白洋淀湖泊湿地中氮素分布的初步研究

湿地中氮素的空间分布在一定程度上反映了湿地环境变化的进程。对白洋淀3个典型淀区沉积物、孔隙水和上覆水中有机质和氮素进行分析,结果表明,白洋淀湖泊湿地沉积物中的有机质和全氮含量在垂直分布上表现出较好的一致性,均随深度增加而减少;但有机质和全氮分布存在空间差异性,英家淀的有机质和全氮含量均高于小杨家淀和小鸭淀;沉积物在6 cm深处,小杨家淀和小鸭淀沉积物中全氮出现一次低值,而所有采样点孔隙水中NH4 -N浓度都在此处出现一个峰值,表明6 cm深度可能是白洋淀湖泊湿地微生物降解有机氮的一个活跃区;芦苇湿地上覆水中NH4 -N和NO3--N含量都高于宽阔湖面水体,说明植被的生长不仅会促进底质有机氮的降解,其自身分泌的代谢产物及残枝败叶的腐烂也会增加水体中各种形态氮的含量,增加对水体中各种氮素的滞留,在芦苇湿地区对水面漂浮物的打捞和对芦苇的及时收割是减少湖泊湿地氮素输入的一种有效途径。     

田间施用硝化抑制剂DMPP对小青菜贮藏过程中硝酸盐与Vc含量的影响

采用田间施药方法,研究了施用硝化抑制剂3,4-二甲基吡唑磷酸盐(3,4-dimethylpyrazolephosphate,DMPP)对冰箱贮藏条件下小青菜可食部分硝酸盐、维生素C(Vc)含量变化的影响。结果表明,在贮藏过程中,施与不施DMPP2种处理小青菜硝酸盐含量呈现先降低后略有升高的趋势,Vc含量呈降低的趋势;DMPP在贮藏前期能够有效地降低硝酸盐含量,延缓Vc含量的降低。贮藏2d后,DMPP处理小青菜硝酸盐、Vc含量分别降低了74.4和9mg·kg-1,而对照处理分别降低了54.4和50mg·kg-1,处理间硝酸盐、Vc降幅差异均达5%显著水平。贮藏2～4d中,DMPP处理硝酸盐、Vc含量分别降低了20.1和91mg·kg-1,而对照处理分别降低了144.7和84mg·kg-1,处理间硝酸盐含量降幅差异达5%显著水平。贮藏4～6d中,对照处理硝酸盐含量升高了60.6mg·kg-1,DMPP处理升高了76.2mg·kg-1,Vc含量分别降低23和117mg·kg-1,且处理间降幅差异达5%显著水平。蔬菜贮藏时间不要过长,以不超过4d为宜。     

黄河流域氮素流失模数研究

氮素流失模数是研究区域氮循环与氮平衡的基本参数,对其进行研究有助于从大区域角度评价我国化肥的利用效率。按多年年径流量均值和多年河水氮浓度均值计算所得的黄河19个主要支流的流域氮素流失模数在0.073～1.665t·km-2·a-1,氮素流失模数的大小与区域人口和农业生产水平存在正相关性;由于存在“流域面积尺度效应”,使按干流数据计算得到的黄河流域的氮素流失模数显著地小于按支流资料计算得到的氮素流失模数;由于干流各站点控制的流域范围具有重叠性以及下游水质对上游水质有继承性,使按干流各站数据计算得到的氮素流失模数数值间差异不大;20世纪90年代以后黄河流域的氮素流失模数大大增加。中游头道拐站以上流域1995年的氮素流失模数比1985年增加4倍以上,下游花园口站以上流域1996年的氮素流失模数比1986年增加2倍以上;黄河流域流失的氮主要是以溶解态形式存在于水相中的氮素,流域氮素流失模数与泥沙径流模数之间无明显关系。以花园口站为控制点计算所得的黄河流域的氮素流失模数小于以大通站为控制点计算所得的长江流域的氮素流失模数。黄河流域的氮肥流失率(指黄河流域流氮素流失总量占流域氮肥总施入量的比例)在90年代后期有快速增加趋势,1998年比1997年增加12%,1999年又比1998年增加18%。我国     

药品选择及径流水样存放时间对总氮测定的影响

研究了国药集团、优耐德、Fluka的过硫酸钾药品以及水样存放时间对总氮含量测定的影响,结果表明:未经过提纯的3种药品均无法达到试验的要求,使用提纯后的Fluka过硫酸钾药品可达到总氮测定的要求;在-20℃环境下保持4个月径流水样总氮浓度无显著变化.     

