Denitrification is a microbial process of anaerobic respiration in which nitrate (NO3-) is chemically reduced to gaseous nitrous oxide (N2O) and molecular N2. Fertilizer N can be lost to the atmosphere through this process. Subsurface drip irrigation may create favorable conditions for denitrification, such as high moisture and NO3- content. The objectives of this research were to: (1) determine the denitrification rate in drip-irrigated cauliflower and sweet corn crops; (2) evaluate the effect of soil water tension on the denitrification rate, and; (3) estimate an N balance under subsurface drip irrigation, including denitrification losses. Two field experiments with subsurface drip-irrigated cauliflower were conducted during the 1996–98 winter growing seasons at the Maricopa Agricultural Center, in Maricopa, AZ. An additional study with subsurface drip-irrigated sweet corn was conducted at the Campus Agricultural Center in Tucson, AZ. All the experiments were complete factorial designs with two soil water tension levels (low, high), two levels of N fertilizer (zero, adequate), and three replications. The denitrification rates evaluated at ambient temperature were <12 g N ha-1 d-1 during the cauliflower winter seasons. When soil cores taken during the 1997–98 winter season were incubated at room temperature (24 ± 2°C), denitrification rates were five to 50 times higher than the rates evaluated at ambient temperature. The denitrification rate measured at room temperature in the cauliflower winter season was similar to the rate observed in the sweet corn during summer. Soil cores from the cauliflower 1997–98 season that received 100 kg N ha-1 had denitrification rates from 10 to 45 g N ha-1 d-1 ; when these cores were amended with additional soluble carbon, the denitrification rate increased to 800 to 3500 g N ha-1 d -1. All of the three experiments showed higher denitrification rates at the end of the season. This trend coincided with increases in denitrifying enzyme activity and soluble organic carbon. The denitrification loss of fertilizer N was <1% in cauliflower and almost 2% in summer sweet corn, when irrigated at the higher soil water tension. Lower soil water tension did not increase the denitrification rate in the winter, but in the summer the loss of N due to denitrification increased to almost 6% of the applied N.
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机译:反硝化是厌氧呼吸的微生物过程,其中硝酸盐(NO3-)化学还原为气态一氧化二氮(N2O)和分子N2。氮肥可以通过这个过程散发到大气中。地下滴灌可能为反硝化创造有利条件,例如高水分和NO3-含量。这项研究的目的是:(1)确定滴灌花椰菜和甜玉米作物的反硝化率; (2)评估土壤水分张力对反硝化率的影响;以及(3)估算地下滴灌下的氮平衡,包括反硝化损失。在亚利桑那州马里科帕市的马里科帕农业中心,在1996–98冬季生长季节期间,进行了地下滴灌花椰菜的两个田间试验。在亚利桑那州图森的校园农业中心进行了地下滴灌甜玉米的另一项研究。所有实验都是完整的因子设计,具有两个土壤水分张力水平(低,高),两个氮肥水平(零,足够)和三个重复。花椰菜冬季期间,在环境温度下评估的反硝化速率为<12 g N ha-1 d-1。当在1997–98冬季采集的土壤核心在室温(24±2°C)下孵育时,反硝化速率比在环境温度下评估的速率高5至50倍。在花椰菜冬季在室温下测得的反硝化率与夏季在甜玉米中观察到的率相似。 1997-98年花椰菜的土壤核心接受100 kg N ha-1的反硝化速率为10到45 g N ha-1 d-1。当这些核用其他可溶性碳进行修正时,反硝化速率增加到800至3500 g N ha-1 d -1。这三个实验均显示在季末反硝化率较高。该趋势与反硝化酶活性和可溶性有机碳的增加相吻合。在较高的土壤水分压力下灌溉时,花椰菜中氮素的反硝化损失小于1%,夏季甜玉米中氮的反硝化损失几乎为2%。较低的土壤水分张力并没有增加冬季的反硝化率,但在夏季,由于反硝化作用而导致的氮损失增加到所施用氮的近6%。
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