68 resultados para Meat and grain yield
Resumo:
辽河三角洲优越的植被生态系统维系着多种生态功能,使该地区成为全国著名的商品粮基地、造纸原料基地和旅游基地。但是,气候变化和人为干扰使得辽河三角洲的植被结构发生了显著变化,影响到植被功能的发挥。 为了应对气候变化和人为干扰对辽河三角洲植被造成的不利影响,本论文围绕植被结构和生产功能,从空间和时间方面,重点阐述了辽河三角洲植被的结构及其驱动机制;辽河三角洲植被生产功能及其驱动机制。 采用的研究方法包括遥感解译、样带调查和全面调查。通过遥感解译方法获取各植被类型的面积、分布及其变化信息,以研究植被的空间分布格局及其变化。通过样带调查方法,获取植被类型、土壤和水文等信息,并结合规范对应分析和偏相关分析等,研究植被空间分布格局的驱动机制。通过全面调查方法,获取植被净第一性生产力、粮食产量、土壤和水文等信息,并结合地理信息系统(GIS)的插值分析和相关分析等,研究植被生产功能的空间分布格局及其驱动机制。主要结论如下: 1. 植被组成和空间格局:辽河三角洲植被主要由自然湿地植被、人工湿地植被、自然旱地植被、人工旱地植被四大植被类型组成。其中,面积最大的3种植被是玉米、水稻和芦苇。四大植被类型以双台子河口为中心,基本上呈现半环状分布格局。 2. 植被空间格局变化:1988~2006年辽河三角洲植被空间格局发生了显著变化,主要植被类型分布趋于集中,形成了一些较大的斑块,而不是离散和破碎。从面积上看,水稻是面积增加最多的植被类型;玉米是面积减少最多的植被类型。从变化速率看,水稻、玉米和芦苇的变化幅度都较大,分别为33.2%、-16.1%和-23.2% 。 3. 植被空间格局形成机制:辽河三角洲植被分布格局不是由气候因子决定的,而是由土壤因子决定。土壤可溶性盐是决定植被分布格局最重要的环境因子,其次是土壤含水量。 4. 植被生产功能:辽河三角洲植被具有极高的生产力。其中,玉米、水稻和芦苇3种主要植被的地上净第一性生产力分别为30,485、18,248和17,440 kg/(ha•a)。玉米和水稻单位面积粮食产量也非常高,分别为14,813和10,365 kg/(ha•a)。 5. 植被生产功能年际变化:辽河三角洲植被生产力存在明显的年际波动。1992~2005 年间玉米和水稻粮食产量呈现显著的年际波动;1949~1990 年间芦苇产量不仅存在较明显的年际波动,而且呈现非常显著的增加趋势。 6. 植被生产功能年际变化的驱动机制:气候因子是玉米和水稻粮食产量年际变化的主要驱动因子,气候因子对玉米和水稻粮食产量的影响远远大于人为因子(农业人口、施肥量、灌溉面积)的影响。气候因子和人为因子对芦苇产量年际变化的影响都非常显著。在气候因子中,年日照数是驱动玉米产量年际波动的主导气候因子;年降水量是驱动水稻产量年际波动的主导气候因子;年蒸发量是驱动芦苇产量年际波动的主导气候因子。 7. 植被生产功能空间格局:植被地上净第一性生产力存在显著的空间差异,表现为一种环形空间分布格局,三角洲中部较低,四周地区较高。这种空间分布格局表明,在辽河三角洲,植被地上净第一性生产力最高的不是湿地植被,而是周围旱地植被。 8. 植被生产功能空间格局的形成机制:土壤含水量和海拔是驱动辽河三角洲植被生产力空间格局的主要因子;土壤盐度、土壤pH和土壤容重对植被生产力的空间格局影响不大。土壤营养元素(氮、磷、钾) 对植被生产力的空间格局几乎没有影响。
Resumo:
基于长期观测资料,众多大气环流模型预测在二十一世纪末大气中二氧化碳浓度将达到700μmolmol'I,地球表面年平均温度也将升高1.5-4.OoC。水稻是亚洲的主要粮食作物,为世界近三分之一的人口提供食物能源。这项工作的目的,是利用人工模拟环境,预测在未来全球气候变化,二氧化碳及温度升高的条件下,水稻的光合生理反应及随之而来的对其产量的影响。本研究是美国环境署( EPA)与国际水稻研究所(IRRI)合作研究项目“Effects of UV-B and Global Climate Change on Rice”的一部分. 在这项研究中,采用了特殊设计并直接建立在水稻田间的开顶式气室(open-top chambers)。在此之前还没有这样大规模的在水稻主产区的此类模拟研究,水稻在气室中渡过了从萌发到收获的整个生长过程。模拟环境条件有三个浓度的二氧化碳(包括现有大气浓度,在此基础上升高200及300 μmolmol-l)和两个温度(即:现有大气温度及升高4度)共六个处理。