[Effects of irrigation regimes on photosynthesis, water use efficiency and grain yield in winter wheat]. / çŒæ°´æ¨¡å¼å¯¹å†¬å°éº¦å ‰åˆç‰¹æ€§ã€æ°´åˆ†åˆ©ç”¨æ•ˆçŽ‡å’Œäº§é‡çš„å½±å“.

The effects of different irrigation regimes on photosynthesis, plant growth, water use efficiency (WUE), and grain yield in winter wheat were examined in a common garden with rainout shelter during 2013-2014 and 2014-2015 growing seasons. The experiment consisted of two irrigation timings, jointing stage (J) and anthesis (F), and three irrigation levels, 0, 37.5 and 75 mm, which generated nine irrigation combinations, i.e. J0F0, J0F1, J0F2, J1F0, J1F1, J1F2, J2F0, J2F1 and J2F2. All plots received 75 mm irrigation at grain filling stage. The results showed that water stress at jointing stage significantly reduced leaf area after jointing stage and the net photosynthetic rate (Pn) at anthesis. Post-anthesis flag leaf Pn was significantly affected by irrigation at anthesis. Water stress at jointing stage followed irrigation at anthesis or that at anthesis followed irrigation at grain filling stage increased dry matter accumulation of wheat plants. Higher amount of irrigation at jointing stage led to higher water consumption in the entire growing period. High amount of irrigation during the entire growing period resulted in high water consumption and grain yield with an exception of J1F2 treatment. Among all the treatments, the J1F2 treatment had superior grain yield and WUE. Sufficient water supply at anthesis resulted in high flag leaf Pn after flowering in J1F2. Irrigation at anthesis for J1F2 enhanced wheat dry matter accumulation and kernel numbers per spike, and consequently high yield. Small amount of irrigation at jointing stage reduced wheat water consumption at middle and late growth stages. The wheat WUE in treatments with small amount of irrigation at jointing stage (J1F2) was higher than in other treatments. In this study, J1F2 was the best irrigation regime for winter wheat.

[Impact of temperature increment before the over-wintering period on growth and development and grain yield of winter wheat].

The effect of temperature increment before the over-wintering period on winter wheat development and grain yield was evaluated in an artificial climate chamber (TPG 1260, Australia) from 2010 to 2011. Winter wheat cultivar 'Zhengmai 7698' was used in this study. Three temperature increment treatments were involved in this study, i.e., temperature increment last 40, 50 and 60 days, respectively, before the over-wintering period. Control was not treated by temperature increment. The results showed that temperature increment before the over-wintering period had no significant effect on earlier phase spike differentiation. But an apparent effect on later phase spike differentiation was observed. High temperature effect on spike differentiation disappeared when the difference of effective accumulated temperature between the temperature increment treatment and the control was lower than 25 °C. However, the foliar age at the jointing stage was enhanced more than 0.8, heading and physiological ripening were advanced 1 day each, when the effective accumulated temperature before the over-wintering period increased 60 °C. Higher effective accumulated temperature before the over-wintering period accelerated winter wheat growth and development, which resulted in a short spike differentiation period. Winter wheat was easy to suffer freeze damage, which lead to floret abortion and spikelet death in spring under this situation. Meanwhile, higher effective accumulated temperature before the over-wintering period also reduced, photosynthetic capacity of flag leaf, shortened the grain filling period, and led to wheat grain yield reduction.

[Responses of wheat seedlings root growth and leaf photosynthesis to drought stress].

Taking drought-sensitive wheat cultivar Wangshuibai and drought-tolerance cultivar Luohan 7 as test materials, a hydroponic experiment was conducted to study the effects of drought stress on root system morphology, physiological characteristics and leaf photosynthesis of wheat seedlings, aimed to elucidate the adaptation mechanisms to drought stress. Under drought stress, the root vitality of the cultivars increased markedly, but the root number and root surface area decreased. Drought stress decreased relative water content and increased the ratio of bound water to free water in leaves of Wangshuibai, but had less effects on Luohan 7. Drought stress decreased, the leaf chlorophyll content, Pn g(s), Ci, and transpiration rate of the two cultivars, but had no significant effects on leaf chlorophyll content and Pn of Luohan 7. Drought stress decreased the leaf area of the two cultivars and the root biomass, shoot biomass, and plant biomass of Wangshuibai, but had no significant effects on Luohan 7. The results indicated that under drought stress, drought-tolerant wheat cultivar was able to compensate decreased root absorption area and retain higher root water uptake capability via enhancing root vitality and maintaining higher root biomass, and further, to keep higher leaf photosynthetic area and Pn to mitigate the inhibition of drought on wheat seedlings growth.