investigations of the plant genome have revealed a large degree of similarity among cereal crops (specifically within the family Triticeae) and other related grass species. Recognition of the close genetic relationship among the grasses indicates that more exotic species, such as weedy grasses, may be exploited by plant breeders to enhance biotic/abiotic stress tolerance in cereal crops. Echinochloa crus-galli (L.) ^{1 1} Mention of company names or products is for the benefit of the reader and does not imply endorsement, guarantee, or preferential treatment by the USDA or its agents. Beauv. (barnyardgrass), a wide-spread, persistent C₄ weed species of agricultural importance, is reported to tolerate high levels of salinity. Growth and ion relations were studied in barnyardgrass using mixed-salt salinity (with final electrical conductivities (ECi) of 3 (control), 7, 11, and 19 dS m^?1 in the irrigation water) to determine whether the mechanism(s) for its salt tolerance are similar to those previously reported for other cereal crops. Such a finding would indicate that barnyardgrass may possess valuable genetic traits. Ion accumulation and ion selectivity ratios in the various treatments were determined from oven-dried shoot tissue. Significant (P < 0.01) linear regressions were obtained between either fresh weight or plant height and ECi. The point of 50% reduction (C₅₀) in fresh weight was predicted to occur at about 13.9 dS m^?1; the C₅₀ value for plant height was at about 22.9 dS m^?1. Statistical analysis of calculated Gapon constants for potassium (K)/sodium (Na) indicated that ion selectivity was not affected until after 11 dS m^?1. Calcium (Ca)/Na selectivity was not significantly affected by salinity. We concluded that, similar to some cereal crops, barnyardgrass maintains growth under saline conditions by maintaining high K/Na ratios, possibly because of better membrane integrity due to high Ca selectivity.     

Calcium Sulfate Improves Salinity Tolerance in Rootstocks of Plum

ABSTRACT

Three vegetative rootstocks of plum (Prunus domestica), Marianna GF 8-1 (Prunus cerasifera × munsoniana), Myrobolan B (P. Cerasifera) and Pixy (P. Insititia) were grown in pots containing sand and irrigated with complete nutrient solution to investigate the effect of calcium sulfate supplied to the nutrient solution on plants grown under salt stress. Treatments were (1) control (C): nutrient solution alone; (2) S (salinity stress): 40 mM NaCl; (3) S+Ca1: 40 mM NaCl +2.5 mM calcium (Ca) and (4) S+Ca₂: 40 mM NaCl + 5 mM Ca. Calcium was supplied as CaSO₄. The plants grown under 40 mol L^?1 NaCl produced less dry matter and had lower chlorophyll content than those without NaCl. Supplementary CaSO₄ at both 2.5 and 5 mM concentrations ameliorated the negative effects of salinity on plant dry matter and chlorophyll content. Salt treatment impaired membrane permeability by increasing electrolyte leakage. The addition of calcium sulfate partially maintained membrane permeability. Sodium (Na) concentration in plant tissues increased in both leaves and roots of plants under the high NaCl treatment. Pixy had much lower Na. The CaSO₄ treatments lowered significantly the concentrations of Na in both leaves and roots. Pixy was more tolerant to salinity than the other two rootstocks. The accumulation of Na in leaves and roots indicates a possible mechanism whereby Pixy copes with salinity in the rooting medium, and/or may indicate the existence of an inhibition mechanism of Na transport to leaves. Concentrations of Ca and K were lower in the plants grown at high NaCl than in those under the control treatment, and these two element concentrations were increased by calcium sulfate treatments in both leaves and roots, but remained lower than control values in most cases.     

Growth and Nutrient Composition of Sugarcane Genotypes Subjected to Salinity and Drought Stresses

Drought and salinity individually or in combination adversely affects growth, development, and yield of sugarcane. Apart from physiological traits, nutrients status was studied in six commercial hybrids subjected to drought, salinity, and salinity + drought. Drought was simulated by withholding irrigation in the field, while salinity and salinity + drought were imposed in microplots. Physiological traits, viz, chlorophyll fluorescence, chlorophyll (SPAD) index, biomass production, and leaf area index, reduced drastically in combined stress as against individual stress treatments. Among major nutrients, phosphorus (P) reduced significantly in all the stress treatments. Similarly, iron (Fe) and Zinc (Zn) reduced due to stress and showed differential response for growth stages. Reduction in cane yield and sucrose percentage in stress conditions warrants supplementation of P, Fe, and Zn.     

