Effects of Soil Moisture Conditions before Heading on Growth of Wheat Plants under Drought Conditions in the Ripening Stage: Insufficient Soil Moisture Conditions before Heading Render Wheat Plants More Resistant to Drought during Ripening

Abstract

Plants growing on soil with insufficient moisture need deep and dense roots to avoid water stress. In crop plants, the production of dry matter during ripening of grains is critically important for grain yield. We postulated that shoot growth would be suppressed but root growth would continue under an insufficient soil moisture condition before heading, while shoot growth would be more vigorous than root growth under a sufficient soil moisture condition. We anticipated that the plants growing under an insufficient soil moisture condition before heading would produce more dry matter and grain under an insufficient soil moisture condition during ripening. In order to examine our hypotheses and to determine the fundamental conditions for improving grain yield and efficient use of irrigated water under limited irrigation, we grew wheat plants (Triticum aestivum L., cv. Ayahikari) in pots (30 cm in diameter, 150 cm in height) with insufficient soil moisture (PD-D pots) or sufficient soil moisture (PW-D pots) for six weeks before heading followed by full irrigation, and then insufficient soil moisture condition during ripening. The growth of shoots was suppressed significantly but that of roots was not before heading in PD-D plants, with a higher resultant ratio of root to shoot than in PW-D plants. The former retained a high leaf water potential and, therefore, were able to produce more dry matter and grain during soil moisture depletion during ripening as compared with the latter plants. We also obtained similar results with field-grown plants.     

Effects of Soil Type,Vertical Root Distribution and Precipitation on Grain Yield of Winter Wheat

Abstract

In Abashiri in eastern Hokkaido, Japan, grain yields of winter wheat (Triticum aestivum L. cv. Hokushin) in the western area, with umbric andosol or dystric cambisol soil types, are lower and unstable compared to those in the eastern area, with mostly haplic andosol soil type. The aim of this study was to evaluate yield differences between the eastern and western areas. The vertical root distribution of wheat plants was examined over two seasons in farmers’ fields in both areas by a wall profile method. Plants grown in the western area had shallower root systems than those grown in the eastern area. Poor soil porosity and high soil penetration resistance suppressed the vertical distribution of root systems in umbric andosol and dystric cambisol. Grain yields were not always correlated with the amount and distribution of the root system. Grain yield in the 2004/2005 season was not correlated with root depth index, whereas it was positively correlated in the 2005/2006 season. During the period from heading to maturity (mid June to late July) over the two seasons, grain yield was associated with precipitation more than with temperature and total solar radiation. In the 2005/2006 season, during the late growing stage of wheat, precipitation was extremely low and soils were very dry. The difference in grain yield between the eastern and western areas was significant and negatively related to precipitation during the period from heading to maturity. Significant correlations of yield with sunshine duration and solar radiation from the heading stage to maturity were observed only on haplic andosol. The results suggest that the major factor controlling yearly changes in the difference in grain yield of winter wheat between the eastern and western areas is the difference in photosynthetic ability, which is based on rooting depth and water supply in response to solar radiation during the late growing stage.     

Performance of a High-Yielding Modern Rice Cultivar Takanari and Several Old and New Cultivars Grown with and without Chemical Fertilizer in a Submerged Paddy Field

