Influence of N form on growth photosynthesis of Phaseolus vulgaris L. plants

Many plant species are characterized by pronounced sensitivity to sole ammonium supply and exhibit growth depression and particularly reduced leaf growth rates. Stress symptoms under sole ammonium supply may be related to perturbation of photosynthetic processes, e.g., low rates of net CO₂ assimilation, low quantum yield, reduced stomatal conductance, and carboxylation capacity. The results of three experiments with French bean plants supplied with an N concentration of 5 mM illustrate significantly lower dry mass and specific leaf area, reduced leaf expansion, and higher chlorophyll and N content of ammonium‐ compared to nitrate‐supplied plants. Light‐saturated rates of CO₂ assimilation (A_max) per unit leaf area were higher under ammonium compared to nitrate supply while no significant effects of N form on quantum yield and A_max per unit leaf weight and chlorophyll were found. Maximal carboxylation (V_cmax) and electron‐transport (J_Max) rates were significantly higher under ammonium supply only in one of three experiments. V_cmax was linearly related to total leaf N, the slope of the regression was similar with both N forms, the x‐axis intercept was significantly higher for ammonium‐ compared to nitrate‐supplied plants. The ratio V_cmax : J_Max was not affected by N form. It is concluded that ammonium supply had no negative effects on the operation of photosynthetic protein‐enzyme complexes.     

旱地冬小麦宽幅匀播光合效应研究

宽幅匀播技术优化了作物群体结构,使小麦显著增产。为了给大面积推广宽幅匀播技术提供理论支撑,以常规条播为对照,采用田间试验研究了旱地冬小麦宽幅匀播的光合效应。结果表明,从拔节期到灌浆期,旱地宽幅匀播冬小麦旗叶叶绿素SPAD值较常规条播高3.1～6.3;盛花期较常规条播小麦旗叶净光合速率(Pn)提高13.4%、气孔导度(Gs)增加34.84%、胞间CO₂浓度(Ci)降低16.05%、蒸腾速率(Tr)提高8.47%。宽幅匀播能显著提高小麦叶片叶绿素含量,改善冬小麦光合特性,使小麦叶片能更有效利用胞间CO₂,提高光合和运输能力,从而显著增加产量。     

Effect of Potassium Fertilizer Application on Physiological Parameters and Yield of Cotton grown on a Potassium deficient Soil

A potassium fertilizer field trial was carried out on a coarse silty loamy soil, low in exchangeable K⁺ in the Zhejiang Province (People's Republic of China). Potassium fertilizer applications increased the leaf area, the chlorophyll concentration, and the CO₂ assimilation of cotton grown on this K⁺ deficient soil. Potassium increased the activity of the cytochrome oxidase and nitrate reductase, increased the stomatal conductance and decreased the transpiration. The leaf tissue of K⁺ deficient plants was flaccid, the cuticle of leaves poorly developed and contrasted much with the leaves well supplied with K⁺ which were characterized by a full turgor and a well developed cuticle. According to these physiological effects of K⁺, potassium fertilizer application increased lint yield and improved cotton and seed quality.     

盐度和氮素对向日葵(Helianthus annuus L.)光合速率和生长状况的影响

Understanding the interactions between salinity and fertilizers is of significant importance for enhancing crop yield and fertilizeruse efficiency. In this study a complete block design experiment was performed in the Hetao Irrigation District of Inner Mongolia,China, to evaluate the effects of interactions between soil salinity and nitrogen(N) application rate on sunflower photosynthesis and growth and to determine the optimum N application rate for sunflower growth in the district. Four levels of soil salinity expressed as electrical conductivity(0.33–0.60, 0.60–1.22, 1.2–2.44, and 2.44–3.95 dS m-1) and three application rates of N fertilization(90, 135,and 180 kg ha-1) were applied to 36 micro-plots. Soil salinity inhibited the photosynthetic rate, stomatal conductance, transpiration rate, plant height, leaf area, and aboveground dry matter of sunflowers. The intercellular CO2 concentration first decreased and then increased with increasing soil salinity in the seedling stage, and the instantaneous leaf water-use efficiency fluctuated with soil salinity. The stomatal and non-stomatal limitations of sunflowers alternated in the seedling stage; however, in the bud, blooming,and mature stages, the stomatal limitation was prevalent when the salinity level was lower than 2.44 dS m-1, whereas the nonstomatal limitation was predominant above the salinity level. The application of N fertilizer alleviated the adverse effects of salinity on sunflower photosynthesis and growth to some extent. During some key growth periods, such as the seedling and bud stages, a moderate N application rate(135 kg ha-1) resulted in the maximum photosynthetic rate and yielded the maximum dry matter. We suggest a moderate N application rate(135 kg ha-1) for the Hetao Irrigation District and other sunflower-growing areas with similar ecological conditions.     