拔节期干旱胁迫下冬小麦品种间产量及生理响应的差异

拔节期干旱是影响冬小麦产量的重要灾害,揭示不同品种对干旱胁迫生理响应的差异,可为鉴选与培育抗旱品种提供指导。选取黄淮海平原不同冬麦区种植面积较大的晋麦47、洛旱2号、石家庄8号、豫麦18和郑麦9023共5个品种和1个抗逆性较弱的品种偃麦20,利用防雨棚开展盆栽试验研究。从籽粒产量以及气孔特性、膜稳定性和渗透调节特性等方面,分析拔节期受水分胁迫后,各品种抗旱性和干旱胁迫响应途径的差异。结果表明:(1)灌溉条件下,晋麦47、洛旱2号和石家庄8号产量较高,豫麦18和偃麦20产量较低。拔节期受干旱胁迫后,晋麦47、洛旱2号和豫麦18产量较高,石家庄8号和偃麦20产量较低。可见,以籽粒产量为抗旱性评价的核心指标,晋麦47、洛旱2号和豫麦18抗旱性较强,石家庄8号和偃麦20抗旱性较弱,郑麦9023抗旱性居中。(2)3个抗旱品种间干旱胁迫响应途径并不一致。与抗旱性较弱的石家庄8号和偃麦20相比,拔节期干旱胁迫下,豫麦18气孔导度较低,气孔调节能力强;洛旱2号细胞渗透势较低,渗透调节能力较强;洛旱2号膜离子渗漏率较低,膜稳定性较强;晋麦47在气孔调节、渗透调节和膜稳定性调节方面与抗旱性较弱的品种无显著...     

Salinity and Defoliation Effects on Soybean Growth

An experiment was conducted to determine if salinity stress alters the response and tolerance of soybean to defoliation. Four soybean [Glycine max(L.) Merr.] cultivars (‘Tachiutaka,’ ‘Tousan 69,’ ‘Dare’ and ‘Enrei’) in a growth chamber were exposed to two salinity treatments (0 and 40 mM NaCl) and two defoliation treatments (with and without defoliation). The interactive effects of salinity stress and defoliation on growth rate, leaf expansion, photosynthetic gas exchange, and sodium (Na⁺) accumulation were determined. The decrease in growth rate resulting from defoliation was more pronounced in plants grown under salinity stress than in those grown without the stress. Without salinity stress, defoliated plants of all four cultivars had leaf-expansion similar rates to those of the undefoliated ones, but the photosynthetic rates of their remaining leaves were higher than those of undefoliated plants. However, with salinity stress, defoliated ‘Tachiutaka’ and ‘Tousa 69’ had lower leaf expansion and photosynthetic rates than undefoliated plants. For cultivars ‘Dare’ and ‘Enrei,’ the defoliated plants had leaf-expansion rates similar to undefoliated ones, but the photosynthetic rate of the remaining leaves did not increase. Except for cultivar ‘Dare,’ defoliated plants grown under salinity stress had higher Na⁺ accumulation in leaves than undefoliated ones, and this result may be related to slow leaf expansion and photosynthesis. Salinity stress negatively affects soybean response and tolerance of defoliation, and the effects varied according to the salt tolerance of the cultivar.     

Effects of Soil Salinity on Growth,Ion Relations,and Compatible Solute Accumulation of Two Sumac Species: Rhus glabra and Rhus trilobata

The effects of soil salinity on growth, photosynthetic pigments, ion relations, and compatible solute accumulation of two sumac seedlings (Rhus glabra and Rhus trilobata) treated with five salinity levels in a completely randomized block design with four replications were studied. Both species were inhibited by soil salinity, but salt-damaged symptoms appeared much earlier and more severely in R. glabra, and relative height growth rates (RGR_H) and photosynthetic pigment contents were much higher on average in R. trilobata. The biomass increment, root/shoot ratio, and relative shoot dry weight (DW) were significantly affected only in R. glabra. Rhus trilobata showed stable potassium (K⁺) concentration and low sodium (Na⁺) accumulation in roots, stems, and leaves, and a proline concentration 10 times greater than that of R. glabra. Overall, our findings suggest that R. trilobata is more salt-tolerant than R. glabra, which is presumably rooted in its better performance in ionic homeostasis and osmotic regulation.     