Abstract

A high nitrogen-uptake capacity and effective use of absorbed nitrogen for dry matter and grain production are required to improve the production cost and environmental pollution. We characterized grain yield, dry matter production and nitrogen accumulation in six rice cultivars: Sekitori (released in 1848) and Aikoku (1882), referred to as SA cultivars hereafter; Koshihikari (1956); Nipponbare (1963) and Asanohikari (1987), referred to as NA cultivars hereafter; and Takanari (in 1990) as a high-yielding modern cultivar. The plants were grown with and without chemical fertilizer in a submerged paddy field. When plants were supplied with manure and chemical fertilizer, Takanari consistently produced the heaviest grain and dry matter, followed by the NA cultivars, and the SA cultivars the lightest. Dry matter production before heading was greater in Takanari and the NA cultivars due to the longer duration of vegetative growth. Dry matter production after heading was greatest in Takanari, with a larger crop growth rate (CGR), and smallest in the SA cultivars with a shorter ripening time. Greater dry matter production during ripening was accompanied by the greater accumulation of nitrogen by Takanari and NA cultivars. These plants developed a larger amount of roots. The smaller light extinction coefficient of the canopy was also attributed to the higher CGR in Takanari. When plants were grown without chemical fertilizer, Takanari also produced heavier grain and dry matter, followed by the NA cultivars. The heavier grain in these cultivars resulted from the greater dry matter production before heading, which was due to the longer period of vegetative growth. The greater dry matter production and nitrogen accumulation by Takanari and NA cultivars were evident when plants were grown with chemical fertilizer. Koshihikari was characterized by a higher CGR and greater nitrogen accumulation during ripening in the absence of chemical fertilizer which should be noted in efforts to decrease rates of nitrogen application.     

Effects of Pre-Flowering Soil Moisture Deficits on Dry Matter Production and Ecophysiological Characteristics in Soybean Plants under Well Irrigated Conditions during Grain Filling

Summary

Summer field crop plants in Japan would develop large shoots but poor root systems during the rainy season called “Baiu”. This might have adverse effects on dry matter production in summer thereafter even when they grow under sufficient soil moisture conditions. The effects of pre-flowering soil moisture conditions on dry matter production and ecophysiological characteristics were investigated.

Soybean plants were grown under sufficient (W plot) and deficient (D plot) soil moisture before flowering in the field. Under sufficient soil moisture conditions after flowering, the plants in the D plot produced higher dry matter due to higher net assimilation rate (NAR) and higher grain yield due to higher pod-flower set ratio and a heavier seed than in the W plot. The higher NAR in the D plot was attributed to (1) a lower resistance to water transport in plants, which is necessary to maintain a high leaf water potential and high photosynthetic rate during the daytime and (2) delayed senescence. The plants in the D plot had a well developed root system, and had roots with high physiological activity represented by a large amount of exudation from the basal cut end of the stem. The development of physiological activity of the root system maybe reflected in higher capacity of root functions, the higher pod-flower set ratio and the delay in the senescence. Improved cultivation practices such as drainage during the rainy season and breeding of the plants with well-developed root system during the rainy season may be necessary to increase the yield of summer crops in Japan. Irrigation during the summer may not be so effective for the plants with a poorly developed root system.     

Analysis of yield-attributing traits for high-yielding wheat lines in southwestern Japan

Development of wheat cultivars that achieve high yields despite the short growing season is essential for increasing wheat production in southwestern Japan. The objectives of this study were to assess the genetic progress in grain yield and to clarify yield-attributing traits of high-yielding wheat lines in southwestern Japan. We conducted field experiments for two growing seasons (2012–2013 and 2013–2014) using three commercial wheat cultivars (Shiroganekomugi, Chikugoizumi, and Iwainodaichi) and four high-yielding wheat lines including Hakei W1380 developed in southwestern Japan. In an ancillary field experiment, we compared a commercial cultivar, Shiroganekomugi, and a high-yielding line, Hakei W1380, in the 2014–2015 season. Across the two seasons, grain yield of high-yielding lines was generally higher than commercial cultivars. Hakei W1380 achieved the highest grain yield across the two seasons, and successfully produced more than 900 g m^?2 in the 2013–2014 season. Correlation analysis showed that recent yield progress of wheat lines in southwestern Japan was derived from enhanced biomass production and grain number m^?2. Larger numbers of grains m^?2 in high-yielding lines than in commercial cultivars were associated with higher crop growth rate at the pre-anthesis stage, and therefore higher spike dry weight m^?2 at anthesis. Genotypic differences in crop growth rate from jointing to anthesis resulted mainly from differences in leaf area index. These results indicate that further improvements in grain yield in southwestern Japan could be achieved by increasing the amount of radiation intercepted at the pre-anthesis stage and grain number m^?2.     

