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1.
Over time, the relative effect of elevated [CO2] on the photosynthesis and dry matter (DM) production of rice crops is likely to be changed with increasing duration of CO2 exposure. However, there is no systemic information on interactive effects of elevated [CO2] and nitrogen (N) supply on seasonal changes in phosphorus (P) nutrient of rice crops. In order to investigate the interactive effects of these two factors on seasonal changes in plant P concentration, uptake, efficiency and allocation, a free-air CO2 enrichment (FACE) experiment was conducted at Wuxi, Jiangsu, China, in 2001–2003. A japonica cultivar with large panicle was grown at ambient or elevated (ca. 200 μmol mol−1 above ambient) [CO2] and supplied with three levels of N: low (LN, 15 g N m2), medium (MN, 25 g N m2) and high N (HN, 35 g N m2 (2002, 2003)). The MN level was similar to that recommended to local farmers. FACE significantly increased shoot P concentration (dry base) over the season, the average responses varied between 7.3% and 16.2%. Shoot P uptake responses to FACE declined gradually with crop development, with average responses of 57%, 51%, 37%, 26% and 11% on average during the growth periods from transplanting to early-tillering (Period I), early-tillering to mid-tillering (Period II), mid-tillering to panicle initiation (Period III), panicle initiation to heading (Period IV) and heading to grain maturity (Period V), respectively. Seasonal changes in shoot P uptake ratio (i.e., the ratio of shoot P uptake during a given growth period to final shoot P acquisition at grain maturity) responses to FACE followed a similar pattern to that of shoot P uptake, with average responses of 19%, 14%, 3%, −5% and −16% in Periods I, II, III, IV and V of the growth period, respectively. As a result, FACE enhanced shoot P uptake by 33% at grain maturity. P allocation patterns among above-ground organs were not altered by FACE before heading, but it was modified after heading, with a shift in P allocation patterns towards vegetative organ. FACE resulted in the significant decrease in P-use efficiency for biomass across the season and P-use efficiency for grain yield and P harvest index at grain maturity. Generally, there were no interactions between [CO2] and N supply on above P nutrient variables measured. Data from this study has important implications for P management in rice production systems under future elevated [CO2] conditions.  相似文献   

2.
Hybrid indica rice (Oryza sativa L.) cultivars play an important role in rice production system due to its heterosis, resistance to environmental stress, large panicle and high yield potential. However, no attention has been given to its yield responses to rising atmospheric [CO2] in conjunction with nitrogen (N) availability. Therefore we conducted a free air CO2 enrichment (FACE) experiment at Yangzhou, Jiangsu, China (119°42′0′′E, 32°35′5′′N), in 2004–2006. A three-line hybrid indica rice cv. Shanyou 63 was grown at ambient and elevated (ca. 570 μmol mol−1) [CO2] under two levels of supplemental N (12.5 g Nm−2 and 25 g Nm−2). Elevated [CO2] had no effect on phenology, but substantially enhanced grain yield (+34%). The magnitude of yield response to [CO2] was independent of N fertilization, but varied among different years. On average, elevated [CO2] increased the panicle number per square meter by 10%, due to an increase in maximum tiller number under enrich [CO2], while productive tiller ratio remained unaffected. Spikelet number per panicle also showed an average increase of 10% due to elevated [CO2], which was supported by increased plant height and stem dry weight per tiller. Meanwhile, elevated [CO2] caused a significant enhancement in both filled spikelet percentage (+5%) and individual grain weight (+4%). Compared with the two prior FACE studies on rice, hybrid indica rice cultivar appears to profit much more from elevated [CO2] than japonica rice cultivar (ca. +13%), not only due to its stronger sink generation, but also enhanced capacity to utilize the carbon sources in a high [CO2] environment. The above data has significant implication with respect to N strategies and cultivar selection under projected future [CO2] levels.  相似文献   

