Zhejiang University, Ocean College, 1# Zheda Road, Zhoushan, Zhejiang 316021, China.
King Abdullah University of Science and Technology (KAUST), Red Sea Research Center (RSRC), Thuwal 23955-6900, Saudi Arabia.
Sci Total Environ. 2021 Jul 1;776:145192. doi: 10.1016/j.scitotenv.2021.145192. Epub 2021 Feb 10.
Seaweed farming has been proposed as a strategy for adaptation to ocean acidification, but evidence is largely lacking. Changes of pH and carbon system parameters in surface waters of three seaweed farms along a latitudinal range in China were compared, on the weeks preceding harvesting, with those of the surrounding seawaters. Results confirmed that seaweed farming is efficient in buffering acidification, with Saccharina japonica showing the highest capacity of 0.10 pH increase within the aquaculture area, followed by Gracilariopsis lemaneiformis (ΔpH = 0.04) and Porphyra haitanensis (ΔpH = 0.03). The ranges of pH variability within seaweed farms spanned 0.14-0.30 unit during the monitoring, showing intense fluctuations which may also help marine organisms adapt to enhanced pH temporal variations in the future ocean. Deficit in pCO in waters in seaweed farms relative to control waters averaged 58.7 ± 15.9 μatm, ranging from 27.3 to 113.9 μatm across farms. However, ΔpH did not significantly differ between day and night. Dissolved oxygen and Ω were also elevated in surface waters at all seaweed farms, which are benefit for the survival of calcifying organisms. Seaweed farming, which unlike natural seaweed forests, is scalable and is not dependent on suitable substrate or light availability, could serve as a low-cost adaptation strategy to ocean acidification and deoxygenation and provide important refugia from ocean acidification.
海藻养殖被提议作为一种适应海洋酸化的策略,但证据主要缺乏。在收获前的几周,比较了中国三个海藻养殖场沿纬度范围的表层海水与周围海水的 pH 值和碳系统参数变化。结果证实,海藻养殖在缓冲酸化方面非常有效,其中,养殖区内的紫菜(Saccharina japonica)具有最高的 pH 值增加能力,为 0.10,龙须菜(Gracilariopsis lemaneiformis)为 0.04,坛紫菜(Porphyra haitanensis)为 0.03。在监测期间,海藻养殖场内的 pH 值变化范围为 0.14-0.30 单位,显示出强烈的波动,这也可能有助于海洋生物适应未来海洋中增强的 pH 值时变。与对照水相比,海藻养殖场水中的 pCO2 亏缺平均为 58.7 ± 15.9 μatm,跨养殖场范围为 27.3-113.9 μatm。然而,pH 值在白天和黑夜之间没有显著差异。溶解氧和 Ω 在所有海藻养殖场的表层水中也升高,这有利于钙化生物的生存。与天然海藻林不同,海藻养殖是可扩展的,不依赖于合适的基质或光照可用性,它可以作为一种适应海洋酸化和缺氧的低成本策略,并为海洋酸化提供重要的避难所。