土壤干旱对小麦生理性状和产量的影响

为探讨土壤干旱对小麦产量的影响及其生理基础,以高产小麦品种扬麦16和宁麦13为材料进行盆栽,自分蘖末期至成熟设置正常供水(WW)、土壤轻度干旱(MD)和土壤重度干旱(SD)3种处理,研究其对小麦根系和地上部分生理性状的影响。结果表明,与WW相比,MD处理显著提高了各生育期的根系氧化力、根系及籽粒中玉米素+玉米素核苷(Z+ZR)的含量、花后干物质积累量及茎鞘中非结构性碳水化合物(NSC)的运转量;根冠比、叶片光合速率及叶片中Z+ZR的含量在WW和MD处理间无显著差异;SD处理则降低了产量和植株生理活性。MD处理显著提高了穗粒数、粒重和产量,SD处理的结果则相反;穗数随土壤干旱程度的加重而降低。两个品种的结果趋势相同。相关分析表明,根系氧化力、根系和籽粒中Z+ZR含量、花后干物质积累量及NSC运转量与籽粒灌浆速率、千粒重和产量呈极显著正相关。表明土壤轻度干旱可提高小麦根系生理活性并促进光合同化物向籽粒的转运,进而增加产量。     

Poor grain filling induced by waterlogging is similar to that in abnormal early ripening in wheat in Western Japan

Abnormal early ripening (AER), a major constraint on wheat production in Western Japan, manifests as sudden leaf senescence shortly after anthesis and results in poor grain filling; this leads to smaller grains and reduced grain yield. It is suggested that overwetting of the soil may be related to AER. We conducted field experiments over 2 seasons (2008-2009 and 2009-2010) in Yamaguchi, Western Japan, with waterlogging treatment using 2 Japanese wheat cultivars, Daichinominori (Western Japanese cultivar) and Haruyutaka (Hokkaido cultivar), which differ in terms of grain growth in the environment of Western Japan. We imposed pre-anthesis waterlogging for 2 weeks in 2008-2009 and post-anthesis waterlogging throughout the grain-filling period in 2009-2010. Pre-anthesis waterlogging had no significant effect on grain yield or grain filling irrespective of cultivar. Post-anthesis waterlogging severely reduced the grain yield by 44% and 36% in Haruyutaka and Daichinominori, respectively. The yield loss was attributable to the smaller grain weight that was a result of slower grain growth rate later in the shortened grain-filling period. Post-anthesis waterlogging induced sudden leaf senescence 1 and 2 weeks after anthesis in Haruyutaka and Daichinominori, respectively, and drastically reduced the photosynthesis and ultimately dry mass accumulation. It also depressed the remobilization of water-soluble carbohydrates (WSCs) from culms to grains leaving more residual WSCs in the culms at harvest (149 and 65 mg g⁻¹ DW in waterlogging and controls, respectively). The results indicate that the reduced grain growth due to waterlogging was attributable to decreased current assimilation and poor remobilization of culm WSCs to grain similar to that in AER plants. These results suggest that injured root function after anthesis might induce early leaf senescence and poor grain filling similar to AER wheat.     

播期对秸秆带状覆盖下冬小麦干物质积累、产量及水分利用效率的影响

为明确半干旱雨养区玉米秸秆带状覆盖条件下播种时间对小麦产量和水分利用效率可能带来的影响,在甘肃省通渭县常河镇甘肃农业大学旱作小麦试验基地设7个播期处理,分别为9月14日(T1)、9月19日(T2)、9月24日(T3)、9月29日(T4)、10月4日(T5)、10月9日(T6),以9月24日露地种植为对照(CK),研究了播期对冬小麦生育期、干物质积累及产量等性状的影响。结果表明,T2处理的产量和WUE最高,穗粒数和千粒重也显著高于其他处理。推迟播期缩短了冬小麦全生育其天数,各生育阶段天数抽穗前大于抽穗后;播期对植株干物质积累的影响表现为营养生长期大于生殖生长期,花前干物质向籽粒的转运量及其对籽粒的贡献率随播期推迟呈增加的趋势。综合来看,在半干旱雨养区玉米秸秆带状覆盖条件下9月19日是冬小麦最佳播期。     