3.
《Field Crops Research》2006,98(1):12-19
It is reported that stimulating effect of elevated atmospheric [CO2] on photosynthesis of rice (Oryza sativa L.) is likely to be reduced during the plant growth period. However, there is little information on seasonal changes in dry matter (DM) production and distribution of rice under elevated atmospheric [CO2]. A free-air CO2 enrichment (FACE) experiment was conducted at Wuxi, Jiangsu, China, in 2001–2003, using Wuxiangging 14, a japonica cultivar. The rice was grown at ambient or elevated (ca. 200 μmol mol−1 above ambient) [CO2] and supplied with 25 g N m2, which is the normal N application rate for local farmers. DM accumulation of rice in FACE plots was significantly increased by 40, 30, 22, 26 and 16% on average at tillering, panicle initiation (PI), heading, mid-ripening and grain maturity, respectively. Rice DM production under FACE was significantly enhanced by 41, 27, 15 and 38% on average during the growth periods from transplanting to tillering (Period 1), tillering to PI (Period 2), PI to heading (Period 3) and heading to mid-ripening (Period 4), respectively, but significantly decreased by 25% in the period from mid-ripening to grain maturity (Period 5). In general, seasonal changes in crop response to FACE in both green leaf area index (GLAI) and net assimilation rate (NAR) followed a similar pattern to that of the DM production. Under FACE the leaves decreased significantly in proportion to the total above-ground DM over the season, the stems showed an opposite trend, while the spikes depended on crop development stage: showing no change at heading, significant increase (+4%) at mid-ripening and significant decrease (−3%) at grain maturity. Grain yield was stimulated by an average of 13% by FACE, due to increased total DM production rather than any changes in partitioning to the grain. We conclude that the gradual acclimation of rice growth to elevated [CO2] do not occur inevitably, and it could also be altered by environmental conditions (e.g., cultivation technique).  相似文献   

4.
Because CO2 is needed for plant photosynthesis, the increase in atmospheric CO2 concentration ([CO2]) has the potential to enhance the growth and yield of rice (Oryza sativa L.), but little is known regarding the impact of elevated [CO2] on grain quality of rice, especially under different N availability. In order to investigate the interactive effects of [CO2] and N supply on rice quality, we conducted a free-air CO2 enrichment (FACE) experiment at Wuxi, Jiangsu, China, in 2001–2003. A long-duration rice japonica with large panicle (cv. Wuxiangging 14) was grown at ambient or elevated (ca. 200 μmol mol−1 above ambient) [CO2] under three levels of N: low (LN, 15 g N m2), medium (MN, 25 g N m2) and high N (HN, 35 g N m2 (2002, 2003)). The MN level was similar to that recommended to local farmers. FACE significant increased rough (+12.8%), brown (+13.2%) and milled rice yield (+10.7%), while markedly reducing head rice yield (−13.3%); FACE caused serious deterioration of processing suitability (milled rice percentage −2.0%; head rice percentage −23.5%) and appearance quality (chalky grain percentage +16.9%; chalkiness degree +28.3%) drastically; the nutritive value of grains was also negatively influenced by FACE due to a reduction in protein (−6.0%) and Cu content (−20.0%) in milled rice. By contrast, FACE resulted in better eating/cooking quality (amylose content −3.8%; peak viscosity +4.5%, breakdown +2.9%, setback −27.5%). These changes in grain quality revealed that hardness of grain decreased with elevated [CO2] while cohesiveness and resilience increased when cooked. Overall, N supply had significant influence on rice yield with maximum value occurring at MN, whereas grain quality was less responsive to the N supply, showing trends of better appearance and eating/cooking quality for LN or MN-crops as compared with HN-crops. For most cases, no [CO2] × N interaction was detected for yield and quality parameters. These data suggested that the current recommended rates of N fertilization for rice production should not be modified under projected future [CO2] levels, at least for the similar conditions of this experiment.  相似文献   

