不同粒度猫尾草对羔羊体外发酵特性和微生物数量的影响

通过Rusitec-s体外发酵系统研究不同粒度猫尾草对羔羊体外发酵参数与微生物数量的影响,选取6种不同粒度(1.00、2.36、3.35、4.75、8.00和12.50 mm)的猫尾草作为试验饲粮的纤维来源,按照猫尾草的粒度将试验分为6个处理组,每个处理4个重复,利用Rusitec-s型人工瘤胃模拟装置进行48 h体外发酵,测定养分降解率、发酵参数及发酵液中6种微生物菌群的拷贝数。结果表明：与其他处理组相比,2.36 mm组显著提高了体外中性洗涤纤维降解率(IVNDFD)、丁酸、异丁酸、戊酸、异戊酸摩尔比和溶纤维丁酸弧菌(B. f)数量(P<0.05),且显著降低总产甲烷菌(TMe)数量(P<0.05)。总菌(TB)与氨态氮(NH3-N)浓度、乙酸摩尔比呈正相关(R²=0.84,P=0.038;R²=0.88,P=0.021);B. f数量与丙酸摩尔比呈正相关(R²=0.82,P=0.045),且与pH呈负相关(R²=-0.98,P=0.001);TMe数量与体外粗蛋白质降解率(IVCP...     

尕海湿地区沼泽草甸退化对土壤氮转化酶活性的影响

为探讨高寒湿地退化对土壤氮转化酶活性的影响,以青藏高原东缘尕海湿地未退化（ND）、轻度退化（LD）、中度退化（MD）和重度退化（HD）4种不同退化程度0~40 cm土层沼泽草甸为研究对象,研究不同退化与土层中土壤氮转化酶（蛋白酶、脲酶、硝酸还原酶和亚硝酸还原酶）活性的变化特征及其与土壤理化性质之间的关系。结果表明：1）随沼泽草甸退化程度加剧,土壤含水量、全氮、铵态氮和微生物生物量氮含量均显著降低,土壤温度与硝态氮含量却显著增加。2）随退化程度加剧,各土层土壤脲酶活性增加、蛋白酶活性降低,且仅在20~40 cm土层存在显著差异;硝酸还原酶活性增加、亚硝酸还原酶活性降低,在0~20 cm土层存在显著差异。3）各退化程度中,土壤脲酶、蛋白酶、亚硝酸还原酶活性均随土层深度的增加而显著下降,硝酸还原酶活性仅在HD显著下降。4）退化程度和土层对4种土壤氮转化酶活性均存在显著影响,且对土壤硝酸酶和亚硝酸还原酶活性存在显著交互作用。5）冗余分析表明土壤含水量对土壤氮转化酶活性变化的贡献率高达67.1%,其是驱动尕海沼泽草甸退化演替过程中土壤氮转化酶活性变化的主导因素。研究结果可为高寒湿地生态系统退化中的土壤酶活性变化规律提供理论依据。     

不同灌溉方式下玉米节水增产效果试验研究

在降雨、灌溉水量和前期土壤特性一定的情况下，对玉米在喷灌、滴灌、渗灌3种灌溉方式下的土壤水分变化特性和玉米生育特性进行了试验研究，分析了各种灌溉方式下玉米的生长特性和玉米地土壤水分的变化规律。试验结果表明：渗灌的节水增产效果最好，产量比滴灌增加1．3％，水分生产率由2．64kg／m^3提高到2．68kg／m^3；比喷灌增加6．3％，水分生产率由2．52kg／m^3提高到2．68kg／m^3。     

调亏灌溉对蚕豆需水规律及水分利用效率的影响

在甘肃秦王川灌区通过大田试验研究了苗期调亏灌溉对蚕豆需水规律和水分生产效率的影响.结果表明:调亏处理蚕豆在苗期、拔节期及花荚期需水量减少,叶面积、蒸腾速率和光合速率下降,在鼓粒成熟期则相对增加,作物的总需水量减少.叶面积、蒸腾速率和棵间蒸发减少是调亏灌溉需水量降低的主要原因.调亏灌溉能够延缓鼓粒期叶片衰老,提高光合速率,使光合同化物向籽粒分配的比例增加,提高水分生产效率.     

