10:15 〜 10:30
[ACG42-05] 短寿命放射性同位元素222Rnと224Raを用いた瀬戸内海沿岸域の海底地下水湧出量評価
キーワード:海底地下水湧出、ラジウム同位体、ラドン、瀬戸内海、沿岸域
Submarine groundwater discharge (SGD) is now recognized as an important pathway of water, nutrients and metals between terrestrial area and costal seas. It is well known that SGD is ubiquitous phenomenon compare to river discharge. Additionally, SGD is defined as constitution of fresh groundwater derived terrestrial area (FSGD) and saline groundwater derived seawater (RSGD). In order to evaluate terrestrial water budgets as water resources and nutrients dynamics in coastal seas, it is important to identify the ratio of FSGD and RSGD, and quantify both fluxes. Seepage meter is one of the approach for quantifying SGD and can evaluate reliable FSGD and RSGD. However, this method has disadvantage to expand the scale from local to regional. On the other hand, geochemical tracers showed integrated SGD signals, and thus they have been used to evaluate SGD in a variety of scale. Generally, 222Rn (t1/2=3.84 d) enriched in fresh and saline groundwater relative to surface water. Ra isotopes are enriched specifically in saline groundwater. Therefore, an estimate of SGD rates by 222Rn activity indicates total flux of SGD (FSGD+RSGD), while that by Ra isotopes would express the flux of RSGD. Combining approach of these short-lived isotopes, 222Rn and 224Ra, can provide the fluxes of FSGD and RSGD. In this study, to evaluate SGD rates by 222Rn and 224Ra, we have conducted simultaneous time-series measurements of short-lived 222Rn and 224Ra activities at two different SGD rates sites from 6 – 7 July 2017 in the central part to the Seto Inland Sea, Japan. Moreover, at both sites, we also quantify SGD, FSGD and RSGD rates using the seepage meter to verify the SGD rates estimated by 222Rn and 224Ra. Measured SGD rates by seepage meter at one site were 99.8±39.3 cm d-1, and at the other site were 4.9±6.5 cm d-1. The ratio of FSGD and RSGD in SGD by 222Rn and 224Ra (31.6% and 68.4%, respectively) showed similar value to these by seepage meter (11.7% and 88.3%, respectively) at the site with high SGD rates. At low SGD rates site, SGD rates by 222Ra (mean±SD=118.7±73.2 cm d-1) showed considerably high value against SGD rates measured by seepage meter (mean±SD=4.9±6.5 cm d-1), and the ratio of FSGD and RSGD in SGD by 222Rn and 224Ra (89.9% and 10.1%, respectively) showed different values from those by seepage meter (14.4% and 85.6%, respectively). Since an average of 222Rn activity in seawater at low SGD rates site (mean±SD=2.1±0.8 dpm L-1) was lower than offshore seawater (3.3 dpm L-1), overestimates of 222Rn-derived SGD may be due to lower 222Rn activity in seawater relative to in offshore seawater. These results suggested that coupling of 222Rn and 224Ra is convenient approach to quantify FSGD and RSGD in regional scale, except for circumstances showing lower geochemical tracers activities in seawater of study area relative to in offshore seawater.