Ozone effects on Aleppo pine seedlings (Pinus halepensis Mill.) grown in open-top chambers

A three-year term experiment was performed in eastern Spain to assess the effects of ozone (O₃) on the physiological behaviour of Aleppo pine (Pinus halepensis). Seedlings of this species were enclosed in open-top chambers during the summer and exposed to either Charcoal Filtered Air (CFA) to exclude O₃, Non Filtered Air (NFA) or Non Filtered Air plus 40 ppb O₃, 9h/day, 5 days/week (NFA+40). Gas exchange, foliar chlorophyll and nutrient levels were measured throughout the year. Clear seasonal fluctuations were observed since chlorophyll levels, stomatal conductance and net photosynthesis rates were lower during the summer, and higher in winter. O₃-induced effects were apparent on previous year needles from the second year of exposure. A reduction in net photosynthesis, stomatal conductance, chlorophyll, N and P was found in the NFA+40 plots. The results showed the sensitivity of this species to ozone, since a three-month exposure to realistic O₃ concentrations over three consecutive years induced important alterations in Aleppo pine performance. The application of the results to the definition of a critical O₃ level for forest trees is discussed.     

Physiological responses of lupinus mutabilis to phosphorus nutrition and season of growth

The response to phosphorus (P) concentration in the nutrient solution (0–0.5 mol P m^‐3) was studied in Lupinus mutabilis Sweet cv. Potosi in two different seasons (winter and spring). Phosphorus deficiency was more severe on growth than on photosynthesis and the season of growth dramatically influenced the optimal concentration of P for plant growth; root biomass was proportionally less affected than shoot biomass. During winter, growth and photosynthesis of plants supplied with 0.02–0.5 mol P m^‐3 were not significantly different, whereas in spring, rates of growth and photosynthesis were faster at the 0.5 mol P m^‐3 level. Stomatal conductance decreased with deficient P independently of leaf water relations. Severe P deficiency limited carbon (C) assimilation rates due to reduction in stomatal conductance and mesophyll photosynthetic capacity. Decreased sucrose/starch in P‐deficient leaves was a consequence of the observed source/sink imbalance which was more marked in winter. Hydraulic conductance was not a limiting factor for leaf expansion under low P. In conclusion, growth and metabolic changes observed in lupins grown at low P supply can be ascribed to an adjustment at the whole plant level, preventing a large drop in leaf P, reducing shoot growth and facilitating P uptake through higher root biomass.     

氮素对超高产小麦生育后期光合特性及产量的影响

本试验在大田条件下研究了施氮量对超高产小麦生育后期光合特性的影响。利用LI-6400便携式光合测定仪,采用开放式气路测定了超高产麦田旗叶的净光合速率、胞间CO2浓度、气孔导度等相关指标。结果表明,氮素对超高产小麦生育后期的光合特性有较大的调节作用,随着施氮量增加,小麦的净光合速率增强,但过高的施氮量（N 375 kg/hm2）导致灌浆后期叶片衰老快,净光合速率下降迅速,叶面积指数降低,千粒重下降明显,最终导致产量的减少。在本试验条件下,超高产麦田的适宜施氮量为N 300 kg/hm2。     

两种氮水平下CO2浓度升高对冬小麦生长和氮磷浓度的影响

预计到 2 1世纪末期大气CO2 浓度将会比目前水平增加 1倍 ,约 70 0 μmolmol- 1 左右。因此CO2 浓度升高对作物的影响研究十分重要。本文探讨在两种氮 (N)水平下 ,CO2 浓度升高对冬小麦 (TriticumaestivumL cv Xinong 872 7)生长和地上部N、磷 (P)浓度的影响及原因。试验设 3 5 0 μmolmol- 1 和 70 0 μmolmol- 1 两种CO2 浓度水平和 45kghm- 2 和 90kghm- 2 两种N肥施用水平。结果表明 ,CO2 浓度升高 ,冬小麦株高和叶面积指数 (LAI)均增加 ,净同化率 (NAR)值增加 ,叶面积比率 (LAR)下降 ,比叶重 (SLW )不增加。高CO2 浓度对相对生长率 (RGR)的影响因施N水平而异 ,低N时RGR不增加 ,高N时明显增加。CO2 浓度增加 ,小麦抽穗提早 7～ 8d ,叶鞘、茎杆和地上部干物重提高 ,叶片、叶鞘和茎杆N、P浓度降低 ,但叶片、叶鞘和茎杆N、P吸收量增加均不明显。CO2 浓度升高 ,氮磷利用效率 (NUE和PUE)提高 ,而对相对氮磷累积速率 (RNAR和RPAR)影响不大。高CO2 浓度冬小麦体内N、P浓度下降是由于稀释效应以及NUE和PUE提高之故。     