Evaluation of Rice and Wheat Cultivars for Tolerance to Salinity and Sodicity in Soil

The large genotypic variation for salt tolerance in rice and wheat is the driving force behind efforts to identify appropriate cultivars for salt‐prone environments where large variations in salinity (electrical conductivity, EC) and sodicity (sodium adsorption ratio, SAR) levels exist. An evaluation of the commonly grown rice and wheat cultivars at different EC/SAR ratios may thus help in coping with the crop failures on salt‐affected soils. Accordingly, we evaluated some salt‐tolerant cultivars of rice and wheat for growth and yield at different soil salinity and sodicity levels in a sandy clay loam soil. Among the cultivars tested, rice ‘SSRI‐8’ produced the highest productive tillers and paddy yield, and wheat cultivar ‘SIS‐32’ produced the highest tillers and grain and straw yields. The high EC/SAR ratios proved more hazardous for rice than for wheat. Irrespective of the varieties tested, the highest levels of EC and SAR (T₅ and T₆) caused significant reduction in paddy yield, whereas at the lowest levels of EC and SAR (T₁ and T₂), paddy yield was not affected significantly when compared with the control. However, in case of wheat crop, all the levels [i.e., the lowest (T₁ and T₂), medium (T₃ and T₄), and the highest (T₅ and T₆) of EC and SAR tested] affected wheat yield adversely with significant differences. For both the crops, there were little or no differences in yield between the two ratios tested (i.e., 1:2 and 1:4) at all the levels of EC and SAR.     

Cd~(2+)胁迫下多年生黑麦草的生长与生理响应

为检验多年生黑麦草对重金属Cd2+的修复潜力,本文研究了多年生黑麦草对重金属Cd2+的积累特性和生长、生理响应,采用水培法对多年生黑麦草进行0、5、10、20mg·L-1重金属Cd2+胁迫,测定了地上部和地下部的生物量、Cd浓度。结果表明,处理6d后,多年生黑麦草的生长受Cd2+显著抑制,地下部、地上部的Cd2+浓度均随着处理浓度的增加而显著升高,多年生黑麦草对Cd2+具有超量积累能力。5mg·L-1Cd2+处理6d后,多年生黑麦草的地下部、地上部生物量和根冠比分别较对照显著下降了36.83%、12.17%和27.59%,叶片的净光合速率在5mg·L-1Cd2+处理6d后较对照显著下降了23.38%,而其他的气体交换参数、光合色素含量和PSⅡ最大、潜在光化学效率均未受到Cd2+的影响;当光合有效辐射超过580μmol·m-2·s-1时,5mg·L-1Cd2+处理下的实际光化学效率和相对电子传递速率均显著低于对照,Cd2+对多年生黑麦草光反应系统电子传递的抑制程度随着光合有效辐射的升高而增加;当辐射强度达到1 465μmol·m-2·s-1时,相对电子传递速率较对照显著下降了15.46%。5mg·L-1Cd2+胁迫下,多年生黑麦草叶片PSⅡ调节性能量耗散始终显著高于对照,减轻了过多激发能对光合机构的伤害。5mg·L-1Cd2+胁迫下,多年生黑麦草叶片和根系的超氧化物歧化酶、抗坏血酸过氧化物酶的活性被抑制,过氧化氢酶的活性被促进,丙二醛的含量显著提高。净光合速率、相对电子传递速率及SOD、APX活性可做为检验Cd2+对多年生黑麦草毒害的生理指标。本研究得到的结论可为在草坪草中选育重金属污染的修复植物提供参考。     

Characterization of salt tolerance in tomato plant in terms of photosynthesis and water relations