供试水稻品种四个:IR72,IR65598-112-2,IR65600-42-5-2-BSI-313和N22。在实验中我们发现,水稻品种(如:1R72)单叶光合速率(以二氧化碳气体交换速率计)受二氧化碳浓度促进,在水稻营养生长期,二氧化碳及温度对其光合有协同促进作用.然而,随着花期的到来,在高温条件下,叶片光合能力(photosynthetic capacity)下降,出现光合适应现象(Photosynthetic acclirnation).水稻群体光合作用同样受到二氧化碳浓度促进,但在后期(Grain fill stage)这种促进作用消失;在高浓度二氧化碳下生长的大多数水稻品种的叶片中有较多的碳水化和物(可溶性糖和淀粉)积累.耐高温品种N22叶片中淀粉积累较少:叶片中氮素含量降低,同时发现Rubisco总活性相应降低,这与NCi曲线所示光合效率降低相吻合;通过叶片叶绿素荧光动力学测定,没有发现光系统光能转化效率的变化;水稻籽粒产量随二氧化碳浓度升高而增加,但温度升高使产量降低12.8-36.8%;不同品种对二氧化碳浓度的反应没有显著差别;在高温条件下,耐高温品生长在高二氧化碳浓度下表现良好。 本文系统地研究了水稻光合作用在二氧化碳及温度条件影响下,对二氧化碳浓度及光强变化的反应曲线,初次对水稻单叶与群体光合对二氧化碳浓度变化的反应做了实验性对比;讨论了温度升高对水稻在高浓度二氧化碳下发生光合适应的影响,对光合适应现象的可能机制做了探讨,并提出对未来大气二氧化碳浓度及温度升高条件下水稻适应品种筛选的可能方向。
Resumo:
The growth and toxin content of the dinoflagellate Alexandrium tamarense ATHK was markedly affected by culture methods. In early growth phase at lower cell density static or mild agitation methods were beneficial to growth, but continuous agitation or aeration, to some extent, had an adverse effect on cell growth. Static culture in 2 L Erlenmeyer flasks had the highest growth rate (0.38 d(-1)) but smaller cell size compared with other culture conditions. Cells grown under aerated conditions possessed low nitrogen and phosphorus cell yields, namely high N and P cell-quota. At day 18, cells grown in continuous agitated and 1 h aerated culture entered the late stationary phase and their cellular toxin contents were higher (0.67 and 0.54 pg cell(-1)) compared with cells grown by other culture methods (0.27-0.49 pg cell(-1)). The highest cell density and cellular toxin content were 17190 cells mL(-1) and 1.26 pg cell(-1) respectively in an airlift photobioreactor with two-step culture. The results indicate that A. tamarense could be grown successfully in airlift photobioreactor by a two-step culture method, which involved cultivating the cells statically for 4 days and then aerating the medium. This provides an efficient way to enhance cell and toxin yield of A. tamarense.