基于APSIM模型的旱地春玉米施肥类型及氮肥用量研究

为探究玉米高产和减少硝态氮残留的合理施肥模式,通过山西寿阳旱地春玉米田间试验和APSIM模型模拟,研究不同施肥类型和施氮量对春玉米产量、硝态氮残留量和氮肥利用率的影响。田间试验设置3个施肥类型主处理,包括化肥单施、有机无机肥配施（配施比例1∶1）和有机肥单施;7个施肥梯度副处理,分别为0、50、100、150、200、250、300 kg·hm^-2,并利用2019—2021年试验站点数据对模型进行校准验证。结果表明：APSIM模型可以较好地模拟当地玉米产量和硝态氮残留量状况。各降水年型下,随氮肥施用量的增加,玉米产量先增加后减少,硝态氮残留量显著增加,氮肥利用率有所降低;相同施肥类型及施肥量下,丰水年的春玉米作物产量最高,硝态氮残留量最低,氮肥利用率最高;相同降水年型及施肥量下,有机无机肥配施方式的春玉米产量最高,硝态氮残留量居中,氮肥利用率最高。相较于化肥单施和有机肥单施方式,有机无机肥配施对于干旱地区玉米产量提升效果更好,其土壤硝态氮残留量对降水变化的敏感性相对较低,其氮肥利用率受降水影响也更小。综上,当施氮量介于148~168 kg·hm^-2时,有机无机肥配施方式下土壤硝态氮残留量维持在阈值内,春玉米产量可达到理论产量的95%左右,适宜在研究区域推广应用。     

基于Python的双过滤水肥一体机智能控制研究

为了满足不同生长时期植株水肥需求,基于基于Python的双过滤图像处理方法及环境监测技术,设计了可以自适应调节的水肥控制系统,主要包括氮肥含量控制和浇灌量控制.氮肥含量控制:首先,CCD摄头采集植株图像,应用Python的双过滤图像处理方法得到植株高度;其次,建立不同生长时期最高植株对应的氮肥浓度的曲线;再次,采用色度...     

Can hydrochar and pyrochar affect nitrogen uptake and biomass allocation in poplars?

Positive effects of pyrochar on soil nutrient availability and plant growth are widely reported in literature. However, few studies have reported effects of hydrochars on plant nutrition. A pot trial was conducted over a period of 2 years to investigate the effect of a pyrochar (AGT) and a hydrochar (HTC) on poplar (Populus × generosa , clone AF8) growth, biomass allocation and nitrogen (N) uptake with special emphasis on the quantification (using an isotopic mass balance approach) of char‐derived nitrogen (CDN) absorbed by plants. We found that both pyrochar and hydrochar positively affected above‐ground biomass productivity in the first year, and biomass and nitrogen (N) allocation over the 2 years by reducing the allocation of resources to fine roots. By the end of the experiment, even though the total N uptake was not affected by char, the CDN was more than 24% of the total N absorbed by HTC‐treated plants compared to a negligible amount absorbed by AGT‐treated ones. Finally, char did not affect nitrogen use efficiency (NUE) in the first year of growth, but by the end of the experiment, NUE was higher in the above‐ground biomass of HTC‐treated than in AGT‐ and control poplars.     

The critical N dilution curve for linseed (Linum usitatissimum L.) is different from other C3 species

The objective was to determine the critical N dilution curve of linseed, which is the minimal total N concentration in shoots necessary to produce the maximal shoot dry matter, and to explain possible differences with other C3 species. One main experiment was carried out in 1998/1999 on winter linseed with four levels of fertilizer N. Two plant densities were also studied, the recommended one (600 seeds m⁻²) and the minimum for canopy closure (150 seeds m⁻²), in order to investigate the stability with plant density of the critical N dilution curve. Shoot dry weights (W_S) and shoot N contents expressed in percentage (N_S) were measured for the determination of the critical dilution curve, along with organ N percentages and relative weights. The results of four other experiments were used to validate the critical N dilution curve. Three of these four trials were conducted on winter linseed (one in 1996/1997 and two in 1997/1998) with five levels of fertilizer N, and one on spring linseed in 1999 with six levels of fertilizer N.