5.
Over time, the relative effect of elevated [CO2] on the photosynthesis and dry matter (DM) production of rice crops is likely to be changed with increasing duration of CO2 exposure, but the resultant [CO2] effects on rice N concentration, uptake, efficiency and allocation remain unclear, especially under different soil N availability. Therefore, we conducted a free-air CO2 enrichment (FACE) experiment at Wuxi, Jiangsu, China, in 2001–2003. A japonica cultivar with large panicle was grown at ambient or elevated (ca. 200 μmol mol−1 above ambient) [CO2] under three levels of N: low (LN, 15 g N m2), medium (MN, 25 g N m2) and high N (HN, 35 g N m2 (2002, 2003)). The MN level was similar to that recommended to local farmers. Averaged across all N levels and years, shoot N concentration (dry base) was lower under FACE by 1.8%, 6.1%, 12.2%, 14.3%, 12.1%, and 6.9% at early-tillering, mid-tillering, panicle initiation (PI), booting, heading and grain maturity, respectively. Shoot N uptake under FACE was enhanced by 46%, 38%, 6% and 16% on average during the growth periods from transplanting to early-tillering (period 1), early-tillering to mid-tillering (period 2), mid-tillering to PI (period 3) and heading to grain maturity (period 5), respectively, but slightly decreased by 2% in the period from PI to heading (period 4). Seasonal changes in crop response to FACE in ratio of shoot N uptake during a given growth period to that over the whole season followed a similar pattern to that of shoot N uptake, with average responses of 33%, 26%, −3%, −11% and 10% in periods 1–5 of the growth period, respectively. As a result, FACE increased final aboveground N uptake by 9% at maturity. FACE greatly reduced the ratio of leaf to shoot N content over the season, while allocation of N to stems and spikes showed an opposite trend. FACE treatment resulted in the significant increase in N use efficiency for biomass (NUEp) over the season except at early-tillering and in N use efficiency for grain yield (NUEg) at grain maturity. These results indicate that, in order to maximize grain output in a future high [CO2] environment, the recommended rates, proportion and timing across the season of N application should be altered, in order to take full advantage of strong N uptake capacity during the early growth period and facilitate N uptake after that.  相似文献   

6.
【Objective】Our aim is to investigate the differences in response of grain yield, nitrogen absorption and utilization to FACE (atmospheric CO2 concentration increase) of different rice varieties. 【Method】Six rice varieties, including conventional japonica rice, hybrid indica rice, and conventional indica rice, were used to study the effects of free-air CO2 enrichment (FACE) (atmospheric CO2 concentration increase) on the nitrogen absorption, utilization, and yield of different types of rice.【Result】 1) FACE treatment dramatically increased rice yield by 24.17% on average and the maximum increment was observed in conventional indica rice. Compared with other types of rice varieties, hybrid indica showed the highest grain yield under both FACE and control (CK) treatments. 2) Panicle number was significantly improved in FACE treatment with conventional japonica rice varieties having the maximum increment. Spikelet number per panicle was significantly improved in hybrid and conventional indica rice varieties in FACE treatment. 3) The nitrogen absorption (NA) and nitrogen use efficiency for grain yield (NUEg) were significantly higher in FACE treatment than those in CK treatment. The average increase of NA was 21.23% with the maximum increment in hybrid indica rice varieties. Compared with other rice varieties, conventional indica rice varieties had the highest NA both in FACE and CK treatments. The average increase of NUEg was 7.33% with hybrid indica rice varieties enjoying the maximum increment. The hybrid indica rice varieties had the highest NUEg in FACE treatment and in CK treatment, respectively. 4) Nitrogen content was decreased in FACE treatment with the average decrease of 0.105%, among which the maximum decrease was observed in conventional japonica rice. Dry matter weight was extremely and significantly increased in FACE treatment. The average increase of dry weight was 23.95% with the maximum increment in conventional indica rice varieties. NA of single panicle was significantly improved in FACE treatment with the average increase of 10.79% in conventional indica rice varieties and 13.93% in hybrid indica rice varieties, but NA of single panicle was decrease by 9.60% in conventional japonica rice. FACE treatment significantly increased rice NA intensity with an average increase of 22.29% and the maximum increment was observed in hybrid indica rice varieties. The growth duration was not influenced by FACE treatment in all rice varieties. NAs of stem, leaf and panicle were significantly higher in FACE treatment than in CK treatment with the highest increase of 51.86% in leaf. The largest increase of NA was observed in hybrid indica rice. NA in different rice growth stages was significantly improved with the maximum increment of 108.90% during heading-maturity. The maximum increment of NA from heading to maturity was observed in hybrid indica rice varieties.5) Effects of dry matter weight, NA per panicle, NA intensity, NA of panicle and NA from heading to maturity on NA at maturity were greater than those of nitrogen content, panicle number, growth duration, NAA of leaf, stem and sheath, NAA during transplanting-tillering and tillering-heading. 6) Partial productivity of nitrogen fertilizer (PFPN) was significantly improved in FACE treatment with an average increase of 24.16% and the maximum increment in conventional indica rice. NAA per 100 kg grains was significantly reduced in FACE treatment with an average decrease of 4.7%. The maximum decrease of NAA per 100 kg grains was observed in conventional indica rice varieties.【Conclusion】The results indicated that FACE could markedly increased both grain yield and nitrogen use efficiency in all rice varieties, but the increases varied with the variety types.  相似文献   