Resumo:
ZnO thin films were deposited on glass substrates at room temperature (RT) similar to 500 degrees C by pulsed laser deposition (PLD) technique and then were annealed at 150-450 degrees C in air. The effects of annealing temperature on the microstructure and optical properties of the thin films deposited at each substrate temperature were investigated by XRD, SEM, transmittance spectra, and photoluminescence (PL). The results showed that the c-axis orientation of ZnO thin films was not destroyed by annealing treatments: the grain size increased and stress relaxed for the films deposited at 200-500 degrees C, and thin films densified for the films deposited at RT with increasing annealing temperature. The transmittance spectra indicated that E-g of thin films showed a decreased trend with annealing temperature. From the PL measurements, there was a general trend, that is UV emission enhanced with lower annealing temperature and disappeared at higher annealing temperature for the films deposited at 200-500 degrees C; no UV emission was observed for the films deposited at RT regardless of annealing treatment. Improvement of grain size and stoichiometric ratio with annealing temperature can be attributed to the enhancement of UV emission, but the adsorbed oxygen species on the surface and grain boundary of films are thought to contribute the annihilation of UV emission. It seems that annealing at lower temperature in air is an effective method to improve the UV emission for thin films deposited on glass substrate at substrate temperature above RT.
Resumo:
CaCu3Ti(4-x)Nb(x)O(12) (x = 0, 0.01, 0.08, 0.2) ceramics were fabricated by a conventional solid-state reaction method. The ceramics showed the body-centered cubic structure without any foreign phases and the grain size decreases with Nb doping. Two Debye-type relaxations were observed for the Nb-doped samples at low frequency and high frequency, respectively. The complex electric modulus analysis revealed that the surface layer, grains and grain boundaries contributed to the dielectric constant. The low-frequency dielectric constant relative to the surface layer decreased to a minimum and then increased with the dc bias voltage at 100 Hz, which were well explained in terms of a model containing two metal oxide semiconductors in series, confirming the surface layer in the ceramics. The shift voltage V-B corresponding to the minimal capacitance increased with increase of the composition x. (C) 2009 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.
Resumo:
A series of diphasic nanocrystalline silicon films and solar cells was prepared using different hydrogen dilution ratios of silane by very high frequency plasma enhanced chemical vapor deposition (VHF-PECVD). It was observed that after light soaking the open circuit voltage (V-oc) of the diphasic solar cells increased, while that of amorphous silicon solar cells decreased. Raman scattering spectroscopy was performed on the series of diphasic silicon films before and after light soaking. It was found that after light soaking the nanostruclures in the diphasic nanocrystalline silicon films were changed. Both the grain sizes and grain volume fraction reduced, while the grain boundary components increased. These results provide experimental evidence for the conjecture that the light-induced increase in V-oc of the diphasic nanocrystalline solar cells might be induced by the changes in the nanostructure of the intrinsic layer. (c) 2006 Elsevier B.V. All rights reserved.
Resumo:
A series of diphasic nanocrystalline silicon films and solar cells was prepared using different hydrogen dilution ratios of silane by very high frequency plasma enhanced chemical vapor deposition (VHF-PECVD). It was observed that after light soaking the open circuit voltage (V-oc) of the diphasic solar cells increased, while that of amorphous silicon solar cells decreased. Raman scattering spectroscopy was performed on the series of diphasic silicon films before and after light soaking. It was found that after light soaking the nanostruclures in the diphasic nanocrystalline silicon films were changed. Both the grain sizes and grain volume fraction reduced, while the grain boundary components increased. These results provide experimental evidence for the conjecture that the light-induced increase in V-oc of the diphasic nanocrystalline solar cells might be induced by the changes in the nanostructure of the intrinsic layer. (c) 2006 Elsevier B.V. All rights reserved.
