Tracing Submarine Groundwater Discharge and Associated Nutrient Fluxes into Jiaozhou Bay by Continuous 222Rn Measurements
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摘要: 为了量化胶州湾东北海岸带的海底地下水排泄量和评价通过海底地下水排泄输入的营养盐数量,分别于2011年10月和2012年5月在胶州湾北岸东大洋码头附近对海水中的222Rn进行了48 h连续测量.通过构建测量点海水中222Rn质量平衡模型,计算得到海底地下水排泄速率平均值分别为6.38 cm/d和8.29 cm/d;实际观测到的海底地下水排泄速率变动较大,其主要控制因素是降水量、潮汐和波浪.根据海底地下水排泄速率,获得地下水输入的DIN(溶解无机氮)为47.0×103 mol/d(2011年10月)和48.6×103 mol/d(2012年5月),可溶性SiO2为15.5×103 mol/d(2011年10月)和17.3×103 mol/d(2012年5月),DIP(溶解性磷酸盐)为0.6×103 mol/d(2012年5月),地下水对胶州湾的营养盐输入具有重要贡献.Abstract: The aim of this paper is to quantify submarine groundwater discharge (SGD) into the northeast coast of Jiaozhou Bay, then estimate the SGD-derived nutrient fluxes. At Dongdayang dock located at the north shoreline of Jiaozhou Bay, the author deployed one in-situ 48 h continuous experiment for measuring 222Rn activity in seawater, in October 2011 and May 2012, respectively. Through establishing 222Rn mass balance model at the observing site, the average SGD rates are assessed to be 6.38 cm/d for October 2011 and 8.29 cm/d for May 2012. Measured results show the SGD rates fluctuate greatly, daily and seasonally, which are mainly controlled by precipitation, tidal pump and wave oscillation. Based on the SGD rates, the SGD-derived nutrient fluxes are calculated to be 47.0×103-48.6×103 mol/d for DIN (dissolved inorganic nitrogen), 15.5×103-17.3×103 mol/d for the soluble SiO2, and 0.6×103 mol/d for DIP (dissolved inorganic phosphorus), respectively. These SGD-derived nutrient fluxes contribute to the eutrophication in Jiaozhou Bay to a certain degree which need due attention.
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Key words:
- submarine groundwater discharge /
- radon-222 /
- nutrients /
- Jiaozhou Bay /
- submarine geology
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图 2 海水中222Rn活度与水深变化(时间:第1行是钟点(时: 分);第2行是日期(月-日))
Fig. 2. Variation of 222Rn activities in seawater and depth of water in the monitoring site
图 3 地下水中222Rn活度的时空变化
Fig. 3. Temporal and spatial variation of 222Rn activities in groundwater
图 4 连续测量点海水中226Ra活度及其变化(时间:第1行是钟点(时: 分);第2行是日期(月-日))
Fig. 4. Variation of 226Ra activities in seawater and depth of water in the monitoring site
图 5 连续测量点处大气损失与风速、水温(时间:第1行是钟点(时: 分);第2行是日期(月-日))
Fig. 5. Variation of atmospheric loss, wind velocity and water temperature in the monitoring site
图 6 222Rn的混合损失通量的估算(时间:第1行是钟点(时: 分);第2行是日期(月-日))
Fig. 6. Plot showing the method for estimating the mixing loss flux of 222Rn
图 7 海底地下水排泄速率(时间:第1行是钟点(时: 分);第2行是日期(月-日))
Fig. 7. Variation for the rate of submarine groundwater discharge during monitoring
表 1 沉积物孔隙水中222Rn活度
Table 1. 222Rn activities in the pore water of sediments
样品编号 SD1 SD2 SD3 SD4 SD5 SD6 SD7 SD8 沉积物(Bq/kg) 0.70 0.87 0.48 0.75 0.82 0.46 0.76 0.65 孔隙水(Bq/m3) 2 416.65 3 447.46 2 060.54 2 756.01 2 717.87 1 653.81 2 549.66 2 283.38 
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表 2 地下水中的营养盐浓度及估算通量
Table 2. Nutrients in groundwater and nutrient loadings
日期 水样 DIN(μM) DIN通量(103 mol/d) PO43-P(μM) PO43-P通量(103 mol/d) SiO2-Si(μM) SiO2-Si通量(103 mol/d) 2011年10月 G18 730.3 未检出 211.9 G19 744.1 未检出 273.3 平均值 737.2 47.0 242.6 15.5 2012年5月 G18 612.7 7.2 231.4 G19 559.1 7.5 186.3 平均值 585.9 48.6 7.4 0.6 208.9 17.3
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