1. Role of biological activity in mediating acidification in a coastal upwelling zone at the east coast of Hainan Island.
- Author
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Dong, Xu, Huang, Haining, Zheng, Nan, Zhang, Junpeng, Wang, Sumin, Zhou, Kaiwen, Zhang, Yuanbiao, Ji, Weidong, Lin, Hui, and Pan, Aijun
- Subjects
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COASTS , *ACIDIFICATION , *DISSOLVED oxygen in water , *BIOLOGICAL productivity , *WATER acidification , *BIOLOGICAL interfaces - Abstract
Coastal upwelling that brings to the surface both CO 2 - and nutrient-rich deep seawater is related to acidification and intense biological productivities in surface waters. However, the impact of biological activities on upwelling-induced acidification from nearshore to offshore areas in an upwelling zone remains insufficiently known. In this paper, we present daily records of high-resolution profiles of carbonate chemistry and hydrographic parameters from the nearshore to the offshore upwelling zone off the east coast of Hainan Island (ECH) in July 2014 (summer season). A three end-member mixing model was adopted to discriminate biological processes from physical mixing and to further semiquantitatively diagnose biological contribution to the upwelling-induced acidification. The results show divergent responses in pH, aragonite saturation state (Ω Ar) and biomediated nonconservative dissolved inorganic carbon (ΔDIC) at depths of 10 m–30 m between nearshore and offshore regimes under the on-going coastal upwelling, which were attributed to the distinct roles of biological activities in mediating acidification in the upper 30 m across the ECH. Specifically, in the offshore regime, enhanced photosynthesis reduced the upwelling-induced acidification by 40% (i.e., type C: relief role), whereas aerobic respiration increased acidification in the subsurface waters of the nearshore regime by 15% (i.e., type B: aggravation role). This led to the pH and Ω Ar minimum in upwelled waters along the transect from the nearshore to the offshore. In contrast, the biological contribution was almost negligible over surface waters in the nearshore regime because of the balance between net community productivity and net community calcification (i.e., type A: limited or minor role). • Three types of biological contribution to upwelling-induced acidification are quantitatively revealed at the east coast of Hainan Island. • Behaviors of carbonate chemistry and dissolved oxygen in upwelled waters are distinct between the nearshore and offshore regimes. • Aerobic respiration intensifies acidification in the subsurface of the nearshore area during a coastal upwelling. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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