Resumo:
Microcrystalline silicon films were deposited by very high frequency (VHF) plasma-enhanced chemical vapor deposition (PECVD) with different hydrogen dilution. The microstructure of these films was investigated using Raman spectroscopy and infrared absorption (IR) spectra. The crystalline, amorphous, and grain boundary volume fractions X-c, X-a and X-gb were estimated from Raman measurements. An interface structure factor (R-if) is proposed to characterize the grain boundary volume fractions in IR spectroscopy. The density of states (DOS) of the microcrystalline crystalline silicon films were studied by phase-shift analysis of modulated photocurrent (MPC) and photoconductivity spectroscopy. It was observed that DOS increases with increasing grain boundary volume fractions, while the values of electron mobility-lifetime product mu T-e(e) disease.
Resumo:
Various concepts have been proposed or used in the development of rheological models for debris flow. The earliest model developed by Bagnold was based on the concept of the “dispersive” pressure generated by grain collisions. Bagnold’s concept appears to be theoretically sound, but his empirical model has been found to be inconsistent with most theoretical models developed from non-Newtonian fluid mechanics. Although the generality of Bagnold’s model is still at issue, debris-flow modelers in Japan have generally accepted Takahashi’s formulas derived from Bagnold’s model. Some efforts have recently been made by theoreticians in non-Newtonian fluid mechanics to modify or improve Bagnold’s concept or model. A viable rheological model should consist both of a rate-independent part and a rate-dependent part. A generalized viscoplastic fluid (GVF) model that has both parts as well as two major rheological properties (i.e., the normal stress effect and soil yield criterion) is shown to be sufficiently accurate, yet practical, for general use in debris-flow modeling. In fact, Bagnold’s model is found to be only a particular case of the GVF model. Analytical solutions for (steady) uniform debris flows in wide channels are obtained from the GVF model based on Bagnold’s simplified assumption of constant grain concentration.
Resumo:
In this study, we analyzed the operational characteristics of a 1.2-MW rice husk gasification and power generation plant located in Changxing, Zhejiang province, China. The influences of gasification temperature, equivalence ratio (ER), feeding rate and rice husk water content on the gasification characteristics in a fluidized bed gasifier were investigated. The axial temperature profile in the dense phase of the gasifier showed that inadequate fluidization occurred inside the bed, and that the temperature was closely related to changes in ER and feeding rate. The bed