植物纤维毯道路边坡防护技术综合效益评价

为系统评价植物纤维毯水土保持作用对不同雨强的响应以及改良土壤的作用,开展了人工模拟降雨试验和野外小区监测,在模拟降雨试验中,设计4个雨强,测试3种植物纤维毯,降雨历时均为60min。在降雨过程中以5min为间隔收集径流泥沙,并测定径流量和侵蚀泥沙量。在野外小区监测中,通过2007,2010,2013年施工的稻草毯小区,以及2014年施工的椰丝毯、椰丝稻草混合毯和稻草毯小区,评价土壤理化性质对植物纤维毯铺设年限和类型的响应差异。结果表明:在47mm/h及以上雨强下,椰丝毯、椰丝稻草混合毯和稻草毯均能有效减少侵蚀和产流,平均减蚀效益分别为94.92%,86.06%,83.42%,平均减流效益分别为31.59%,45.02%,52.44%,减蚀效益显著优于减流效益。3种植物纤维毯均在47mm/h雨强下减蚀效益和减流效益达到最高,其中最高减蚀效益为椰丝毯(97.54%),最高减流效益为椰丝稻草混合毯(88.26%)。随着雨强增大,减蚀效益和减流效益均不同程度降低,且减流效益降低更快。随着植物纤维毯铺设年限延长,土壤理化性质逐渐改善;铺设1年后,椰丝稻草混合毯改土效果最佳。     

乡土野花组合在农业景观中的应用

乡土野花组合是筛选以乡土野花为主体的,并通过混合播种建立群落的一种景观植被建植模式,是欧美国家近年来较为流行的一种农业景观恢复与建设的技术措施。已有的研究发现乡土野花组合能够改善景观结构与生境质量,吸引传粉生物和自然天敌,从而起到增强农业景观的传粉及害虫控制功能,并改善农作物品质、提高农作物产量;与此同时,乡土野花组合也具有较好的文化功能。乡土野花组合的设计对建植效果具有重要作用,其物种筛选、配比、播种方式及布局是设计中需要主要解决的问题。本文在总结欧美国家乡土野花组合设计模式与生态监测结果的基础上,提出乡土野花组合物种筛选的3原则：乡土性、功能多样性与包含特定关键物种;并对其生长周期、物种数、播量、播种面积与空间布局等技术细节进行了讨论,以促进乡土野花组合的本土化、区域化发展。欧美国家提出了一系列推动产业发展及农户补贴的有关政策,其中美国主要以推动基础研究与产业发展政策为主,注重限制植物材料本土化;欧洲国家通过多项立法及农业环境管护政策为农户提供多样化的生态补贴,以促进农户充分参与乡土野花组合栽植过程。在我国,尚缺乏成熟的乡土野花组合应用案例。中国的乡土野花组合需充分发掘种质资源并进行生态、栽培与景观特性评估,以实现本土化的乡土野花组合。本文最后提出,通过多学科合作实现乡土野花组合的设计与推广,政府、产业、科研机构与农民共同参与乡土野花组合的设计过程,并提出市场化的生态补贴政策,以推动乡土野花组合在我国农业景观的应用,为改善我国农业生态环境做出应有贡献。     

黄顶菊入侵对土壤氨氧化古菌群落多样性的影响

为了明确入侵植物黄顶菊对土壤氮循环关键过程硝化作用的影响机制,本研究通过对其入侵地和未入侵地、根围土和根际土氨氧化古菌(ammonia-oxidizing archaea,AOA)的群落多样性分析,探讨了AOA对黄顶菊入侵的响应规律。结果表明:黄顶菊入侵增加了入侵地根围土AOA的多样性,AOA的Shannon指数表现为:入侵地根围土入侵地根际土未入侵地土壤,且差异显著。铵态氮含量与p H的变化都会影响土壤AOA的群落结构。系统发育树分析表明,土壤AOA主要隶属于氨氧化古菌的Nitrososphaera cluster。黄顶菊入侵导致的AOA的多样性水平的提升主要是由于入侵地氨氧化菌群种类增加所致。     

