USEPA-Office of Research and Development, Environmental Sciences Division, Las Vegas, PO Box 93478, NV 89119, USA.
J Environ Manage. 2013 Jan 30;115:14-20. doi: 10.1016/j.jenvman.2012.10.028. Epub 2012 Dec 6.
Phosphorus (P) loss from agricultural fields is of environmental concern because of its potential impact on water quality in streams and lakes. The Mississippi Delta has long been known for its fish productivity and recreational value, but high levels of P in fresh water can lead to algal blooms that have many detrimental effects on natural ecosystems. Algal blooms interfere with recreational and aesthetic water use. However, few studies have evaluated P losses from agricultural watersheds in the Mississippi Delta. To better understand the processes influencing P loss, rainfall, surface runoff, sediment, ortho-P (orthophosphate, PO(4)-P), and total P (TP) were measured (water years 1996-2000) for two subwatersheds (UL1 and UL2) of the Deep Hollow Lake Watershed and one subwatershed of the Beasley Lake Watershed (BL3) primarily in cotton production in the Mississippi Delta. Ortho-P concentrations ranged from 0.01 to 1.0 mg/L with a mean of 0.17 mg/L at UL1 (17.0 ha), 0.36 mg/L at UL2 (11.2 ha) and 0.12 mg/L at BL3 (7.2 ha). The TP concentrations ranged from 0.14 to 7.9 mg/L with a mean of 0.96 mg/L at UL1, 1.1 mg/L at UL2 and 1.29 mg/L at BL3. Among the three sites, UL1 and UL2 received P application in October 1998, and BL3 received P applications in the spring of 1998 and 1999. At UL1, ortho-P concentrations were 0.36, 0.25 and 0.16 for the first, second and third rainfall events after P application, respectively; At UL2, ortho-P concentrations were 1.0, 0.66 and 0.65 for the first, second and third rainfall events after P application, respectively; and at BL3, ortho-P concentrations were 0.11, 0.22 and 0.09 for the first, second and third rainfall events after P application, respectively. P fertilizer application did influence P losses, but high P concentrations observed in surface runoff were not always a direct result of P fertilizer application or high rainfall. Application of P in the fall (UL1 and UL2) resulted in more ortho-P losses, likely because high rainfall often occurred in the winter months soon after application. The mean ortho-P concentrations were higher at UL1 and UL2 than those at BL3, although BL3 received more P application during the monitoring period, because P was applied in spring at BL3. However, tillage associated with planting and incorporating applied P in the spring (BL3) may have resulted in more TP loss in sediment, thus the mean TP concentration was the highest at BL3. Ortho-P loss was correlated with surface runoff; and TP loss was correlated with sediment loss. These results indicate that applying P fertilizer in the spring may be recommended to reduce potential ortho-P loss during the fallow winter season; in addition, conservation practices may reduce potential TP loss associated with soil loss.
农田中磷的损失引起了人们对环境的关注,因为它可能会对溪流和湖泊的水质造成影响。密西西比三角洲地区以其鱼类产量和娱乐价值而闻名,但淡水中的高磷水平会导致藻类大量繁殖,这对自然生态系统有许多不利影响。藻类大量繁殖会干扰娱乐和美学用水。然而,很少有研究评估密西西比三角洲农业流域的磷损失。为了更好地了解影响磷损失的过程,对密西西比三角洲 Deep Hollow 湖流域的两个子流域(UL1 和 UL2)和 Beasley 湖流域的一个子流域(BL3)进行了降雨、地表径流、泥沙、正磷酸盐(orthophosphate,PO4-P)和总磷(TP)的测量(1996-2000 水年),这些子流域主要用于棉花生产。正磷酸盐浓度范围为 0.01-1.0mg/L,平均值为 0.17mg/L(UL1,17.0ha),0.36mg/L(UL2,11.2ha)和 0.12mg/L(BL3,7.2ha)。TP 浓度范围为 0.14-7.9mg/L,平均值为 0.96mg/L(UL1)、1.1mg/L(UL2)和 1.29mg/L(BL3)。在这三个地点中,UL1 和 UL2 于 1998 年 10 月施磷,BL3 于 1998 年和 1999 年春季施磷。在 UL1,正磷酸盐浓度分别为 0.36、0.25 和 0.16,这是施磷后第一次、第二次和第三次降雨事件;在 UL2,正磷酸盐浓度分别为 1.0、0.66 和 0.65,这是施磷后第一次、第二次和第三次降雨事件;在 BL3,正磷酸盐浓度分别为 0.11、0.22 和 0.09,这是施磷后第一次、第二次和第三次降雨事件。磷肥的施用确实会影响磷的损失,但地表径流中高浓度的磷并不总是磷肥施用或高降雨的直接结果。秋季(UL1 和 UL2)施磷导致更多的正磷酸盐损失,可能是因为冬季经常有高降雨,而且在施磷后不久就发生了。尽管在监测期间 BL3 施磷量更多,但 UL1 和 UL2 的平均正磷酸盐浓度高于 BL3,因为 BL3 的磷是在春季施的。然而,与春季种植和施入土壤相关的耕作(BL3)可能导致更多的 TP 随泥沙流失,因此 BL3 的平均 TP 浓度最高。正磷酸盐的损失与地表径流有关;而 TP 的损失与泥沙损失有关。这些结果表明,春季施磷可能有助于减少秋季休耕期潜在的正磷酸盐损失;此外,保护措施可能会减少与土壤流失相关的潜在 TP 损失。
