荒漠-绿洲边缘区生态过渡带的土壤颗粒分形特征

通过实地采样和实验室分析,测定了黑河中游荒漠绿洲边缘区生态过渡带的土壤粒级分布、有机碳(SOC)、全氮(TN)、全磷(TP)、速效氮(AN)和速效磷(AP)的含量,并采用1993年杨培岭等提出的用粒径的重量分布代替数量分布的土壤分形模型,计算了土壤颗粒分形维数;最后利用统计分析法,研究了颗粒分形维数与土壤粒级分布及各养分指标的关系.结果表明:从荒漠边缘向绿洲延伸的过渡带,土壤中砂粒含量占绝对优势,粉粒居中,黏粒最少,采样区土壤质地较粗;土壤颗粒分形维数在2.105～2.609之间变动,处于极低水平,与土壤各养分指标具有相似的变化趋势,除靠近绿洲区存在一个"生态裂谷"外,整体呈上升趋势;利用相关分析法得出,土壤颗粒分形维数与砂粒含量呈显著负相关,与黏粉粒及各养分指标均呈显著的正相关;利用回归分析法进行定量分析,砂粒含量每增加1g/kg,颗粒分形维数D降低0.0019个单位;粉粒和黏粒含量每增加1g/kg,颗粒分形维数D分别增加0.002和0,023个单位,对土壤颗粒分形维数变化幅度的影响依次为黏粒>粉粒>砂粒,分形维数对黏粒含量的变化最为敏感.因此,可以将土壤颗粒分形维数作为衡量荒漠-绿洲边缘区土壤养分变化状况的指标之一,用于反映荒漠绿洲区土壤的退化状况.     

芜菁花叶病毒提纯技术的研究

将繁殖于大白菜上的病叶榨汁,结合聚乙二醇(PEG)沉淀及差速离心技术,拟定三种提纯程序,所得芜菁花叶病毒(TuMV)粗提纯物,可侵染芜菁、萝卜和大白菜,并在苋色藜和普通烟黄茵榆上产生局部枯斑。测定提纯物表现出典型的核蛋白紫外吸收光谱,在电镜观察下,其丝状病毒粒子形态清晰且排列疏松均匀、病毒粒子长度集中分布在730nm、宽12～13nm。用水醋酸分解、可获得本病毒的提纯的衣壳蛋白,它具有典型蛋白质紫外吸收光谱,上述三种提纯程序中,以第三种程序最佳。初步认为,若设备不足情况下省用蔗糖密度梯度离心步骤,仅用第三种提纯程序,亦可获得较好提纯效果。     

直接模拟蒙特卡罗方法在CFD冲蚀预测中的应用

为研究气固两相流中固体颗粒间碰撞对冲蚀的影响,提出一种利用直接模拟蒙特卡罗(Direct Simulation Monte Carlo,DSMC)方法和计算流体力学(CFD)计算颗粒间碰撞的冲蚀预测方法。使用Eulerian-Lagrangian方法,将气相作为连续相,通过Navier-Stokes方程求解,颗粒平移运动由离散相模型(DPM)求解。颗粒平移运动由Eulerian-Lagrangian框架下的DPM求解,计算颗粒间碰撞运动时采用DSMC方法以少量采样颗粒代替真实颗粒,碰撞的发生条件通过修正的Nanbu方法判定。分析气固两相流中颗粒间碰撞对弯管冲蚀速率和颗粒分布的影响,结果表明:使用DSMC方法计算颗粒间碰撞,Oka模型的平均百分误差从39.2%降低至27.4%;计算颗粒间碰撞时弯管内拱侧的无颗粒区变小,最大冲蚀位置沿外拱轴线后移5°,同时V形冲蚀痕迹的两翼向外侧扩大。使用DSMC方法计算颗粒间碰撞可以明显降低模型误差,考虑颗粒间碰撞的Oka模型与实验结果偏差最小,是冲蚀预测的最佳模型。     

围封对短花针茅植丛土壤颗粒组成和养分富集的影响

以一体化土壤采集器为试材,采用植丛内外差值百分比法,以围封退化短花针茅草地为研究对象,临近自由放牧草地为对照(CK),对比研究了荒漠草原短花针茅植丛对土壤颗粒组成和SOC和TN的富集效应在空间上的变化,以期探讨植丛对土壤富集作用的影响。结果表明:就富集率"E"值而言,粘粒(<2μm)和砂粒(50～2 000μm)的富集格局大致趋势相反,生境和土层深度对粉粒(2～500μm)的富集均无显著影响(P>0.05)。SOC在6～8 cm土层放牧区显著高于围封区,12～14 cm土层围封区显著高于放牧区;TN则在4～6 cm土层围封区显著高于放牧区,12～14 cm土层放牧区显著高于围封区(P<0.05)。沿土层深度垂直变化,颗粒组成仅放牧区砂粒在12～14 cm土层"E"值显著增高(P>0.05);SOC围封区0～2 cm土层"E"值显著高于其它土层(P<0.05),TN放牧区呈先减少后增高"V"型变化,4～8 cm土层"E"值显著降低(P<0.05),放牧区的SOC和围封区的TN都无显著变化(P>0.05)。粘粒与砂粒的"E"值均呈显著负相关(P<0.05),粉粒与粘粒、粉粒与砂粒的"E"值相关关系逆转;颗粒组成与SOC、TN的"E"值相关性都不显著(P>0.05)。总之,围封并未使短花针茅植丛对土壤粘粒的整体富集率增大,反而有所降低;但围封确推动了土壤粘粒和SOC表聚型富集;土壤SOC和TN的富集是2个独立的过程,围封都有利于任意土层TN的富集。     