Analysis of High Yielding Ability in a Rice Cultivar Akisayaka

Abstract

The yielding ability of a new rice cultivar Akisayaka was compared with that of a standard rice cultivar Yumehikari. The refined grain yield was 9% larger in Akisayaka than in Yumehikari since Akisayaka had more panicles and spikelets per unit area but had a similar percentage of ripened grain. Although the leaf area index (LAI) in Akisayaka was similar to that in Yumehikari, the leaf area of the flag leaf per unit area of Akisayaka was smaller than that of Yumehikari at the full heading stage. This indicates that Akisayaka had a larger number of smaller upper leaves than Yumehikari. The refined grain weight of Akisayaka was similar to that of Yumehikari at 30 days after heading. This implies that the plant type of Akisayaka is not so important for increasing dry matter production from early to middle ripening period although small upper leaves seems to suppress overluxuriant growth. Accordingly the most important factor for the high yield of Akisayaka was considered to exist in the late ripening stage. The refined grain weight of Akisayaka increased more rapidly than that of Yumehikari from 30 to 45 days after heading. In addition, the leaf chlorophyll content estimated with chlorophyll meter (SPAD) and top dry weight of Akisayaka exceeded those of Yumehikari at the late ripening stage. These results suggest that the large number of spikelets per unit area and the continuation of sink and source ability during the late ripening stage caused the high yielding ability of Akisayaka.     

不同土壤肥力麦田小麦干物质生产和产量的差异

为明确不同土壤肥力下小麦干物质生产和产量的差异,于2019-2020年小麦生长季,选择了产量潜力分别为10 500 kg·hm^-2和9 000 kg·hm^-2的超高产土壤肥力和高产土壤肥力两种麦田,以济麦22为材料,比较分析了不同土壤肥力麦田小麦的群体动态、干物质生产、籽粒灌浆特性、穗部特征和产量构成的差异。结果表明,与高产土壤肥力相比,超高产土壤肥力增加了小麦拔节至成熟期的干物质积累量及成熟期干物质在籽粒中的分配量,促进了小麦开花前营养器官储存同化物在开花后向籽粒的转运量和开花后的光合物质同化量,提高了收获指数;超高产土壤肥力使籽粒在灌浆中后期维持较高的灌浆速率,延长了活跃灌浆期,提高了粒重。超高产土壤肥力通过增加单位面积的穗数和千粒重,实现小麦高产。     

谷物水分仪直测水稻干湿谷试验比较

在水稻收割机收获后,抽取样品稻谷,按毛湿谷、净湿谷、净燥谷分别称重、测水分,获得对比数据。结果表明,应用PM-8188New型谷物水分测量仪进行毛鲜湿谷直测比干燥处理后的净谷再测,稻谷折干率及标准水分产量明显偏高,在本试验条件下,折干率平均偏高2.8个百分点,相应的单产偏高3.3%。     

