咸水灌溉对基质栽培甜脆豌豆生长及营养品质的影响

【目的】探讨在水资源紧缺地区开展无土栽培咸水灌溉的可行性。【方法】采用基质盆栽试验,以甜脆豌豆为试验对象,设置0.6(淡水)、1.6、2.6、3.6、4.6 g/L共5个矿化度(深层地下淡水掺兑NaCl而成)灌水处理,研究了甜脆豌豆植株地上部和根系生长状况以及豌豆营养品质对咸水灌溉的响应。【结果】与淡水灌溉相比,灌溉水矿化度为3.6 g/L和4.6 g/L时出苗率显著(P<0.05)降低,降幅分别为12.5%和31.2%;甜脆豌豆的株高、地上部鲜/干物质量均随灌溉水矿化度的增加而显著(P<0.05)降低;在播后16 d时1.6 g/L和2.6 g/L处理的甜脆豌豆根系干物质积累未明显降低,但是在播后32d时咸水灌溉处理的根系干物质较淡水灌溉处理分别降低28.9%、40.5%、52.2%和53.1%;随灌溉水矿化度的增加,甜脆豌豆的根冠比呈增加趋势,豌豆淀粉量呈降低趋势,但2.6 g/L与0.6g/L处理间差异不显著(P≥0.05),豌豆可溶性蛋白量和可溶性糖量表现出先增加后减少的趋势,最大值均出现在2.6 g/L处理。【结论】开展基质栽培咸水灌溉甜脆豌豆是可行的,但灌溉水矿化度应≤2.6 g/L。     

Using vibrational molecular spectroscopy to detect moist heating induced carbohydrates structure changes in cool-climate adapted barley grain

There is limited research to study how moist heating affects internal structure of barley grain on a molecular basis. The objectives of this study were to use vibrational molecular spectroscopy: 1) to determine the moist heating induced changes of barley carbohydrate (CHO) structure on a molecular basis, 2) to study the effects of moist heating on CHO chemical profiles, Cornell Net Carbohydrate and Protein System (CNCPS) subfractions, in situ rumen degradation, and predicted intestinal carbohydrate supply of barley grain; and 3) to reveal the association between molecular structure spectral features and CHO related metabolic characteristics. Barley samples (CDC cowboy) were collected from Kernen Crop Research Farm (Saskatoon, Canada) during two consecutive years. Half of each sample was kept as raw barley and the other half underwent moist heating (autoclaving at 120 °C for 60 min). The molecular spectroscopy (attenuated total reflectance-fourier transform infrared, ATR-FTIR) was used to detect the barley CHO related molecular structure spectral features. Moist heating did not affect carbohydrate related chemical profiles and CNCPS subfractions but it decreased rumen degradable carbohydrate. Rumen undegradable and intestinal digestion of CHO subfractions were not affected by moist heating. The advanced vibrational molecular spectroscopy can be used to detect carbohydrate molecular spectral features. Nutrient utilization prediction using molecular spectral characteristics is warranted and further investigation is encouraged.     

垄作稻鱼鸡共生对水稻群体生长特性及产量形成的影响

为了探究水稻垄作栽培和稻鱼鸡共生模式的结合对水稻群体生长特性及产量形成的影响，在总结前人垄作栽培、稻鱼和稻鸡共生模式的研究基础上，提出了水稻垄作栽培养鸡养鱼的种养结合技术，通过设计常规水稻垄作栽培(CK)、水稻垄作养鱼(RF)、水稻垄作养鸡(RC)和水稻垄作养鸡养鱼(RFC)的田间对比试验，研究了不同垄作稻鱼鸡共生模式下的水稻群体生长特性和产量形成。结果表明：与CK处理相比，2年中RFC和RC处理的水稻平均产量能够维持稳定，平均有效穗、每穗总粒数、结实率和千粒重虽有差异，但均未达到显著性差异；RF处理水稻产量、有效穗、每穗总粒数、结实率和千粒重平均降幅分别为29.98%、19.70%、484%、3.99%和5.74%，且均达到显著性水平。2年中RFC、RC处理的茎、叶和穗的干物质平均积累量与CK处理整体不存在显著差异，但较RF处理均显著增加。RFC、RC和CK处理水稻茎和叶在齐穗前干物质积累量显著高于RF处理，平均增幅分别为56.23%、50.66%和54.15%，齐穗后干物质积累量的降幅慢于RF处理，并且维持叶面积指数在较高水平，平均增幅为41.38%、38.35%和38.23%。2年中RFC、RC和CK处理较RF处理均具有较高的群体生长速率、净同化率和光合势，其中群体生长速率增幅分别为77.94%、70.29%和7669%，净同化率为40.07%、39.47%和38.87%，光合势为38.39%、35.49%和35.94%，进而为稻穗积累更多的干物质量和产量的形成奠定基础。综上可知，垄作稻鱼鸡共生和垄作稻鸡共生利于水稻的干物质积累及叶面积指数、群体生长速率、净同化率和光合势的提高，进而保证水稻产量稳定。     