Yield performance of spring wheat improved by regulated deficit irrigation in an arid area

A field experiment was conducted in 2003 and 2004 growing seasons to evaluate the effects of regulated deficit irrigation on yield performance in spring wheat (Triticum aestivum) in an arid area. Three regulated deficit irrigation treatments designed to subject the crops to various degrees of soil water deficit at different stages of crop development and a no-soil-water-deficit control was established. Soil moisture was measured gravimetrically in the increment of 0–20 cm every five to seven days in the given growth periods, while that in 20 increments to 40, 40–60, 60–80, and 80–100 cm depth measured by neutron probe. Compared to the no-soil-water-deficit treatment, grain yield, biomass, harvest index, water use efficiency (WUE), and water supply use efficiency (WsUE) in spring wheat were all greatly improved by 16.6–25.0, 12.4–19.2, 23.5–27.3, 32.7–39.9, and 44.6–58.8% under regulated deficit irrigation, and better yield components such as thousand-grain weight, grain weight per spike, number of grain, length of spike, and fertile spikelet number were also obtained, but irrigation water was substantially decreased by 14.0–22.9%. The patterns of soil moisture were similar in the regulated deficit treatments, and the soil moisture contents were greatly decreased by regulated deficit irrigation during wheat growing seasons. Significant differences were found between the no-soil-water-deficit treatment and the regulated soil water deficit treatments in grain yield, yield components, biomass, harvest index, WUE, and WsUE, but no significant differences occurred within the regulated soil water deficit treatments. Yield performance proved that regulated deficit irrigation treatment subjected to medium soil water deficit both during the middle vegetative stage (jointing) and the late reproductive stages (filling and maturity or filling) while subjected to no-soil-water-deficit both during the late vegetative stage (booting) and the early reproductive stage (heading) (MNNM) had the highest yield increase of 25.0 and 14.0% of significant water-saving, therefore, the optimum controlled soil water deficit levels in this study should range 50–60% of field water capacity (FWC) at the middle vegetative growth period (jointing), and 65–70% of FWC at both of the late vegetative period (booting) and early reproductive period (heading) followed by 50–60% of FWC at the late reproductive periods (the end of filling or filling and maturity) in treatment MNNM, with the corresponding optimum total irrigation water of 338 mm. In addition, the relationships among grain yield, biomass, and harvest index, the relationship between grain yield and WUE, WsUE, and the relationship between harvest index and WUE, WsUE under regulated deficit irrigation were also estimated through linear or non-linear regression models, which indicate that the highest grain yield was associated with the maximum biomass, harvest index, and water supply use efficiency, but not with the highest water use efficiency, which was reached by appropriate controlling soil moisture content and water consumption. The relations also indicate that the harvest index was associated with the maximum biomass and water supply use efficiency, but not with the highest water use efficiency.     

Water-use efficiency of dwarf-green coconut (Cocos nucifera L.) orchards in northeast Brazil

Field experiments were conducted in a tropical region to determine the water-use efficiency (WUE), yield (Y) and evapotranspiration (ET) of a 6-year-old dwarf-green coconut (Cocos nucifera L.) orchard. Three water levels were applied in plots with nine palms. The irrigation treatments denoted as T:50, T:100 and T:150 received 50, 100 and 150 L/plant/day, respectively. The actual evapotranspiration was obtained by the soil water balance (SWB) method. Yield and water-use efficiency were assessed in terms of bunches per plant, fruits per plant and water volume per fruit. The application of the SWB resulted in mean daily ET values of 2.5; 2.9 and 3.2 mm/day for irrigation treatment of T:50, T:100 and T:150, respectively, while the cumulative ET varied from 900 to 1100 mm as irrigation treatment increased from T:50 to T:150. Results also showed that ET values were higher in the beginning and end of the year and lower in the middle of the experimental period. The application of a high irrigation water volume does not necessarily resulted in high coconut fruits yield. Evapotranspiration, fruits yield and water-use efficiency were strongly affected by irrigation water volume in coconut palms. WUE values decreased with increasing irrigation water level for all productivity parameters.     