播种期补灌对土壤含水量和小麦籽粒产量的影响

为明确播种期0~200 cm土体贮水量及其纵向分布对小麦出苗、群体发育和籽粒产量的调节作用,于2013-2014年度小麦生长季,在土壤容重、田间持水量和肥力条件一致,而小麦播前土壤贮水量不同的A、B两个地块,在播种期设置不同的计划湿润层深度和目标土壤含水量进行补灌。结果表明,在地块A和地块B 0~100 cm土层土壤贮水量分别为201.5和266.3 mm、0~200 cm土层土壤贮水量分别为554.2和586.4 mm的条件下,播种期补灌,土壤水分平衡后,灌溉水在地块B下渗的深度较大,但主要集中在60 cm以上土层,其中0~10和0~20 cm土层土壤含水量提高的幅度最大;小麦出苗率主要受播种期0~10 cm土层土壤含水量的影响,而群体发育、干物质积累和产量形成则受播前土壤贮水量和播种期补灌水平的共同影响。播种期上部土层土壤含水量过低不利于幼苗发育,显著减少越冬至拔节期间的单位面积茎数。播种前0~100 cm土层土壤贮水量过低,即使播种期在一定范围内增加补灌水量,并于拔节期和开花期再补灌,仍会制约小麦生育中后期的生长,导致成穗数和干物质积累量减少,产量降低。在同一底墒条件下,小麦总耗水量和籽粒产量均随播种期补灌目标土壤相对含水量的提高呈增加趋势,但补灌水量过多,籽粒产量不再增加,水分利用效率降低。     

水分管理对免耕抛秧水稻根系生长及产量的影响

研究了水分管理对免耕水稻根系生长和产量的影响。结果表明,干湿交替灌溉对根系的伸长、生长、生理及分布具有较大影响,水稻各生育期干湿交替灌溉处理水稻单株根干质量、单株生物量、根半径、根表面积、总根数、根系活力、超氧化物歧化酶活性均显著高于淹水淹灌。干湿交替灌溉处理实收产量显著高于淹水淹灌,增产主要因子是有效穗数、每穗粒数和结实率。灌浆盛期干湿交替灌溉处理单株生物量、根半径、根表面积、总根数、超氧化物歧化酶活性均显著高于湿润淹灌,水稻产量差异则不显著。     

长江中下游稻区双季晚粳稻产量生理与资源利用效率研究进展

长江中下游稻区是我国水稻主产区,同时又是单、双季稻混作区。目前,随着经济发展和人民生活水平的提高,人们对优质大米,尤其是优质粳米的需求日益增加,因此,在双季稻生产中引入粳稻具有重要的现实意义。本文介绍了长江中下游双季稻的温光资源特性,总结了现有双季晚(籼/粳)稻品种的种植表现,从产量、产量结构、干物质积累、群体动态、生育期、温光利用率、稻米品质等方面比较了长江中下游稻区晚粳与晚籼的可能差异。总体来说,双季晚粳在产量、每穗粒数、结实率、千粒重等方面均显著高于晚籼;前期干物质积累两者无显著差异,但是后期干物质积累量晚粳要高于晚籼,晚粳的灌浆率显著高于晚籼,这预示着双季晚粳具有更高的产量潜力。粳稻比籼稻有着较平稳的茎蘖动态,这使其具有更强的后期光合能力、更高的后期光能利用率;全生育期晚粳比晚籼长,主要体现在推迟抽穗结实,延长结实灌浆期;粳稻全生育期积温和光照时数均显著高于籼稻,粳稻后期叶面积指数大于籼稻,光合势亦高于籼稻,而在生育前期(拔节至抽穗期)两者对温光资源的利用基本相当,因此温光利用率晚粳显著高于晚籼;另外,晚粳的稻米品质要优于晚籼。因此,相对于双季晚籼,双季晚粳具有更高的应用推广价值。     