4种水生植物深度净化村镇生活污水厂尾水效果研究

通过设置动态模拟试验,持续进水、出水条件下分析比较了漂浮植物凤眼莲和水浮莲、沉水植物轮叶黑藻和挺水植物黄菖蒲对村镇生活污水厂(一级A标准)尾水深度净化效果,筛选出具有去污效果优势的水生植物,为优化水生植物生态修复工程技术在尾水深度净化中的应用提供依据。结果表明:经水生植物深度净化后,尾水水质得到明显改善,漂浮植物凤眼莲和水浮莲对尾水氮、磷的净化效果优于挺水植物黄菖蒲和沉水植物轮叶黑藻。试验周期内,污水厂尾水总氮、总磷和高锰酸盐指数(CODMn)平均浓度为12.22 mg?L-1、0.38mg?L-1和3.88 mg?L-1,凤眼莲、水浮莲、轮叶黑藻、黄菖蒲和对照各系统的总氮平均去除率分别为46.25%、45.74%、43.41%、38.39%和29.22%,总磷去除率分别为36.84%、34.21%、31.58%、28.95%和26.32%,CODMn去除率分别为42.27%、30.93%、32.47%、32.47%和37.89%。凤眼莲、水浮莲、黄菖蒲和轮叶黑藻生物量净增长率分别为550.5%、418.8%、210.6%和80.3%,凤眼莲生物量净增率最大。各处理系统内凤眼莲、水浮莲、黄菖蒲和轮叶黑藻对尾水氮富集量分别为7.36 g、2.33 g、5.12 g和4.46 g,对磷的富集量分别为0.60 g、0.19 g、0.33 g和0.78 g,凤眼莲富集氮能力优于另外3种水生植物,轮叶黑藻磷富集量高于另外3种水生植物。凤眼莲、水浮莲、黄菖蒲和轮叶黑藻植株吸收作用对尾水总氮去除的表观贡献率分别为15.29%、4.90%、11.17%和11.34%,对尾水总磷去除的表观贡献率分别为50.34%、17.17%、35.24%和76.34%。因此,可利用漂浮植物凤眼莲和沉水植物轮叶黑藻立体复合种养的方式深度净化生活污水厂尾水。     

国外农业航空静电喷雾技术研究进展与借鉴

农业航空静电喷雾技术作为中国发展精准农业航空应用技术的内容之一,对农药的有效利用和减少环境污染有积极意义.农业航空静电喷雾技术在国外发展较早也相对成熟,美国已有应用于有人机的商业化产品,并在美国、巴西等国各类粮食作物、经济作物和杂草防治作业中开展了大规模田间应用.该研究首先从基础研究、田间应用和优化工作等方面梳理了国外...     

Development of a plant conveyance system using an AGV and a self-designed plant-handling device: A case study of DIY plant phenotyping

Plant phenotyping technology has been actively developed in recent years, but the introduction of these technologies into the field of agronomic research has not progressed as expected, in part due to the need for flexibility and low cost. “DIY” (Do It Yourself) methodologies are an efficient way to overcome such obstacles. Devices with modular functionality are critical to DIY experimentation, allowing researchers flexibility of design. In this study, we developed a plant conveyance system using a commercial AGV (Automated Guided Vehicle) as a case study of DIY plant phenotyping. The convey module consists of two devices, a running device and a plant-handling device. The running device was developed based on a commercial AGV Kit. The plant-handling device, plant stands, and pot attachments were originally designed and fabricated by us and our associates. Software was also developed for connecting the devices and operating the system. The run route was set with magnetic tape, which can be easily changed or rerouted. Our plant delivery system was developed with low cost and having high flexibility, as a unit that can contribute to others’ DIY’ plant research efforts as well as our own. It is expected that the developed devices will contribute to diverse phenotype observations of plants in the greenhouse as well as to other important functions in plant breeding and agricultural production.     

3D modeling and reconstruction of plants and trees: A cross-cutting review across computer graphics,vision, and plant phenotyping

This paper reviews the past and current trends of three-dimensional (3D) modeling and reconstruction of plants and trees. These topics have been studied in multiple research fields, including computer vision, graphics, plant phenotyping, and forestry. This paper, therefore, provides a cross-cutting review. Representations of plant shape and structure are first summarized, where every method for plant modeling and reconstruction is based on a shape/structure representation. The methods were then categorized into 1) creating non-existent plants (modeling) and 2) creating models from real-world plants (reconstruction). This paper also discusses the limitations of current methods and possible future directions.     