Use of a chlorophyll meter to evaluate the nitrogen status of dryland winter wheat

Abstract

Chlorophyll meter leaf readings were compared to grain yield, leaf N concentration and soil NH₄‐N plus NO₃‐N levels from N rate studies for dryland winter wheat Soil N tests and wheat leaf N concentrations have been taken in the spring at the late tillering stage (Feekes 5) to document a crop N deficiency and to make fertilizer N recommendations. The chlorophyll meter offers another possible technique to estimate crop N status and determine the need for additional N fertilizer. Results with the chlorophyll meter indicate a positive association between chlorophyll meter readings and grain yield, leaf N concentration and soil NH₄‐N plus NO₃‐N. Additional tests are needed to evaluate other factors such as differences among locations, cultivars, soil moisture and profile N status.     

Economic viability of Phaseolus vulgaris (BRS Estilo) production in irrigated system in a function of application of leaf boron

Foliar fertilization may be a viable strategy to boron supply in irrigated cropping systems with common beans (Phaseolus vulgaris), since it prevent B leaching. The aim of this work was to evaluate the economic viability and physiological parameters of the common beans production in irrigated cropping systems using sources and increasing foliar boron doses. A field experiment was carried out using an experimental block design in a factorial scheme 2?×?5?×?3, with two sources of B (boric acid and borax) and five doses: 0 (control), 2, 4, 6 e 8?kg?ha^?1, with three repetitions. Foliar B applications were performed at 40 days after seeds germination, in pre-flowering stage. Physiological process (transpiration, stomatal conductance, CO₂ internal concentration, net photosynthesis, and relative chlorophyll index), B level in leaves and grain yield were measured. These data were used to determine the economic viability of B fertilization in common beans. Both boric acid and borax increased B levels in common beans leaves. Borax affected some physiological process reducing stomatal conductance and increasing net photosynthesis. Using borax, the highest net photosynthesis was observed at a rate of 4?kg?ha^?1, while the boric acid increased net photosynthesis linearly after increasing B doses application. An enhance of 311?kg?ha^?1 in the grain yield was observed using borax related to the control (without B application); however, grain yield decreased linearly after application of increasing B doses, as boric acid. Comparing the economic viability of sources and doses of B, the highest profitability is obtained using borax at a rate of 4?kg?ha^?1, which promoting a differential profit of US$534.44 per hectare compared to common beans cropping without B.     

Interaction of Glyphosate with Zinc for the Yield,Photosynthesis, Soil Fertility and Nutritional Status of Soybean

Application of glyphosate herbicide in genetically modified (GM) soybean [Glycine max (L.) Merrill] in soils with low zinc (Zn) concentration may interfere in the uptake of this and other nutrients, with negative impact on productivity. Thus, an experiment was conducted in greenhouse conditions on Ustoxix Quatzipsamment soil to investigate the effects of the interaction of glyphosate with Zn for the yield, photosynthesis, soil fertility and nutritional status of soybean. The treatments consisted of two soybean varieties [BRS 133 (conventional—NGM) and its essentially derived transgenic line BRS 245RR (GM) with and without glyphosate application] and five Zn rates (0, 5, 10, 20 and 40 mg kg^?1, source zinc sulfate (ZnSO₄)), with four replicates. Except for the copper (Cu) and iron (Fe) concentrations, the introduction of the herbicide-resistant gene is the predominant factor reducing nutrient uptake, photosynthetic (A) rate, stomatal conductance (Gs), leaf chlorophyll and ureide concentrations. The administration of Zn rates lowered the leaf phosphorus (P) concentration, and there was significant increase in Zn concentration in the soil and in the plant. Except for the 20 mg kg^?1 of Zn rate, the use of the herbicide did not affect the shoot dry weight (SDW) and seed yield, and on average, the maximum seed yield was obtained with Zn concentrations of 26.4 and 18.7 mg kg^?1 extracted by Mehlich 1 and diethylenetriaminepentaacetic acid-triethanolamine (DTPA-TEA), respectively.     

