Previous research has shown that starter fertilizer, a small amount of fertilizer placed with or near the seed at planting, often accelerates early season growth and increases biomass production, but does not always increase grain yield in corn (Zea mays L.). Our objective was to evaluate the effects of starter fertilizer on crop growth and development, as well as grain yield and moisture in continuous corn cropping systems. Treatments consisted of no fertilizer applied at planting (Control), a "Popup" application of 3.8 kg N ha-1 and 5.8 kg P ha-1 placed in-furrow with the seed (PU), an application of 19.8 (DPAC) or 28.1 kg N ha-1 (PPAC, NEPAC, and SEPAC) and 11.0 (PPAC), 5.8 (NEPAC), 7.7 (DPAC) or 6.1 (SEPAC) kg P ha-1 placed 5 cm to one side and 5 cm below (5x5) the seed (S), a combination of 3.8 kg N ha-1 and 5.8 kg P ha-1 applied in-furrow with 17.1 (DPAC) or 24.3 kg N ha -1 (PPAC, NEPAC, and SEPAC) and 9.4 (PPAC), 5.0 (NEPAC), 6.7 (DPAC) or 5.3 (SEPAC) kg P ha-1 applied 5x5 (P+S), and an application of 39.8 (DPAC) or 56.2 kg N ha-1 (PPAC, NEPAC, and SEPAC) and 21.9 (PPAC), 6.1 (NEPAC), 15.6 (DPAC) or 12.3 (SEPAC) kg P ha-1 placed 5x5 cm (SH). At the NEPAC location, 2.8 kg S ha-1 was applied across all treatments in the 5x5 cm position. The total N rate applied, but not P rate, was equalized across all treatments with variable sidedress N rates. The study was conducted in 2014 and 2015 at three locations, and in 2016 at four locations with varying weather conditions, soil types, and management practices.;Final plant population was generally unaffected by starter treatments. Crop growth and development responses to starter fertilizer treatments were similar across all locations. Starter fertilizer accelerated the rate of leaf collar appearance throughout the vegetative growth period, beginning as early as the one to two leaf collar stage (V1-V2). As the season progressed, phenological differences among the treatments increased even after total applied N was equalized with the sidedress N applications. Flowering and physiological maturity occurred sooner in the P+S and SH treatments than in the Control or PU treatments while in the S treatment, the timing of flowering was intermediate. In addition to increasing leaf collar appearance, starter fertilizer treatments that received at least 28 kg N ha-1 and 6 kg P ha-1 also increased the total number of leaves plant-1 produced at all four locations it was measured compared to the control. Ear leaf number was also increased by the addition of at least 28 kg ha-1 of N and between 6 and 15 kg P ha -1 at planting, but to a lesser extent than the total leaf number.;Dry matter increased 95% when plants received the SH treatment relative to the control while all other treatments had intermediate effects. In 2015, whole plants were sampled at the V6-V7 growth stage and whole plant nutrient concentrations generally decreased as the amount of N and P applied as starter fertilizer increased. In 2016, sampling was done earlier at the V4-V5 growth stage and the opposite was observed for N concentrations, but all other nutrients responded similar to 2015. Whole plant nutrient content was generally increased with starter fertilizer and was largely driven by dry matter accumulation differences. There were few instances in which ear leaf nutrient concentrations differed. At the locations in which they did, the trend was similar to the results from the whole plant sampling in that concentrations decreased as the amount of applied N and P increased at planting. Grain nutrient concentrations were the least effected by starter fertilizer and at locations in which a response occurred, results were variable.;The number of kernel rows ear-1 (KRE) was influenced by starter fertilizer at one of four locations where it was measured and was decreased by the two treatments in which the 5x5 cm placement was used. The total number of kernels ear-1 (TKE) was increased by starter fertilizer at two of four locations and at one location was decreased by the PU treatment. The two locations that did see an increase of TKE from starter fertilizer had a significant grain yield response at harvest. Kernel weights (KW) were decreased by adding at least 28 kg ha-1 and 6 kg P ha -1 of N at planting at one location, and were increased by the P+S treatment at another. No differences were observed at the remaining two locations. Both locations in which differing KW were observed also saw increased TKE. On average, grain moisture of the PU, S, P+S, and SH treatments were 6, 11, 14, and 17 g kg-1 lower than the control treatment. However, grain yield was increased by starter treatments at only 4 of the 10 locations. The PU treatment only increased yield at 1 of the 10 locations, increasing yield by 370 kg ha-1. Yield was increased by 497, 587, and 775 kg ha-1 on average when plants received the S, P+S, and SH treatments respectively compared to the control at the four responsive locations.