7.
目的 探明不同类型水稻品种产量和氮素吸收利用对FACE(大气CO2浓度增高)响应的差异。方法 以常规粳稻、杂交籼稻、常规籼稻共6个品种为供试材料,研究FACE对不同类型水稻产量、氮素吸收利用的影响。结果 1)FACE处理极显著提高了水稻产量,平均增加24.17%, 常规籼稻增幅最大,FACE和对照均以杂交籼稻最高;2)FACE处理显著增加了单位面积穗数,常规粳稻增幅最大,并显著增加了杂交籼稻和常规籼稻每穗粒数;3)FACE处理显著提高了成熟期吸氮量和氮素籽粒生产效率,成熟期吸氮量平均增加21.23%,杂交籼稻增幅最大, FACE和对照均以常规籼稻最高;氮素籽粒生产效率平均增加7.33%,杂交籼稻增幅最大,FACE和对照均以杂交籼稻最高。成熟期吸氮量对产量促进作用略大于成熟期氮素籽粒生产效率;4)FACE处理降低了植株含氮率,成熟期平均下降0.105个百分点,常规粳稻降幅最大。FACE处理极显著提高植株干物质量,成熟期平均增加23.95%,常规籼稻增幅最大;FACE处理显著提高常规籼稻和杂交籼稻成熟期单穗吸氮量,分别增加10.79%、13.93%,但常规粳稻下降了9.60%;FACE处理显著提高了成熟期群体吸氮强度,平均增加22.29%,杂交籼稻增幅最大。FACE处理对水稻全生育期天数无显著影响;FACE处理显著提高茎鞘、叶片、穗各器官吸氮量,叶片增幅最大,平均增加51.86%,杂交籼稻增幅最大;FACE处理显著提高了不同生育阶段吸氮量,抽穗-成熟阶段增幅最大,平均增加108.90%,杂交籼稻增幅最大;5)植株干物质量、单穗吸氮量、吸氮强度、穗吸氮量、抽穗-成熟阶段吸氮量对成熟期总吸氮量的促进作用分别大于植株含氮率、单位面积穗数、生育天数、茎鞘叶吸氮量、移栽-分蘖和分蘖-抽穗阶段吸氮量;6)FACE处理显著提高了氮肥偏生产力,降低了每百千克籽粒需氮量,前者平均增加24.16%,常规籼稻增加最多;后者平均降低4.7%,常规籼稻降幅最大。结论 FACE处理可显著提高水稻产量和氮素吸收利用效率,但品种间差异较大。  相似文献   