高寒草甸植物叶片生态化学计量特征对长期氮肥添加的响应

氮(N)是植物生长发育所需的基本元素,人为N添加已成为陆地生态系统N输入的主要形式。施N作为改善土壤养分条件的重要途径,可改变土壤理化性质,也会对植物叶片生态化学计量特征产生影响。本研究在2012年5月设置0(CK)、10(N₁₀)、20(N₂₀)、30(N₃₀)g·m^-2·a^-1的N添加试验,并于2018年8月采集禾本科、莎草科、豆科和杂类草叶片,测定其碳(C)、N、磷(P)含量,分析不同水平N添加下植物叶片生态化学计量特征的差异,探索长期N添加下植物叶片生态化学计量特征变化的影响因素。结果表明:1)N添加显著提高了禾本科叶片碳(LC)含量而显著降低了豆科LC含量(P<0.05),莎草科和杂类草LC含量变化不显著(P>0.05)。随施N量增加,4种功能群叶片氮(LN)含量均显著增加(P<0.05),而叶片磷(LP)含量变化趋势不一致。2)N添加下4种功能群植物叶片碳氮比(LC/N)整体呈下降趋势,叶片氮磷比(LN/P)和叶片碳磷比(LC/P)呈上升趋势。3)...     

抑制荸荠中多酚氧化酶活性的研究

通过单因素及多因素试验,探讨抑制荸荠中多酚氧化酶活性的效果。L_9(3~3)正交试验结果表明:柠檬酸预煮液的质量分数0.5%,预煮温度100℃,预煮时间5 min为最优预煮条件。     

Cotton Chemical Topping by Applying DPC in Different Cotton-Growing Regions

[Objective] The objective of this study was to investigate the stability and universality of cotton chemical topping by applying mepiquat chloride (1,1-dimethyl-piperidinium chloride, DPC) in different cotton-growing regions. [Method] Field experiments were conducted in 2018 at 10 locations in the Yellow River basin (Hejian and Handan, Hebei province; Dezhou and Wudi, Shandong province), the Yangtze River basin (Dafeng, Jiangsu province; Huanggang, Hubei province), and Xinjiang area (Shihezi location I and loacation II, northern Xinjiang and Luntai and Shaya, southern Xinjiang). Local cultivars/lines were used, and the experiments were performed using a randomized complete block design with three or four replicates. Accompanied with typical DPC multi-application in each location, chemical topping was conducted at 10 days before manual topping (T1) or at the same time with manual topping (T2) by applying four dosages of DPC (0, 90, 180, 270 g·hm^－2), manual topping was used as the first control and non-topping as the second control. [Result] The time of chemical topping significantly affected cotton plant height (except for the results in Handan, Dezhou and Wudi) and the number of fruit branches (except for the results in Dafeng and Huanggang). It was observed that earlier chemical topping would result in lower cotton plant height and a fewer fruit branches. In Hejian and Shihezi location I, the average plant height across DPC chemical topping at T1 stage was not only lower than that of T2 stage but also 3.3 cm and 4.6 cm lower than that of manual topping, respectively. In most locations, chemical topping at T1 stage increased around two fruit branches per plant compared with manual topping, while in T2 stage the increased fruit branches per plant ranged from 2.3 to 7.7. Also, we found that a higher dosage of DPC resulted in shorter plant height (except for that in Huanggang). In some locations, plant heights of chemical topping with 180 g·hm^－2 or 270 g·hm^－2 DPC were even shorter than that of manual topping. The number of fruit branches per plant of 0 g·hm^－2 DPC increased by 2.4-8.3 compared with manual topping. However, chemical topping with 90-270 g·hm^－2 DPC significantly reduced the number of fruit branches compared with 0 g·hm^－2 DPC. There were no significant differences in the number of fruit branches among three DPC dosages (90, 180, and 270 g·hm^－2). In Handan, seed cotton yield of chemical topping at T2 stage was significantly lower than that of manual topping due to the decreased boll number, which is possibly associated with the high temperature and drought weather after chemical topping. While at other locations, most treatments of chemical topping by using DPC did not produce significant effects on yield. In addition, chemical topping by using DPC did not delay cotton maturity, characterized by their similar boll-opening rate and the first harvest rate to those of manual topping before spraying harvest aids. [Conclusion] Cotton chemical topping with DPC is more stable and universal across different cotton-growing regions. We suggest that 90-180 g·hm^－2 DPC could be used at the same time with manual topping for cotton chemical topping.