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机译:先前的研究表明,起子肥料是播种时与种子一起或靠近种子放置的少量肥料,通常会加速早期季节的生长并增加生物量的产量,但并不总是增加玉米的产量(Zea mays L.)。我们的目标是评估改良肥料对玉米生长和发育的影响,以及连续玉米种植系统中谷物的产量和水分。处理包括在播种时不施肥(对照),与种子(PU)一起放在沟中的3.8 kg N ha-1和5.8 kg P ha-1的“ Popup”施肥,19.8(DPAC)施肥或28.1 kg N ha-1(PPAC,NEPAC和SEPAC)和11.0(PPAC),5.8(NEPAC),7.7(DPAC)或6.1(SEPAC)kg P ha-1放置在一侧5厘米,下方5厘米( 5x5)种子(S),将3.8 kg N ha-1和5.8 kg P ha-1的组合与17.1(DPAC)或24.3 kg N ha -1(PPAC,NEPAC和SEPAC)和9.4一起施用(PPAC),5.0(NEPAC),6.7(DPAC)或5.3(SEPAC)kg P ha-1施加5x5(P + S),并施加39.8(DPAC)或56.2 kg N ha-1(PPAC,NEPAC)和SEPAC)和21.9(PPAC),6.1(NEPAC),15.6(DPAC)或12.3(SEPAC)kg P ha-1放置在5x5 cm(SH)上。在NEPAC位置,所有处理均以5x5 cm的位置施用2.8 kg S ha-1。在所有具有可变N含量的处理中,施加的总N值(而不是P值)相等。这项研究分别于2014年和2015年在三个地点进行,并于2016年在四个地点进行了不同的天气条件,土壤类型和管理措施。;最终植物种群通常不受启动剂处理的影响。在所有地点,作物对起子肥料的生长和发育反应都相似。从一到两个叶领期(V1-V2)开始,在整个营养生长期中,改良肥可加速叶领的出现速度。随着季节的进行,即使在总施氮量与氮肥施用量相等的情况下,各处理之间的物候差异也会增加。在P + S和SH处理中,开花和生理成熟比对照或PU处理要早,而在S处理中,开花的时间是中间的。除了增加叶领外观,与对照相比,接受至少28 kg N ha-1和6 kg P ha-1的发酵剂处理还增加了在所有四个位置生产的叶片植物1的总数。 。种植时,通过添加至少28 kg ha-1的N和6至15 kg P ha -1也增加了耳叶的数量,但幅度小于总叶数量。当干燥时,干物质增加了95%相对于对照,植物接受SH处理,而所有其他处理均具有中间效果。 2015年,在V6-V7的生长期对整株植物进行了采样,并且随着发酵剂肥料的施用,整株植物的养分浓度普遍随着氮和磷的施用量而降低。 2016年,在V4-V5生长阶段进行了更早的采样,氮含量却相反,但所有其他养分的响应与2015年相似。整株养分的含量一般都以起动肥提高,主要是由干物质积累驱动差异。在极少数情况下,耳叶养分浓度不同。在种植地点,其趋势与整个植物采样的结果相似,其浓度随着种植时氮和磷的施用量增加而降低。谷物养分浓度受起动剂肥料影响最小,并且在发生响应的位置结果是可变的。;在测量的四个位置之一,穗粒穗数(KRE)的数量受起动剂肥料的影响,并且通过使用5x5 cm放置的两种处理,减少了。在4个地点中的2个地点,通过起动施肥增加了1号仁的总数(TKE),而在PU处理中,在1个地点减少了1个仁的总数。确实从起始肥料中增加了TKE的两个地区在收获时都有明显的谷物增产响应。在一个地方种植时,通过添加至少28 kg ha-1和6 kg Pha -1来减少内核重量(KW),而在另一个地方通过P + S处理增加内核重量(KW)。在其余两个位置没有观察到差异。观察到KW的两个位置的TKE也都增加了。平均而言,PU,S,P + S和SH处理的谷物水分比对照处理低6、11、14和17 g kg-1。但是,仅在10个位置中的4个位置,通过启动处理增加了谷物产量。 PU处理仅增加了10个位置中的1个位置的产量,使产量增加了370 kg ha-1。与在四个响应位置的对照相比,分别接受S,P + S和SH处理的植物分别平均增产497、587和775 kg ha-1。
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