江西省耕地土壤pH值和养分状况调查

按中国第二次土壤普查推荐的土壤养分和pH值的分级标准，对2014年江西省5个不同区域(赣南、赣北、赣中、赣西、赣东北)的94个县(市)具有代表性的4 188个耕地土壤的养分和pH值的测定数据进行比较分析，探明江西省耕地土壤养分及pH状况。结果表明：江西省耕地土壤pH值平均为5.3，偏酸性；赣南、赣北耕地土壤有机质质量分数均值分别为28.5、25.8 g/kg，属中等水平，而赣中、赣西和赣东北土壤有机质质量分数均值分别为31.9、33.9、31.1 g/kg，属较丰富水平；赣南土壤碱解氮质量分数均值为144.4 mg/kg，属较丰富水平，其他4个区域的均值均高于150 mg/kg，属丰富水平；赣南、赣中土壤有效磷质量分数均值分别为21.8、21.6 mg/kg，属较丰富水平，其他3个区域的属中等水平；5个区域土壤速效钾质量分数均值均在50～100 mg/kg，属较缺乏水平。可见，江西省耕地土壤酸化严重，养分极不平衡。     

基于PLSR-BP复合模型的红壤有机质含量反演研究

对红壤地区土壤有机质进行快速预测,以满足智慧农业与精准施肥的需要。以江西省奉新县北部为研究区域,采用1 km×1 km标准格网划分研究区进行采样,共得到红壤样本248个。对土壤光谱进行了包含分数阶导数在内的3种数学变换方法,将经过P=0.01显著性检验的波段用于模型的构建,选用偏最小二乘回归(PLSR)和BP神经网络建立土壤有机质含量预测模型。结果表明:当对红壤光谱数据进行1.5阶导数变换后再使用PLSR-BP复合模型对土壤有机质含量进行预测时的结果为最优,训练集R~2=0.89,RMSE=4.68g·kg~(-1),验证集R~2=0.87,RMSE=5.55g·kg~(-1),RPD=2.75。1.5阶导数对红壤光谱数据的变换能够更好地突出与有机质相关的特征信息,有助于其含量预测。PLSR-BP复合模型预测精度优于单一模型,能够较好地预测红壤有机质含量,为精准农业快速监测红壤有机质含量提供了新的途径。     

不同沟垄覆盖下土壤水热效应对旱作马铃薯生长及产量的影响

针对宁南山区春季降雨少、低温不利于马铃薯出苗,而作物生育中后期高温胁迫限制马铃薯块茎形成导致减产等问题,于2016年设置垄覆地膜沟内覆盖塑料地膜(DM)、玉米秸秆(JG)、生物降解膜(SM)、麻纤维地膜(MM)、液态地膜(YM)及沟不覆盖(BM),以传统平作为对照(CK),研究沟垄覆盖模式对土壤温度、土壤水分、旱作马铃薯生长及块茎产量的影响.结果表明:处理DM,SM,MM和YM马铃薯生育期耕层土壤温度表现出增温效应,而处理JG和BM表现为降温效应,其中处理DM增温效果和处理JG降温效果最佳.处理YM,JG对马铃薯生长前期保水效果较好,分别较CK显著提高13.3%,27.0%,而处理JG,DM对生育中后期的保墒效果较佳,分别较CK显著提高22.4%,13.2%.处理JG可显著促进马铃薯生长,其增产效果最为显著,DM次之,分别较CK增产47.8%,44.8%,其他处理较CK差异不具有统计学意义.可见,在宁南山区实施垄覆地膜沟覆秸秆模式可调控土壤水热环境,对旱作马铃薯生长及增产效果最佳.     

Vectorizing agrochemicals: enhancing bioavailability via carrier‐mediated transport

Systemicity of agrochemicals is an advantageous property for controlling phloem sucking insects, as well as pathogens and pests not accessible to contact products. After the penetration of the cuticle, the plasma membrane constitutes the main barrier to the entry of an agrochemical into the sap flow. The current strategy for developing systemic agrochemicals is to optimize the physicochemical properties of the molecules so that they can cross the plasma membrane by simple diffusion or ion trapping mechanisms. The main problem with current systemic compounds is that they move everywhere within the plant, and this non‐controlled mobility results in the contamination of the plant parts consumed by vertebrates and pollinators. To achieve the site‐targeted distribution of agrochemicals, a carrier‐mediated propesticide strategy is proposed in this review. After conjugating a non‐systemic agrochemical with a nutrient (α‐amino acids or sugars), the resulting conjugate may be actively transported across the plasma membrane by nutrient‐specific carriers. By applying this strategy, non‐systemic active ingredients are expected to be delivered into the target organs of young plants, thus avoiding or minimizing subsequent undesirable redistribution. The development of this innovative strategy presents many challenges, but opens up a wide range of exciting possibilities. © 2018 Society of Chemical Industry