秸秆带状覆盖对旱地冬小麦产量及土壤水分的影响

为探讨西北半干旱雨养条件下秸秆带状覆盖麦田水分利用特征和增产效果,通过田间试验,以露地条播为对照(CK),研究了3种不同覆盖处理[秸秆带状覆盖常规条播(SM1)、秸秆带状覆盖宽幅条播(SM2)和全膜覆土穴播(PM)]对旱地冬小麦田土壤含水量、小麦产量和水分利用效率的影响。结果表明,秸秆带状覆盖和全膜覆土穴播均可显著改善小麦全生育期0~20cm以及开花前20~90cm土壤墒情,但开花后20~90cm以及全生育期90~200cm土壤墒情普遍不如CK。3种覆盖处理均能促进冬小麦对土壤贮水的利用,显著提高开花至成熟阶段的耗水量及其占总耗水量的比例。秸秆带状覆盖和全膜覆土穴播生育期耗水量分别比CK增加4.6%和7.6%。秸秆带状覆盖在孕穗前0~200cm土壤墒情与全膜覆土穴播无显著差异,孕穗期开始则好于全膜覆土穴播;全膜覆土穴播0~200cm土壤贮水消耗量显著高于秸秆带状覆盖,而开花至成熟阶段的耗水量及其占总耗水量的比例则略低于秸秆带状覆盖。3种覆盖处理均显著提高产量和水分利用效率,PM、SM1和SM2较CK分别增产36.8%、29.7%和27.5%,水分利用效率分别提高27.3%、23.9%和22.7%。产量与生育期耗水量呈显著正相关(r=0.97*)。覆盖处理中,全膜覆土穴播产量虽最高,但从产量、水分利用效率和经济效益角度综合考虑,秸秆带状覆盖优于全膜覆土穴播。因此认为,秸秆带状覆盖是一种更加高产高效、适宜在西北半干旱雨养区推广的覆盖种植方式。     

Effect of lowering the root/shoot ratio by pruning roots on water use efficiency and grain yield of winter wheat

A pot and a field experiment were conducted to assess the effects of root/shoot ratio (R/S) on the water use efficiency (WUE) and grain yield of winter wheat. The R/S was regulated by pruning the roots during the stem elongation stage, resulting in reduced root systems of the plants. At the heading stage, the root dry weight of root-pruned plants was less than that of intact-root plants, but their R/S was similar to that of intact-root plants under both experimental conditions. After tiller pruning, the R/S of root-pruned plants was significantly lower than that of intact-root plants (p < 0.05). Root pruning reduced the rate of leaf transpiration and lowered the number of tillers per plant (p < 0.05) during the vegetative stage. As a result, root-pruned wheat showed reduced water use when compared to intact-root plants before heading (p < 0.05). At anthesis, there was no significant difference in transpiration between plants with intact roots and those with pruned roots in the pots. However, under field conditions, transpiration of root-pruned plants was significantly higher than that of intact-root plants at anthesis. Additionally, at anthesis root-pruned plants had a higher rate of leaf photosynthesis and lower rate of root respiration, which resulted in a significantly higher grain yield at maturity when compared to plants with intact roots. Under both experimental conditions, there were no significant differences in shoot dry weight per plant between root-pruned and intact-root plants grown in monoculture. When root-pruned plants were grown with intact-root plants, the root-pruned wheat was less productive and had a lower relative shoot dry weight (0.78 and 0.86, respectively) than the intact-root plants (1.24 and 1.16, respectively). These results suggest that plants with pruned roots had a lower ability to compete and to acquire and use the same resources in the mixture when compared with intact-root plants. Root pruning improved the WUE of winter wheat under both experimental conditions. This suggests that appropriate management for the root system/tillers in wheat crops can be used to increase grain yield and water use efficiency. Specifically, lowering the R/S improved the grain yield and WUE of winter wheat significantly by lowering its competitive ability and improving root efficiency. Therefore, drought-resistance breeding to improve the grain yield and WUE, at least for wheat, should be made by targeted selection of less competitive progeny with a small R/S for cultivation in arid and semiarid areas.     

B803A系列杂交水稻组合根系生长特性研究

以B803A所配4个杂交水稻组合与汕优63(CK)为材料,研究了不同生育时期的根系干重、根冠比、根系含水率和发根力变化及其与产量的关系。结果表明,B优系列组合各个生育时期的根系干重均大于汕优63,而根冠比却小于汕优63;抽穗期后的根系含水率及孕穗期的发根力均高于汕优63,说明B优系列组合生育后期的根系活性强于汕优63。对根系特性与产量的相关分析表明,水稻生育后期根系活性对产量的形成具有重要影响。     