8.
To study the sensitivity of inter-subspecific hybrid rice to climatic conditions, the spikelet fertilized rate (SFR) of four types of rice including indica-japonica hybrid, intermediate hybrid, indica and japonica were analyzed during 2000-2004. The inter-subspecific hybrids showed lower SFR, and much higher fluctuation under various climatic conditions than indica and japonica rice, showing the inter-subspecific hybrids were sensitive to ecological conditions. Among 12 climatic factors, the key factor affecting rice SFR was temperature, with the most significant factor being the average temperature of the seven days around panicle flowering (T7). A regressive equation of SFR-temperature by T7, and a comprehensive synthetic model by four important temperature indices were put forward. The optimum temperature for inter-subspecific hybrids was estimated to be 26.1-26.6℃, and lower limit of safe temperature to be 22.5-23.3℃ for panicle flowering, showing higher by averagely 0.5℃ and 1.7℃, respectively, to be compared with indica and japonica rice. This suggested that inter-subspecific hybrids require proper climatic conditions. During panicle flowering, the suitable daily average temperature was 23.3-29.0℃, with the fittest one at 26.1-26.6℃. For an application example, optimum heading season for inter-subspecific hybrids in key rice growing areas in China was as same as common pure lines, while inferior limit for safe date of heading was about a ten-day period earlier than those of common pure lines.  相似文献   

9.
【目的】研究秸秆还田与水氮配施的理论与技术,探讨对水稻群体质量和产量形成的影响。【方法】选用宜香优2115为试验材料,三因素裂裂区设计,主区为油菜秸秆堆腐还田和直接还田两种秸秆还田方式,裂区为淹水灌溉和控制性交替灌溉两种水分管理方式,裂裂区为4种施氮量,分析对水稻群体质量及产量的影响,并探讨秸秆还田与水氮管理模式下群体质量和产量形成的关系。【结果】秸秆还田与水氮管理对主要生育时期水稻干物质积累量、叶面积指数(LAI)及产量均存在显著或极显著的调控效应,互作效应显著;且群体质量指标与产量呈显著或极显著正相关。秸秆堆腐还田对水稻群体质量指标的调控显著高于秸秆直接还田,齐穗期高效叶面积指数提高了4.71%~6.50%,群体干物质显著增加了9.22%~13.30%;并对水稻产量及其构成因素影响显著,有效穗数及每穗粒数分别提高了5.9%~9.8%和1.5%~5.2%,从而使产量提高了9.5%~13.4%。控制性交替灌溉相对于淹灌能保证足够的穗数,提高干物质积累量,减缓拔节至齐穗期叶面积衰减,加快结实期群体生长率,利于穗粒数及产量的提高;且随着氮肥用量的增加,分蘖数、干物质积累量、有效叶面积率和高效叶面积率均呈先增后降的趋势。【结论】从三因素间的互作效应来看,秸秆堆腐还田处理下,控制性交替灌溉与施氮量150 kg/hm^2,可有效提高齐穂期高效叶面积指数(4.80~5.32),具有较高的结实期干物质积累量(6.94~7.36t/hm^2),显著提高了有效穗(181.6万~220.9万/hm^2)及每穗粒数(180~200粒),从而显著提高产量达到10328.1~12464.1 kg/hm^2,为本研究节水减氮增效最佳的处理。  相似文献   

10.

Background

Heat-tolerant rice cultivars have been developed as a countermeasure to poor grain appearance quality under high temperatures. Recent studies showed that elevated CO2 concentrations (E-[CO2]) also reduce grain quality. To determine whether heat-tolerant cultivars also tolerate E-[CO2], we conducted a free-air CO2 enrichment (FACE) experiment with 12 rice cultivars differing in heat tolerance.

Results

The percentage of undamaged grains of five standard cultivars (Akitakomachi, Kinuhikari, Koshihikari, Matsuribare, Nipponbare) averaged 61.7% in the ambient [CO2] (AMB) plot and 51.7% in the FACE plot, whereas that of heat-tolerant cultivars (Eminokizuna, Wa2398, Kanto 257, Toyama 80, Mineharuka, Kanto 259, Saikai 290) averaged 73.5% in AMB and 71.3% in FACE. This resulted in a significant [CO2] by cultivar interaction. The percentage of white-base or white-back grains increased from 8.4% in AMB to 17.1% in FACE in the sensitive cultivars, but from only 2.1% in AMB to only 4.4% in FACE in the heat-tolerant cultivars.