春小麦调亏灌溉对土壤氮磷钾的影响

对河西绿洲灌区春小麦调亏灌溉2年后的土壤碱解氮和全氮、速效磷和全磷、速效钾和全钾进行了研究,并对土壤养分年际间的差异进行了分析,旨在为该区春小麦调亏灌溉对土壤氮磷钾养分的影响研究提供一些可靠的信息。     

观赏文冠果新品种‘森淼重瓣冠’

‘森淼重瓣冠’是从文冠果的实生变异单株中选出的观赏型新品种。树势强健,发枝力强;总状花序,每花序20~30朵重瓣无性花,每朵小花约30个花瓣,花瓣白色;外层花瓣较大为倒卵形,逐层变小,内层花瓣长条形;不结实。     

Effects of different soil conservation tillage approaches on soil nutrients,water use and wheat-maize yield in rainfed dry-land regions of North China

Excessive tillage compromises soil quality by causing severe water shortages that can lead to crop failure. Reports on the effects of conservation tillage on major soil nutrients, water use efficiency and gain yield in wheat (Triticum aestivum L.) and maize (Zea mays L.) in rainfed regions in the North China Plain are relatively scarce. In this work, four tillage approaches were tested from 2004 to 2012 in a randomized study performed in triplicate: one conventional tillage and three conservation tillage experiments with straw mulching (no tillage during wheat and maize seasons, subsoiling during the maize season but no tillage during the wheat season, and ridge planting during both wheat and maize seasons). Compared with conventional tillage, by 2012, eight years of conservation tillage treatments (no tillage, subsoiling and ridge planting) resulted in a significant increase in available phosphorus in topsoil (0–0.20 m), by 3.8%, 37.8% and 36.9%, respectively. Soil available potassium was also increased following conservation tillage, by 13.6%, 37.5% and 25.0%, and soil organic matter by 0.17%, 5.65% and 4.77%, while soil total nitrogen was altered by −2.33%, 4.21% and 1.74%, respectively. Meanwhile, all three conservation tillage approaches increased water use efficiency, by 19.1–28.4% (average 24.6%), 10.1–23.8% (average 15.9%) and 11.2–20.7% (average 15.7%) in wheat, maize and annual, respectively. Additionally, wheat yield was increased by 7.9–12.0% (average 10.3%), maize yield by 13.4–24.6% (average 17.4%) and rotation annual yield by 12.3–16.9% (average 14.1%). Overall, our findings demonstrate that subsoiling and ridge planting with straw mulching performed better than conventional tillage for enhancing major soil nutrients and improving grain yield and water use efficiency in rainfed regions in the North China Plain.     

盐胁迫对裸果木幼苗光合特性的影响

本研究以一年生裸果木幼苗为材料，采用盆栽育苗方式，设计7个不同浓度NaCl溶液（CK、0.2%、0.4%、0.6%、0.8%、1.0% 和1.2%）模拟盐分胁迫，测定分析了其叶片气体交换参数、光响应曲线及叶绿素荧光参数的变化规律。结果表明：随着盐浓度的增加，叶片净光合速率（P_n）、气孔导度（G_s）和蒸腾速率（T_r）均呈下降趋势，NaCl浓度≥0.4%时，各处理P_n、G_s和T_r均显著低于CK；气孔限制值（L_s）和瞬时水分利用效率（WUE）随盐浓度增加呈先升后降趋势，胞间CO₂浓度（C_i）呈相反趋势，NaCl浓度为0.4%时，L_s达到最大值，而C_i达到最小值，说明P_n下降以气孔限制因素为主，而当NaCl浓度≥0.6%时，以非气孔限制为主要因素。随着盐胁迫程度的增大，最大净光合速率（P_nmax）、暗呼吸速率（R_d）、光饱和点（L_SP）、表观量子效率（A_QY）逐渐降低，光补偿点（L_CP）逐渐增加，表明盐分抑制了幼苗对光的吸收、利用和转换能力。叶片PSII潜在活性（F_v/F₀）、原初光能转化效率（F_v/F_m）、实际光化学效率（Φ_PSII）、电子传递速率（ETR）和光化学猝灭系数（q_p）随着盐浓度的增加呈下降趋势；非光化学猝灭系数（NPQ）在≤0.4%NaCl处理下较CK显著增加，盐浓度≥0.8%时，NPQ显著下降。基质的NaCl浓度在0.2%和0.4%时，裸果木叶片P_n、F_v/F₀、F_v/F_m下降不显著，WUE有所提高，PSII系统可以通过耗散过剩的光能保护光合机构，表现出一定的耐盐性；但盐浓度超过0.6%时，光合生态幅变窄，光合机构受到明显破坏，显著抑制了光合作用能力。