Effect of nitrogen supply on leaf traits related to photosynthesis during grain filling in two maize genotypes with different N efficiency

In the present study, plant traits related to the photosynthetic capacity at the whole plant level were compared during grain filling in two maize genotypes with different nitrogen (N) efficiency. The plants were grown in a greenhouse in large root containers and supplied either with suboptimal or optimal rates of N fertilizer. Suboptimal N supply reduced total plant biomass at maturity (47 days (d) after flowering) by 29 % for the efficient genotype and by 36 % for the inefficient genotype. Suboptimal N supply reduced leaf growth of both genotypes. The reduction of leaf area was less severe in the N‐efficient genotype, despite of lower N content in the leaves. This indicates lower sensitivity of leaf growth towards internal N limitation in the efficient genotype. At low N supply, the green leaf area per plant gradually decreased after flowering in both genotypes, because of loss of chlorophyll during leaf senescence. The rate of net photosynthesis per unit leaf area (A) was reduced at low in comparison with high N supply. The ratio of A/leaf N content or leaf chlorophyll content was higher in the efficient genotype, indicating more efficient utilization of internal N for photosynthesis. At the end of grain filling, low N supply led to enhanced intercelluar CO₂ concentrations (Ci) in the leaves, indicating limitation of CO₂ assimilation by carboxylation rather than by stomatal resistance. The N deficiency‐induced increase of Ci was less pronounced in the efficient genotype. Furthermore, higher photosynthetic rate of the efficient genotype at suboptimal N supply was associated with lower contents of reducing sugars and sucrose in the leaves, whereas starch content was higher than in the inefficient genotype. The ability to avoid excessive sugar accumulation in the leaves under N deficiency might be related to higher photosynthetic N efficiency.     

低磷条件下不同磷效率小麦品种及其杂种F1光合碳同化特性研究

以典型的磷低效(L)、吸收高效(H1)和利用高效(H2)的小麦品种及以上述品种为亲本配制的杂种F1-1(L×H1)和F1-2(L×H2)为材料,对上述品种和杂种F1的光合特性及其生理机制进行了研究。结果表明,缺磷条件下,随着叶片生长进程,供试品种和杂种F1旗叶CO2传导参数气孔导度(Gs)、叶肉导度(Gm)和碳酸酐酶(CA)活性;旗叶叶绿素含量(Chl)、光合速率(Pn)、叶绿体无机磷(PI)浓度和Mg2+-ATPase活性、可溶蛋白含量(SP)和RuBPCase活性均不断降低。不同磷效率类型品种相比,旗叶各测定时期上述参数均以L较低,H1和H2较高。与各自亲本相比,F1-1和F1-2各测定时期的光合生理参数多表现出明显的优势。表明磷高效小麦品种(H1和H2)以及杂种叶片光合碳同化特性的相对提高,是由于其光合器官捕获光能的能力较强、光合作用气孔限制和非气孔限制的程度较低和暗反应速率较高综合作用的结果。其中,磷高效品种及杂种F1叶绿体Pi供应量的增多,在维持光合器官的结构和功能中可能具有重要作用。研究还表明,供试不同磷高效小麦品种之间(吸收高效H1和利用高效H2)尽管在磷的吸收和利用特征上表现明显不同,但在叶片的光合碳同化特性及其内在生理机制上表现相似,表明控制小麦磷素吸收与利用的遗传基因位点可能与控制光合器官结构与功能的遗传位点不存在紧密连锁。在低磷胁迫条件下,充分利用杂种F1在光合碳同化特性上的杂种优势,对于改善小麦对磷素的吸收和利用以及促进子粒产量的增加具有潜在的应用价值。     

The effects of planting systems on soil biology and quality attributes of tomatoes

This study was carried out to determine the effects of seedling types (grafted and non-grafted) and different plantation systems (raised-bed and flat planting) on growth, yield and quality of tomato (Solanum lycopersicum cv. Depar F1) plants organically grown in open-field conditions in Samsun. Soil microbial biomass-C increased by 25% and soil CO₂ contents increased by 16% in raised-bed systems. It was observed that soil microbial biomass-C positively correlated with CO₂ contents, leaf chlorophyll content, stomatal conductance and yield (P < 0.05 and P < 0.01) and negatively correlated with soil compaction. The highest chlorophyll content (47.37 CCI), fruit shape index (1.21) and yield (1.95 kg plant^?1) were obtained from grafted seedlings of the raised-bed planting systems. The highest stomatal conductance (118.50 mmol m^?2 s^?1) and firmness (79.34%) were obtained from non-grafted seedlings of the raised-bed planting systems. As a result, successful tomato cultivation was carried out with the use of raised-bed and grafted seedlings. However, non-grafted seedlings of the raised-beds had higher yield and quality values than the grafted seedlings of the flat planting.     