Three commercial tomato cultivars (UC-97, Momotaro, and Edkawi) were subjected to a gradual increase of NaCI concentrations and the effect on biomass production and its parameters was compared. The data indicated that salinity reduced plant growth and the reduction was more pronounced in UC-97 and less in Edkawi. The apparent photosynthetic rate (P _o) was also depressed by the salt treatment and the depression was more remarkable in UC-97 and less in Edkawi. Edkawi shoot showed a much higher concentration of sodium ion and proline compared with the other cultivars, which may result in the maintenance of a higher turgor potential. In all the cultivars examined the stem diameter decreased after the beginning of exposure to light and recovered after the light was turned off. The decrease in the stem diameter during day light was enhanced and the recovery at night decreased after 1 d of salt treatment and the changes in the stem diameter were less conspicuous in Edkawi than in the other cultivars. These results suggest that Edkawi is more tolerant to salinity than the other cultivars due to a higher ability of maintaining the root function for the uptake and supply of water to shoot under salinity conditions but not due to the adjustment of transpiration from stomata.     

Growth Parameter and These Ratio Ionics Responses of Three Cultivars Pistachio to Low and High Salinity

Salinity as a major abiotic stresses is one of the main challenges in world’s agricultural productions. The aim of this work was to study the effect of salinity on growth parameter and these ratio ionics responses of three cultivars pistachio. The experiment was arranged in a randomized complete block design consisting of a 3 × 4 factorial combination of three pistachio cultivars (Akbari, Aghaei, and Kalle-Ghuchi) and four salinity levels (1, 5, 10, and 15 dS/m sodium chloride) with three replications. The results showed that the Aghaei cultivars having a high ratio of potassium (K)/sodium (Na) and maintain this ratio at different levels of salinity and Akbari cultivars is sensitive to salinity because of the less ratio of K/Na.     

INTERACTIVE EFFECTS OF SALINITY AND PHOSPHORUS NUTRITION ON PHYSIOLOGICAL RESPONSES OF TWO BARLEY SPECIES

Salinity is one of the most important agricultural problems in Iran. The effect of different levels of salinity and phosphorus on shoot length, root and shoot fresh and dry weight, nutrient elements (sodium (Na⁺), potassium (K⁺), phosphorus (P) and chloride (Cl^?), proline and soluble sugar contents of barley were investigated. Two cultivars of barley, Hordeum murinum (wild resistant germplasm) and Hordeum vulgar, variety Afzal were treated in vegetative stage under hydroponics condition in a factorial arrangement based on completely randomized block (CRB) design with four levels of salinity [0, 100, 200 and 300 mM sodium chloride (NaCl)] and three levels of phosphorus (15, 30 and 55 μm L^?1) with three replications. By increasing salinity, all the measured parameters, except sodium (Na⁺) content were reduced. Furthermore, with increased in phosphorus levels from 15 to 55 μm, Na⁺ content of the plant shoots decreased, but length, fresh and dry weights of roots and shoots and K⁺, P, Cl^?, proline, and soluble sugars content of the shoots increased. The results indicated that accumulation of mineral ions for osmotic adjustment and restriction of Na⁺ accumulation in shoots were involved in phosphorus enhancement of the salt tolerance of barley. Thus, it seems that in saline soils, where there is no possibility for soil leaching and amending, application of phosphorus fertilizers can lead to a satisfactory growth and production in barely yield.     

冬春季多年生牧草对富营养化水体的响应及净化效果研究

在室外条件下以8种多年生牧草为材料研究其在重度富营养化水体中的生长状况及生长期间对水体氮磷的削减。结果表明,8种牧草均能适应水生环境并快速生长。经过收割后,每1m2的坦克草浮床生长期内可从水体中吸收17.5g的氮和7.5g的磷。牧草修复水体后,其作为饲料的基本指标均符合国家标准。选取室外试验中生长状况较好的4种多年生牧草进行室内模拟实验,研究其对富营养化水体的修复效应。水体TN、TP、NH4+-N、NO3--N、NO2--N、COD在植物浮床系统处理下均显著下降,坦克草处理下去除率最高,对TN、TP、NO3--N、CODMn去除率分别达64.1%,92.1%,70.7%和80.7%。多年生牧草在冬春季对富营养化水体中的氮磷具有较好的净化效果,可作为水体生态修复的优良物种而使用。