Conclusion

Heat-tolerant cultivars retained their grain appearance quality at E-[CO2] under present air temperatures. Further improvements in appearance quality under present conditions will be needed to achieve improvements under E-[CO2], because E-[CO2] will likely lower the threshold temperature for heat stress.  相似文献   

11.
The increase in atmospheric CO2 concentration [CO2] has been demonstrated to stimulate growth of C3 crops. Although barley is one of the important cereals of the world, little information exists about the effect of elevated [CO2] on grain yield of this crop, and realistic data from field experiments are lacking. Therefore, winter barley was grown within a crop rotation over two rotation cycles (2000 and 2003) at present and elevated [CO2](375 ppm and 550 ppm) and at two levels of nitrogen supply (adequate (N2): 262 kg ha−1 in 1st year and 179 kg ha−1 in 2nd year) and 50% of adequate (N1)). The experiments were carried out in a free air CO2 enrichment (FACE) system in Braunschweig, Germany. The reduction in nitrogen supply decreased seasonal radiation absorption of the green canopy under ambient [CO2] by 23%, while CO2 enrichment had a positive effect under low nitrogen (+8%). Radiation use efficiency was increased by CO2 elevation under both N levels (+12%). The CO2 effect on final above ground biomass was similar for both nitrogen treatments (N1: +16%; N2: +13%). CO2 enrichment did not affect leaf biomass, but increased ear and stem biomass. In addition, final stem dry weight was higher under low (+27%) than under high nitrogen (+13%). Similar findings were obtained for the amount of stem reserves available during grain filling. Relative CO2 response of grain yield was independent of nitrogen supply (N1: +13%; N2: +12%). The positive CO2 effect on grain yield was primarily due to a higher grain number, while changes of individual grain weight were small. This corresponds to the findings that under low nitrogen grain growth was unaffected by CO2 and that under adequate nitrogen the positive effect on grain filling rate was counterbalanced by shortening of grain filling duration.  相似文献   

12.
Increasing global atmospheric CO2 concentrations are expected to influence crop production. To investigate the effect on rice (Oryza sativa L.), plants were grown under ambient CO2 (AMB) or free-air CO2-enrichment (FACE) at CO2 concentrations ranged from 275 to 365 μmol mol−1 above AMB. We supplied 13CO2 to the plants at different growth stages so we could examine the contribution of carbohydrate stored during the vegetative stage or newly fixed carbohydrate produced during the grain-filling stage to ear weight at grain maturity. In plants supplied with 13C at the panicle-initiation or pre-heading stages, plants grown under FACE had more starch in the stems at heading, but there was no difference in stem 13C content. Furthermore, there were no differences between treatments in whole-plant 13C contents at heading and grain maturity. In contrast, plants supplied with 13C at the grain-filling stage had more 13C in the whole plant and the ears at grain maturity under FACE than under AMB, indicating that the increased amount of photosynthate produced at the grain-filling stage under CO2 enrichment might be effectively stored in the grains. Furthermore, regardless of when the 13C was supplied, plants had more 13C in starch in the ears at grain maturity under FACE than under AMB. Therefore, CO2 enrichment appears to promote partitioning of photosynthate produced during both vegetative and grain-filling stages to the grains.  相似文献   

13.
杂交水稻始穗期氮钾营养对剑叶生理特性的影响   总被引:13,自引:0,他引:13  
 采用盆栽试验研究了杂交水稻汕优63在施基肥的基础上,始穗期供给 NK营养对剑叶生理特性的影响。施用NK,可促进剑叶叶绿素含量、光合速率、蔗糖磷酸合成酶(SPS)、过氧化物酶(POX)、超氧物歧化酶(SOD)、硝酸还原酶(NR)活性提高,呼吸速率下降,增加剑叶的可溶性糖和可溶性蛋白含量及根系活力,加速14C同化物从剑叶的输出,提高14C同化物在稻穗的分布积累及输入积(IAP)。讨论了始穗期共施NK营养提高结实率、谷粒充实度及稻谷产量的良好效果  相似文献   