华北地区采用无机氮测试和植株速测进行夏玉米氮肥推荐

A field experiment with a split-plot design was carried out at Dongbeiwang Farm in Beijing Municipality to establish reliable N fertilizer recommendation indices for summer maize (Zea mays L.) in northern China using the soil Nmin(mineral N) test as well as the plant nitrate and SPAD (portable chlorophyll meter readings) tests. The results showed that Nrnin sollwert (NS) 60 kg N ha^-1 at the third leaf stage and N rate of 40 to 120 kg N ha^-1 at the tenth leaf stage could meet the N requirement of summer maize with a target yield of 5.5-6 t ha^-1. Sap nitrate concentrations and SPAD chlorophyll meter readings in the latest expanded maize leaves at the tenth leaf stage were positively correlated with NS levels, indicating that plant nitrate and SPAD tests reflected the N nutritional status of maize well. Considering that winter wheat subsequently utilized N after the summer maize harvest, the 0-90 cm soil Nmin (74 kg N ha^-1) and apparent N loss (12 kg N ha^-1) in the NS60＋40 treatment were controlled at environmentally acceptable levels. Therefore NS60＋40, giving a total N supply of 100 kg N ha^-1, was considered the optimal N fertilizer input for summer maize under these experimental conditions.     

Cold tolerance,yield, and fruit quality of ‘d'Anjou’ pears influenced by nitrogen fertilizer rates and time of application

Low and moderate rates of ammonium nitrate (NH₄NO₃) fertilizer were applied in late winter or late summer to mature ‘d'Anjou’ pear (Pyrus communis, L.) trees (planted 1963, 1965) from 1976 to 1994. Data on cold tolerance, nutrition, yield and fruit quality in relation to nitrogen (N) fertilization were collected between 1980 and 1988. Early autumn cold tolerance was higher for trees receiving low N rates versus moderate N rates in either late winter or late summer. In late autumn and early winter, cold tolerance increased for all trees, and little difference in winter hardiness existed for any N treatment. By mid‐winter, cold tolerance was higher for trees receiving the moderate rate of N in late winter versus low N in late summer. Cold tolerance was relatively high throughout autumn and winter freeze‐test periods for trees fertilized with low N in late winter. Tree vigor, fruit size, leaf N, and fruit N were highest for trees receiving the late winter, moderate rate of N. Yield was lowest, but fruit firmness, fruit quality and fruit calcium (Ca) concentrations were highest for trees treated with the late winter, low rate of N. The incidence of cork spot was lower from trees with the late winter, low N treatment than for the late summer, moderate N‐treated trees.     

Phosphorus affects storage root yield of cassava through root numbers

Abstract

The objective of this study was to determine the effect of phosphorus applied through fertigation on growth and root yield of cassava. This was achieved through a greenhouse pot-experiment consisting of 1, 4, 7, 10, 20 and 30?mg?P?L^?1. Increasing P from 1 to 30?mg?P?L^?1 realized a 57.1 and 150.0% increase in leaf blade P in 2014 and 2015, respectively. Similarly, chlorophyll content and shoot growth increased as P concentration in solution increased. However, leaf stomatal conductance and net photosynthesis reached a maximum in 7 and 20?mg?P?L^?1 in 2014 and 2015, respectively. This trend of stomatal conductance and net photosynthesis was consistent with that of dry root yield and storage roots numbers. Regressing dry root yield against storage root numbers showed that R² = 0.80. Phosphorus encourages formation of storage roots and the duration of cassava’s growth affects the amount of P required for maximum root yield.     