The critical N dilution curve of linseed was different from those of other C3 species. The curve was steeper, indicating a greater decrease in the critical shoot N concentration (N_SC) as the critical shoot dry weight (W_SC) increased. This linseed curve determined with the data of the main experiment was relevant when compared to the data of the four other experiments. Organ weight ratios and N concentration of organs were investigated in a fertilizer N treatment resulting in N_S close to the critical N values, N_SC. In this treatment, the decrease in N_S was the result of both a decrease in the N percentage of all organs and a decrease in the leaf weight ratio. The difference between linseed and other C3 species was mainly due to an acceleration of the dilution of N when leaf emission stopped and the flower bud emission began. At this stage of development, the leaf weight ratio of linseed was less than that of wheat, resulting in lower N_S. For a given W_S, no significant differences in N_S, organ N percentages nor organ weight ratios were observed between the two plant densities. This indicates that the difference between linseed and other C3 species could not result from very high plant densities in linseed. Hence, it is concluded that the linseed N accumulation in shoot is different from other C3 species.     

Low sulfide concentrations affect nitrate transformations in freshwater and saline coastal retention pond sediments

Coastal areas in the southeastern USA are prone to hurricanes and strong storms that may cause salt-water influx to freshwater aquatic sediments. These changes in environmental conditions may impact sediment processes including nitrogen (N) cycling. The relative abilities of sediment microbial communities from two freshwater golf course retention ponds that drain into the adjacent wetlands, and two proximal saline wetland ponds, to remove nitrate (NO₃⁻) were compared to assess whether low concentrations of sulfide changed N-transformation processes. Microcosms were incubated with NO₃-N (300 μg g dw⁻¹) alone, and with NO₃-N and sulfide (H₂S) (100 and 200 μg g dw⁻¹). Nitrous oxide (N₂O), nitrite (NO₂⁻), NO₃⁻, ammonium (NH₄⁺), SO₄²⁻ and acid volatile sulfides were analyzed over time. The acetylene block technique was used to measure denitrification in sediment microcosms with no added H₂S. Denitrification was measured without acetylene (C₂H₂) addition in microcosms with added H₂S. With no added H₂S, denitrification was greater in the freshwater retention ponds than in the wetland ponds. Although low H₂S concentrations generally increased NO₃-N removal rates at all sites, lag periods were increased and denitrification was inhibited by low sulfide in the freshwater sediments, as evidenced by the greater concentrations of N₂O that accumulated compared to those in the wetland sediments. In addition to the inability of the freshwater sediments to convert N₂O to N₂ in the absence of C₂H₂, anomalously high transient NO₂-N concentrations accumulated in the retention pond samples. NH₄-N formation generally decreased due to H₂S addition at the freshwater sites; NH₄-N formation increased initially at the wetland sites, but was greater when no H₂S was added. Storm events that allow influx of SO₄²⁻-containing seawater into freshwater systems may change the dominant N species produced from nitrate reduction. Even low concentrations of sulfide produced incomplete denitrification and decreased formation of NH₄⁺ in these coastal freshwater sediments.     

Effects of partial replacement of nitrate with different nitrogen forms on the yield,quality and nitrate content of Chinese kale

In this study, the yields, nutritional qualities and nitrate (NO₃) content of Chinese kale were studied with two cultivars, following partial replacement of nitrate (20%) with ammonium (NH₄), urea and glycine in hydroponics. The results showed that, compared with the full nitrate treatment, ammonium replacement increased the fresh weight by 18.1% and 8.0% of ‘Zaobao’ and ‘Lvbao’ cultivars respectively, whereas urea and glycine replacements decreased the biomass significantly. Adding different nitrogen (N) forms significantly improved the contents of vitamin C, soluble sugar, free amino acid, protein, soluble phenol and flavonoids in Chinese kale. Adding the three alternative N forms also reduced nitrate content significantly, in which glycine replacement was the lowest. According to the results obtained, different forms of N replacement could be used for different purposes. Glycine replacement could be the best alternative only to improve qualities, while ammonium replacement could be the best alternative to improve both the yield and qualities.