temperature increased linearly with increasing ER when the feeding rate was kept constant, while a higher feeding rate corresponded to a lower bed temperature at fixed ER. The gas heating value decreased with increasing temperature, while the feeding rate had little effect. When the gasification temperature was 700-800C, the gas heating value ranged from 5450-6400kJ/Nm3. The water content of the rice husk had an obvious influence on the operation of the gasifier: increases in water content up to 15% resulted in increasing ER and gas yield, while water contents above 15% caused aberrant temperature fluctuations. The problems in this plant are discussed in the light of operational experience of MW-scale biomass gasification and power generation plants.
Resumo:
根据米脂县1990—2007年粮食生产的相关数据,对该县耕地、人口和粮食生产动态变化以及粮食总产与其影响因素进行了灰色关联度分析。结果表明,退耕还林还草工程是耕地总面积迅速减少的主要原因;提高粮食单产保障粮食总产是实现粮食安全的最关键因子;持续增长的人口造成耕地的承载压力越来越大,并对该区实现粮食安全提出了更大的挑战。最后,根据分析结果提出了增加科技投入,提高单产,保护耕地,挖掘耕地潜力等措施以保障该区域的粮食安全,为政府部门制定相关粮食安全政策提供科学的理论依据。
Resumo:
采用田间小区试验,监测夏玉米不同生长期土壤水分和硝态氮剖面含量变化,研究不同施氮量对其时空变化及籽粒产量、水肥利用效率的影响,探讨氮肥对水肥资源高效利用的调节作用。结果表明:不同施氮处理,土壤剖面水分和硝态氮随土壤深度的变化趋势基本一致,即表层50 cm土壤水分和硝态氮含量较高且呈降低态,50~110 cm相对较低且波动较小,灌浆期二者均达到最低值;各生长期表层50 cm土壤含水量呈不施氮处理均高于施氮处理,50~110 cm土层则相反;施氮能提高土壤硝态氮含量,土壤硝态氮运移受土壤水分状况和含量的影响,含量越高,向下移动越深;施氮能显著提高水分利用效率及籽粒产量,增产效果明显(增产28.52%~37.86%),二者均以施氮240 kg/hm2处理最高;随施氮量的增加籽粒产量及籽粒吸氮量和水分利用效率增幅均表现为先升高后降低之趋势,当施氮量超过240 kg/hm2后,籽粒产量和水分利用效率提高并不显著;不施氮与施氮处理氮素生产力、氮肥利用率之间均存在极显著差异。在本试验条件下,从控制土壤硝态氮积累及取得较高的产量和氮素利用率综合考虑,夏玉米的适宜施氮量范围应控制在120~240 kg/hm2较好。
Resumo:
研究不同施磷水平对夏玉米生长期土壤硝态氮时空分布、累积量及玉米籽粒产量的影响,为夏玉米合理施肥提供参考依据。【方法】采用田间小区试验,在施磷水平分别为0,60,120和180 kg/hm2时,研究施磷对夏玉米产量及土壤氮素吸收累积的影响。【结果】在0~110 cm土层,随土壤剖面深度的增加,土壤硝态氮含量逐渐降低,0~30 cm土层明显高于30~110 cm土层且变幅较大,施磷肥能显著降低土壤硝态氮含量。随夏玉米生育期推进,0~110 cm土层硝态氮累积量呈先降低后升高的趋势,于灌浆期达到最低值;当施磷水平为120 kg/hm2时,成熟期0~110 cm土层硝态氮累积量低于施磷60和180 kg/hm2的处理;施磷肥能显著增加玉米籽粒产量、籽粒吸氮量及氮收获指数,均以施磷水平为120 kg/hm2时最高。【结论】在施氮基础上施用磷肥,有利于提高玉米籽粒产量,促进作物对氮素的吸收累积,减少土壤中硝态氮的累积及向更深土层中的运移量。
Resumo:
施用氮肥是提高作物产量和土壤有机碳(SOC)、氮(TSN)含量的重要养分管理措施。利用长期田间试验(19842~007),定量评价了常规耕作条件下5个施氮水平N 0(N0)、45(N45)、90(N90)、135(N135)和180(N180)kg/hm2处理下,小麦子粒产量、SOC、TSN和氮肥利用效率的变化。研究了施氮水平对黄土旱塬区小麦产量、SOC和TSN积累的影响。结果表明,19842~007年期间,N0、N45、N90、N135和N180处理小麦产量的平均值依次为1.2、2.4、2.9、3.2和3.4t/hm2;N0处理的小麦产量随试验年限而降低,年降低幅度达67 kg/hm2(P<0.001);但增施氮肥处理小麦产量降低趋势得到显著控制,当施氮水平提高到N 90 kg/hm2时,产量随年限呈现出缓慢升高的趋势。随着施氮水平的提高,地上部氮肥利用率由40%(N45)降低到28%(N180)。不同施氮水平条件下,SOC含量随年限呈缓慢升高趋势。23年后(2007年),N0、N45、N90、N135和N180处理下,0—20 cm土层SOC储量依次为16.9、18.2、18.7、19.0和19.1 t/...
Resumo:
为了探明施氮量对黄土旱塬区冬小麦(Triticum aestivum L.)籽粒产量和麦田土壤水分动态的影响规律,以抗旱性冬小麦品种长武58为供试材料,于2006~2008年连续两个年度在陕西省长武县对不同施氮量条件下麦田土壤贮水量动态、耗水规律、小麦产量和夏闲期降水补给率等特征进行研究。结果表明,麦田土壤贮水量随季节和降水明显变化,同一生育时期2.7m土层的土壤贮水量基本随施氮量的增加而减少。偏旱年每公顷施氮300kg和平水年每公顷施氮225kg均能够获得当年最大的籽粒产量和水分利用效率。每公顷施氮75kg和225kg均能在夏闲期获得较大的降水补给率。每公顷施氮225kg更有利于黄土旱塬区冬小麦的高产和稳产。