14.
水稻灌浆期源质量与产量关系及氮素调控的研究   总被引:33,自引:2,他引:31  
以中粳稻武育粳3 号和杂交中籼稻汕优63 为材料, 采用不同密度、施肥等栽培措施, 形成成穗率不同的群体, 研究水稻抽穗期源质量与产量关系及其影响因素。结果表明: 水稻高产群体抽穗期叶面积指数(LAI) 适宜, 有效叶面积率高, 高效叶面积率为75%~80% , 灌浆期光合势在2. 10×10 6 m2·d 以上, 势粒比在47 cm2·d 粒以上。势粒比(光合势与总颖花量的比值) 能反映抽穗后群体源库发展动态的优劣, 是经济产量形成期源库质量的较好表述。本试验条件下, 通过穗肥等措施,在抽穗期适宜叶面积基础上, 降低抽穗后叶面积下降速率, 提高光合势和势粒比是进一步提高产量的有效途径。  相似文献   

15.
SUMMARY

Increasing atmospheric CO2 concentrations [CO2] have the potential to enhance growth and yield of agricultural plants. Con-comitantly plants grown under high [CO2] show significant changes of the chemical composition of their foliage and of other plant parts. Particularly, high [CO2] result in a decrease of plant nitrogen (N) concentration, which may have serious consequences for crop quality. This presentation summarizes the results of a variety of CO2 enrichment studies with pasture plants (Lolium spp., Trifolium repens) and cereal species (Triticum aestivum, Hordeum vulgare) which were conducted at our laboratory under different growth and CO2 exposure conditions ranging from controlled environment studies to investigations under free air carbon dioxide enrichment (FACE). With the exception of clover in all experiments a CO2-induced decline of forage and grain N concentration was observed. The magnitude of this reduction differed between species, cultivars, management conditions (N fertilization) and CO2 exposure conditions. No unambiguous evidence was obtained whether N fertilization can contribute to meet the quality requirements for cereals and grass monocultures with respect to tissue N concentrations in a future high-CO2 world. As shown in the FACE experiments current application rates of N fertilizers are inadequate to achieve quality standards.  相似文献   

16.
淹涝胁迫对杂交中稻生长特性及产量形成的影响   总被引:1,自引:0,他引:1  
以近年审定的20个杂交中稻品种为材料,研究了分蘖期和抽穗期淹涝胁迫对杂交中稻的某些生理指标、生长发育、产量及干物质生产的影响。结果表明:(1)淹没胁迫对杂交中稻的生育期有显著影响。分蘖期受淹没胁迫,头季稻和再生稻的抽穗期分别平均延长了3.25 d和3.95 d,成熟期分别平均延长了1.85 d和2.75 d;而抽穗期受淹没胁迫,成熟期会提前,平均提前1.60 d,且品种间差异较大。(2)淹没胁迫对杂交中稻的产量有显著影响。与对照相比,分蘖期受淹没胁迫,分蘖期叶干重、有效穗数、每穗粒数降低,使其平均减产59.0%;齐穗期受淹没胁迫,每穗粒数和结实率显著降低,使其平均减产57.6%。(3)分蘖期受淹没48 h后,不宜割苗蓄留再生稻,应以加强田间管理保留头季稻为主,耐淹性较强的品种有川谷优6684、冈优169和乐优198;抽穗期受淹没48 h后,则以割苗蓄留再生稻较佳,其中冈优169、内5优317、蓉优22和川谷优6684的产量较高。(4)分蘖期和抽穗期耐淹组合间没有相关性,生产上应分别在各时期筛选相应耐淹能力较强的品种。  相似文献   

17.
以大穗型杂交中稻蓉18优1015和多穗型杂交中稻内6优103为材料,于2018年在四川泸县开展试验,研究稻鱼共生模式下不同施氮量(N0,不施氮;N1,减氮66.6%;N2,减氮33.3%;CK,常规施氮,施氮量135 kg/hm^2)对杂交中稻产量、产量构成因子、干物质、收获指数、氮肥利用率的影响。结果表明,大穗型杂交中稻产量以N2处理最高,较CK增加2.8%;多穗型杂交中稻产量以CK最高,较N2、N1处理分别增加5.3%、20.4%;随施氮量的增加,杂交中稻有效穗数、干物质量呈显著增加的趋势,结实率、收获指数则呈下降趋势,减量施氮对杂交中稻每穗粒数和千粒重影响不显著;大穗型杂交中稻的氮肥农学利用率N2、N1处理较CK分别增加63.2%、45.6%,多穗型杂交中稻氮肥农学利用率N2处理较CK增加了27.4%;随施氮量的增加,杂交中稻氮肥偏生产力呈显著下降趋势,与CK相比,N2、N1处理的氮肥偏生产力分别增加了74.6%和48.2%。可见,在稻田养鱼模式下,综合考虑产量和氮肥利用率,杂交中稻的适宜减氮量为33.3%。  相似文献   