Kernel vitreousness and protein content: Relationship,interaction and synergistic effects on durum wheat quality

Four sets of durum samples were used in this study to further understand the interrelationships among hard vitreous kernels (HVK), protein content, and pigment concentration, with a focus on the interaction and synergistic effects of protein content and vitreousness on durum quality. HVK level increases with higher protein content in the range of 9.5–12.5%, but this relationship is less evident in durum samples with high protein content (12.5–14.5%). Both protein content and kernel vitreousness can significantly affect durum milling quality. White starchy kernels (WSK) in low protein durum have a very detrimental impact on milling and pasta processing quality, but high protein content can mitigate the adverse impact of WSK on durum quality. Although protein content plays a dominant role, higher HVK might contribute positively to pasta firmness. There was no significant difference in yellow pigment content between HVK and WSK. However, pigment loss from semolina to dough was higher for WSK than HVK. Despite the difference in protein content, HVK and WSK have little difference in gluten strength. The monomeric protein was preferentially accumulated in HVK. The glutenin proteins of HVK and WSK were similar in the ratios of 1Bx/1By and HMW/LMW-GS.     

不同木屑颗粒度对工厂化压块香菇生长的影响

以香菇(Lentinula edodes)工厂化生产品种沪香F2为供试菌株,以香菇生产常用配方(78%木屑,20%麸皮,2%石膏)为基础培养料,以菌丝生长速度、子实体产量、单菇重、出菇期、生物学效率以及菇型等为筛选指标,考察不同木屑颗粒度配比对工厂化压块条件下香菇生产的影响。结果表明:颗粒度组合M3(K1∶1.5mm以下,K2∶1.5~3.0mm,K3∶3.0~8.0mm;K1∶K2∶K3=1∶1∶1)的菌丝生长速度最快[(5.2±0.8)mm/d],单菇重最大[(27.1±1.0)g],产量较高[(178.7±3.6)g],菇型好,第一潮菇生物转化率可达到40.8%,生产周期可控制在100d以内,适合于在工厂化条件下应用。     

D形截面螺旋输送机输送颗粒物料的实验研究

在可控转速的情况下运输粉末或者颗粒等松散物料时,因其机构简单,螺旋输送机被广泛应用于林业、农业等多种背景下的短距离提升或水平运输物料。为此,采用实验方法,针对改进后的D形截面筒的输送机进行输送颗粒物料的研究,结果表明:输送的质量流速率随着输送转速的增加而增加,随输送角度的增大而降低。另外,螺距和颗粒物料的粒径也对质量流速率有影响:大螺距的输送质量流速率较大,且随着输送倾斜角度的增大,螺距对质量流速率的影响减小;大颗粒的质量流速率大于小颗粒,且随着输送倾斜角度增加差距增大。     

办公建筑中空调形式对室内外PM2.5浓度相关性的影响

室外PM2.5可通过新风及围护结构缝隙渗透至室内,室外PM2.5较高时尤为明显,结果导致室内空气中的PM2.5浓度上升。为了研究空调形式对室内外PM2.5浓度相关性的影响,在2015年夏季对重庆某办公建筑中采用不同空调形式的室内外PM2.5浓度进行了实测。实测结果发现：集中式空调、分体式空调和非空调房间室内外PM2.5浓度比变化范围分别为0.59～0.76、0.47～0.76、0.71～0.91。室内外PM2.5浓度相关性系数的排序为：集中式空调环境（0.94）> 非空调环境（0.92）> 分体式空调环境（0.77）,研究结果表明,办公建筑的空调形式,对室内外PM2.5浓度的相关性有影响。     

Intensive organic vegetable production increases soil organic carbon but with a lower carbon conversion efficiency than integrated management

Intensive vegetable production in greenhouses has rapidly expanded in China since the 1990s and increased to 1.3 million ha of farmland by 2016, which is the highest in the world. We conducted an 11‐year greenhouse vegetable production experiment from 2002 to 2013 to observe soil organic carbon (SOC) dynamics under three management systems, i.e., conventional (CON), integrated (ING), and intensive organic (ORG) farming. Soil samples (0–20 and 20–40 cm depth) were collected in 2002 and 2013 and separated into four particle‐size fractions, i.e., coarse sand (> 250 µm), fine sand (250–53 µm), silt (53–2 µm), and clay (< 2 µm). The SOC contents and δ¹³C values of the whole soil and the four particle‐size fractions were analyzed. After 11 years of vegetable farming, ORG and ING significantly increased SOC stocks (0–20 cm) by 4008 ± 36.6 and 2880 ± 365 kg C ha^?1 y^?1, respectively, 8.1‐ and 5.8‐times that of CON (494 ± 42.6 kg C ha^?1 y^?1). The SOC stock increase in ORG at 20–40 cm depth was 245 ± 66.4 kg C ha^?1 y^?1, significantly higher than in ING (66 ± 13.4 kg C ha^?1 y^?1) and CON (109 ± 44.8 kg C ha^?1 y^?1). Analyses of ¹³C revealed a significant increase in newly produced SOC in both soil layers in ORG. However, the carbon conversion efficiency (CE: increased organic carbon in soil divided by organic carbon input) was lower in ORG (14.4%–21.7%) than in ING (18.2%–27.4%). Among the four particle‐sizes in the 0–20 cm layer, the silt fraction exhibited the largest proportion of increase in SOC content (57.8% and 55.4% of the SOC increase in ORG and ING, respectively). A similar trend was detected in the 20–40 cm soil layer. Over all, intensive organic (ORG) vegetable production increases soil organic carbon but with a lower carbon conversion efficiency than integrated (ING) management.