浙江红花油茶高接换冠成活率影响因素研究

为研究浙江红花油茶高接换冠成活率影响因素,解决嫁接成活率低的问题,2013年6月从中国林业科学研究院亚热带林业研究所引进浙江红花油茶优树穗条,在青田县大垟山林场开展浙江红花油茶高接换冠试验,分析砧木林郁闭度、坡位、砧木生长势及接穗保存时间等因素对嫁接成活率的影响。结果表明,林分郁闭度在0.3~0.7之间,随着郁闭度增加嫁接平均成活率提高;郁闭度在0.7~0.9之间,随着郁闭度增加,嫁接成活率降低;当郁闭度为0.7时,嫁接成活率最高为88.8%。山腰的嫁接成活率高达86%,显著高于山顶和山脚。浙江红花油茶砧木生长势越强嫁接成活率越高。接穗于采集当天嫁接效果最好成活率达89.1%,接穗保存1、2、3、4、5、6天嫁接,成活率分别为85.2%、75.2%、51.6%、28.1%、12.2%、9.3%。偏相关分析表明,各因素对嫁接成活率影响由大到小依次为接穗保存时间(-0.97)、郁闭度(0.85)、生长势(0.81)、坡位(-0.65)。     

河北省优质棉育种70年回顾与展望

河北省优质陆地棉品种选育工作起步较早，新中国成立以来先后选育出石短5号、冀棉22号、冀棉26、新陆中8号、冀228、农大棉13号等高品质棉花品种和大量优质棉品种。根据不同时期的优质棉评价标准，对1949―2019年河北省选育的优质棉品种的纤维品质性状进行了统计和分析，结合纺织工业对优质原棉的需求，指出河北省优质棉育种存在的问题，并对未来的发展方向进行了展望。     

旱碱地增施叶面肥对减氮棉田冠层光分布及产量的影响

为了研究机采种植模式下不同水平减施氮肥后增施叶面肥对棉花花铃期冠层光分布、叶面积指数及与产量的影响，旱碱地条件下，设置0（CK）、60（N1）、90（N2）、120（N3）、150（N4）、180（N5，当地常规施氮量）、225 kg·hm^－2 （N6）7个施氮水平，其中N1～N4喷施叶面肥4次，测定花铃期群体叶面积指数（Leaf area index, LAI）、冠层光分布和籽棉产量。结果表明：与当地常规施氮量相比，减施（60～150 kg·hm^－2）氮肥后，棉花花铃期叶面积指数降低0.7%～5.5%，冠层光总截获率降低0.2～1.7百分点，冠层光透射率升高0.2～0.8百分点；各减施氮肥处理群体叶面积指数与冠层上层叶片的光截获率均呈显著正相关，与下层叶片的光截获率则呈负相关；籽棉产量随施氮量的减少而降低，二者有较高的相关性（R²＝0.990 5）。减氮（90～150 kg·hm^－2）增施叶面肥处理的LAI、冠层光总截获率、光透射率、冠层上下层叶片光截获率以及籽棉产量与当地常规施氮量180 kg·hm^－2处理差异均不显著。综上，旱碱地机采模式棉田增施叶面肥，对减施氮肥棉花花铃期冠层光分布、叶面积指数及籽棉产量有一定补偿作用。     

近红外光谱技术在家禽养殖领域应用现状

近红外光谱是一种快速光谱分析的新方法,伴随着光谱技术与化学计量法的发展,近红外光谱已广泛应用于农业、食品、医药、石油化工等行业,极大地提高了各行业信息化水平。基于近红外光谱在家禽养殖领域的应用现状,本文总结了近红外光谱技术的发展及其在饲料成分检测和禽肉检测中的应用。在饲料检测和家禽肉类检测方面,通过将禽肉样品的光谱信息与质量指标的参考值相关联,建立了预测饲料和待测肉类高精度、高稳定性的数学模型。与传统方法相比,近红外光谱技术具有信息量大、数据计算速度快等优点。本文还归纳了近红外光谱技术在饲料品质检测和肉类品质检测的应用现状,指出了近红外光谱在家禽养殖领域的大规模应用推广的可能性。同时指出近红外光谱技术存在的问题和未来发展方向,结果表明近红外光谱技术在饲料和畜产品检测领域具有良好的发展前景和应用价值。     

Prediction of Genetic Gain in Sweet Corn using Selection Indexes

Journal of Crop Science and Biotechnology - The cultivation of sweet corn is expanding in Brazil, but there are serious constraints about the availability of commercial cultivars. The selection of...     

The potential of mini-ridging for controlling intrarow weeds: estimating minimum lethal burial depth

Weed management using synthetic herbicides is undergoing a global decline, necessitating a re-evaluation of existing control measures and the development of novel weed management tools. ‘Mini-ridging’ is a non-discriminatory, physical weeding method that functions by burying weeds in the intrarow with a laterally shifted ridge of soil. In glasshouse trials using potted plants, we found that plant recovery after soil application was influenced by plant size, which in turn was influenced by plant species, developmental stage and/or age. The likelihood of plant recovery after soil application was negatively related to the depth of soil applied: very few plants survived total coverage by soil but, conversely, survival could be substantial if some parts of the plants were not covered. The results suggest that burial under a depth of 6 cm of soil would eliminate most plants regardless of species or growth stage. Larger plants would require the application of a greater total depth of soil to achieve this 6 cm of soil cover, and weed management would, therefore, tend to be more successful and more practical if weeds were targeted when still small. This research demonstrates the potential of plant burial as a simple and reliable means of non-chemical weed management, and re-emphasises that, for weed control to be effective, the applied soil layer must cover the whole plant.