小麦秸秆还田条件下轻简栽培水稻的生长特性

 以粳稻品种扬辐粳8号作试验材料,设小麦秸秆还田处理,以秸秆不还田作对照,进行直播、机械插秧、抛秧,并对水稻物质生产、产量形成及有关生理指标进行了分析。与秸秆不还田相比,秸秆还田处理穗数均有所下降,每穗粒数、结实率和千粒重均有所增加,产量均显著提高;各生育期的茎蘖数均明显降低。光合势、叶面积指数和干物质积累抽穗前低于秸秆不还田,抽穗后则相反;各生育期的根冠比均较高。抽穗期高效叶面积、高效叶比例以及粒叶比均较大,结实期茎鞘中贮存的碳水化合物的输出率及转换率以及收获指数明显大于秸秆不还田。结实期根系活力、伤流液、光合速率和ATP酶活性均高于秸秆不还田。阐明了秸秆还田轻简栽培水稻的生育特性和增产效应。同时,对秸秆还田水稻高产的生理原因进行了讨论,并提出秸秆还田水稻的关键调控技术。     

水稻-再生稻体系干物质积累及氮磷钾养分的吸收利用

【目的】 阐明水稻-再生稻体系的干物质积累及氮、磷、钾养分吸收利用规律,为其科学施肥提供理论依据。【方法】 通过2年的田间试验,以深两优5814为材料,在养分供应充足的条件下,于水稻关键生育期(分蘖期、幼穗分化期、孕穗期、齐穗期、灌浆期、完熟期)进行取样,测定各器官的干物质量及氮、磷、钾养分含量,计算养分积累量,研究头季稻和再生稻干物质积累和氮、磷、钾养分吸收积累动态及分配、转运规律。【结果】 头季稻总干物质积累量在整个生育期表现为“慢-快-慢”的增长趋势,茎、叶干物质快速积累期分别在分蘖-齐穗期和孕穗前,增长量分别占其最大积累量的81.1%和43.8%,且茎、叶的干物质积累量在灌浆-完熟期之间没有明显降低;从齐穗期至灌浆中期是穗的干物质快速积累期,在此期间增加的干物质积累量占总量的58.8%。再生稻的总干物质积累呈“S”形曲线,茎、叶的干物质积累量分别在灌浆期和齐穗期达到最大;头季稻桩的干物质积累量从头季收割后呈下降趋势。养分吸收结果显示,头季稻氮的总积累量以及茎、穗两个器官的氮素积累量的变化规律与其干物质积累量相似,磷和钾的总积累量在灌浆后期降低;茎和叶的各养分积累量分别在齐穗期和灌浆期达到最大。头季收获后,头季稻桩的氮、磷和钾养分积累量表现为下降的趋势,茎和叶的养分积累量先增加后减少,穗的养分积累量则表现为不断增加。从齐穗期到完熟期,各器官的氮转运量表现为叶>茎>头季稻桩,磷转运量表现为茎>头季稻桩>叶,钾转运量表现为头季稻桩>叶>茎。【结论】 头季稻孕穗期至灌浆中期是其干物质和养分的快速积累期,从头季收获至再生季齐穗期间是再生稻干物质及养分积累的关键时期,头季稻桩中的养分会在头季收获后转移至再生器官中。满足头季稻抽穗灌浆期间的养分需求,及时补充再生芽萌发生长期间的养分供应是水稻-再生稻体系高产的基础和保障。     

春、夏玉米物质生产及其对温光资源利用比较

比较了春玉米和夏玉米在产量和品质、干物质积累、光温气候资源的利用等方面的差异。结果表明:春玉米比夏玉米平均增产1600kg/hm²,前者的子粒粗蛋白含量也显著高于后者。春玉米的高生产力主要体现在干物质积累速率上,平均比夏玉米高15.8%,但年际间有一定的变异。春玉米对光温资源的占用率较高,但在光能利用率上并无明显优势。春玉米较高的产量潜力主要得益于营养生长期优越的光温条件以及较长的灌浆期;夏玉米灌浆期气候较适宜,但由于受冬小麦生育期的限制,产量潜力未得到充分发挥。