18.
亚种间杂交水稻协优413开花灌浆特性的比较研究   总被引:5,自引:3,他引:5  
 以盆栽试验对亚种间杂交水稻协优413、其父本中413和籼型杂交水稻汕优10号的开花灌浆特性进行了比较研究。结果表明中413单穗籽粒总干物重最高,协优413次之,汕优10号最低,分别为4652.5、4173.9和3194.4 mg,结实率中413和协优413相近,分别为80.8%和83.9%,显著高于汕优10号的70.5%。单穗产量的差异与组合(恢复系)的开花灌浆特性有关,即与单穗颖花开花集中程度和强弱势粒灌浆结实的差异程度有关。对于供试的3个品种(或组合)而言,颖花开花越集中,强弱势粒灌浆结实差异越小,产量越高。还对单穗颖花开花历时作为今后亚种间杂交水稻的育种目标进行了讨论。  相似文献   

19.
《Plant Production Science》2013,16(3):203-210
Summary

Generally F1 hybrids from crosses between japonica and indica rice show variable degrees of sterility. Previous studies revealed that among the indica rice, the Aus type has sexual affinity with japonica cultivars giving higher fertility in F1 hybrids. Therefore, we made an effort to obtain higher grain yield by producing F1 hybrids between japonica and Aus-type indica. A field experiment was conducted to investigate the heterosis in these F1 hybrids for dry matter accumulation, spikelet fertility, yield and yield attributes, to find cross combinations with higher grain yield, and examined the relationships of grain yield with some agronomic characters. F1 hybrids flowered earlier than their parent cultivars. Heterosis for dry matter accumulation was positive at the panicle initiation stage, at heading and at maturity. The average heterosis for number of panicles, grain and straw yield per plant, number of spikelets per panicle and 1000-grain weight was positive. A few F1 hybrids showed positive heterosis for number of filled grains per panicle, spikelet fertility and harvest index; but the average heterosis for these traits was negative. Among the yield components, a higher number of panicles per plant and higher number of spikelet per panicle contributed to higher grain yield in F1 hybrids. A significant and positive relationship existed between spikelet fertility and grain yield per plant. The higher grain yield was attributed to higher dry matter production rather than higher harvest index in F1 hybrids, although low spikelet fertility limited yield potential in some F1 hybrids.  相似文献   

20.
在田间和盆栽条件下研究了穗肥氮施用比例对两系杂交水稻氮素吸收、籽粒氨基酸含量和产量的影响。两系杂交早稻施N 180 kg/hm2,30%作穗肥、70%作基肥的稻谷产量最高,比施N 180 kg/hm2 10%作穗肥和施N 120 kg/hm2 30%作穗肥两个处理均增产6.2%。晚稻在施N 210 kg/hm2条件下,仍以30%作穗肥处理的稻谷产量最高。3个施氮量平均,氮肥利用率和农学效率均表现为30%作穗肥>20%作穗肥>10%作穗肥,氮肥利用效率表现为30%作穗肥<20%作穗肥<10%作穗肥。与其他氮素穗肥比例处理比较,氮肥30%作穗肥、70%作基蘖肥的分配方案能提高稻米必需氨基酸含量0.09~0.38个百分点,其中又以亮氨酸和异亮氨酸增加较多,赖氨酸次之;且稻米产量、总氨基酸积累量和必需氨基酸积累量分别增加5.4%~27.5%、5.4%~30.4%、15.1%~36.0%。  相似文献   

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