Influence of nitrogen on leaf chlorophyll content and photosynthesis of ‘Golden Delicious’ apple

Abstract

The aim of the present study was to estimate the influence of different rates of soil-applied nitrogen on leaf N and chlorophyll content and photosynthesis in ‘Golden Delicious’ apple trees. Three different treatments were included: the trees were either fertilized with 80 kg N ha^?1 (N-80), 250 kg N ha^?1 (N-250) or left unfertilized (CON). Fertilization increased leaf nitrogen content, with a more prominent effect in high N application level treatment. In all treatments, a slight seasonal decrease in leaf nitrogen content was observed. N-250 treatment resulted in higher chlorophyll content; a similar effect was found late in the season for N-80 treatment. Measurements of A-C _i curves, performed on spur leaves, revealed a higher CO₂ saturated photosynthetic rate in N-250 trees compared with low application level fertilized or unfertilized trees. No effect of N fertilization on carboxylation efficiency was found, as revealed by comparisons of the initial slopes of A-C _i curves. The lack of positive effect is rather surprising, since the leaf N content was efficiently increased with application of fertilizer. Obviously, the existing pool of leaf nitrogen in non-fertilized trees does not limit Rubisco activity and efficiency.     

Effect of NO3 and NH4 concentrations in nutrient solution on yield and nitrate concentration in seasonally grown leaf lettuce

The effect of suboptimal supply of nitrogen (N) and of replacing nitrate in the nutrient solution with ammonia on growth, yield, and nitrate concentration in green and red leaf lettuce was evaluated over two seasons (autumn and spring) using multiple regression analysis. The plants were grown in a greenhouse on a Nutrient Film Technique (NFT) system. Nitrogen concentrations in the nutrient solution were either 3?mM or 12?mM, and the form of N was varied as follows: 100% NO₃, 50% NO₃?+?50% NH₄, and 100% NH₄. In both seasons, the biomass (fresh weight) of lettuce heads increased with increasing NO₃ concentrations and in autumn, NO₃ even at 1.5?mM was sufficient for high yield. However, head dry weight was affected neither by the season nor by changes in the composition of the nutrient solution. The concentration of NO₃ had no effect on root dry weight, but it decreased at higher concentrations of NH₄. The number of leaves increased as the ratio of NO₃ to NH₄ in the nutrient solution increased and was higher in autumn because of the longer growth period. Increasing the concentration of NO₃ in nutrient solution increased both total N and nitrate concentration in lettuce heads (dry weight) but decreased the concentration of total C. Also, leaf nitrate concentration was lower in spring than in autumn and decreased with increasing NH₄ concentration. Nitrogen utilization efficiency was maximum when NH₄ levels in the nutrient solution were either 0% or 50% irrespective of the season. Our results thus show that suboptimal N supply in autumn will not affect lettuce yield, and that nitrate concentration in leaves is lower when NH₄ concentrations in nutrient solution are higher and also much lower in red lettuce than in green lettuce.     

Effect of silicon on photosynthetic gas exchange,photosynthetic pigments,cell membrane stability and relative water content of different wheat cultivars under drought stress conditions

This study aims to explain the effects of silicon (Si) foliar application on gas exchange characteristics, photosynthetic pigments, membrane stability and leaf relative water content of different wheat cultivars in the field under drought stress conditions. The experiment was arranged as a split-split plot based on randomized complete block design with three replications. Irrigation regime (100%, 60%, and 40% F.C.), silicon (control and Si application) and wheat cultivars (Shiraz, Marvdasht, Chamran, and Sirvan) were considered as main, sub and sub-sub plots, respectively. This study was carried out at the Research Farm of the Collage of Agriculture, Shiraz University, Iran, during 2012–2013 growing season. The results showed that foliar application of silicon increased the leaf relative water content, photosynthesis pigments (chlorophyll a, b and total chl and carotenoids), chlorophyll stability index (CSI) and membrane stability index (MSI) in all wheat cultivars, especially in Sirvan and Chamran (drought tolerant cultivars), under both stress and non-stress conditions. However, more improvement was observed under drought stress as compared to the non-stress condition. In contrast, these parameters decreased under drought stress. Si significantly decreased electrolyte leakage in all four cultivars under drought stress conditions. Furthermore, the intercellular carbon dioxide (CO₂) concentration (C_i) increased under drought stress. Si application decreased C_i especially under drought stress conditions. Net photosynthesis rate (A), transpiration rate (E) and stomatal conductance (g_s) were significantly decreased under drought conditions. Under drought, Si applied plants showed significantly higher leaf photosynthesis rate, transpiration rate, and stomatal conductance. Intrinsic water use efficiency (WUEi) and carboxylation efficiency (C_E) decreased in all cultivars under drought stress. However, the silicon-applied plants had greater WUEi and C_E under drought stress. The stomatal limitation was found to be higher in stressed plants compared to the control. Exogenously applied silicon also decreased stomatal limitation. Overall, application of Si was found beneficial for improving drought tolerance of wheat plants.