The impacts of long-term flow reductions and an extreme drought on a large, permanently open estuary, and implications for setting the ecological reserve

IF 1 4区环境科学与生态学 Q4 WATER RESOURCES

Water SA Pub Date : 2022-04-27 DOI:10.17159/wsa/2022.v48.i2.3927

Barry M Clark, Jane K Turpie, James DS Cullis, Jessica Dawson, Louise Dobinson, Marlé M Kunneke, Annabel Horn

{"title":"The impacts of long-term flow reductions and an extreme drought on a large, permanently open estuary, and implications for setting the ecological reserve","authors":"Barry M Clark, Jane K Turpie, James DS Cullis, Jessica Dawson, Louise Dobinson, Marlé M Kunneke, Annabel Horn","doi":"10.17159/wsa/2022.v48.i2.3927","DOIUrl":null,"url":null,"abstract":"Environmental water requirements (EWRs) are set for South Africa’s estuaries to ensure that they are maintained in a state that is both achievable and commensurate with their level of conservation and economic importance. However, these EWRs are typically determined on the basis of models and scenario analyses that require extrapolation beyond existing data and experience, especially if climate change is considered. In the case of the Berg Estuary, South Africa, available data on changes in freshwater flow and water quality span a period of at least five decades (1970s–present) during which significant reduction in flows has been observed. Monitoring data also cover an extreme 3-year drought, from 2015−2017, which provided a unique opportunity to study the effects of severe freshwater starvation (zero-flow for an extended period) on this large, permanently open system. Our analyses show that mean annual runoff (MAR) under present-day conditions has been reduced to around 50% of that under reference (natural) conditions and that reduction in runoff during the low-flow season (summer) has been more severe (80–86% reduction) than for the high-flow season (39–42% reduction). The salinity gradient now extends much further upstream than under reference conditions. Hypersaline conditions along with a reverse salinity gradient were recorded in the estuary for the first time ever during the drought of 2015/17. Levels of dissolved inorganic nitrogen (NOx) reaching the estuary from the catchment have increased dramatically (6–7 fold) over the past five decades, dissolved reactive phosphate (PO4) slightly less so (2–3 fold), but ammonia (NH4) hardly at all. Increases in nutrient input from the catchment in the high-flow season are also much more dramatic than in the low-flow season. The estuary is no longer compliant with gazetted EWRs and requires urgent interventions to restore the quantity and quality of freshwater it receives. \n ","PeriodicalId":23623,"journal":{"name":"Water SA","volume":"36 6 1","pages":""},"PeriodicalIF":1.0000,"publicationDate":"2022-04-27","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Water SA","FirstCategoryId":"93","ListUrlMain":"https://doi.org/10.17159/wsa/2022.v48.i2.3927","RegionNum":4,"RegionCategory":"环境科学与生态学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"WATER RESOURCES","Score":null,"Total":0}

引用次数: 2

Abstract

Environmental water requirements (EWRs) are set for South Africa’s estuaries to ensure that they are maintained in a state that is both achievable and commensurate with their level of conservation and economic importance. However, these EWRs are typically determined on the basis of models and scenario analyses that require extrapolation beyond existing data and experience, especially if climate change is considered. In the case of the Berg Estuary, South Africa, available data on changes in freshwater flow and water quality span a period of at least five decades (1970s–present) during which significant reduction in flows has been observed. Monitoring data also cover an extreme 3-year drought, from 2015−2017, which provided a unique opportunity to study the effects of severe freshwater starvation (zero-flow for an extended period) on this large, permanently open system. Our analyses show that mean annual runoff (MAR) under present-day conditions has been reduced to around 50% of that under reference (natural) conditions and that reduction in runoff during the low-flow season (summer) has been more severe (80–86% reduction) than for the high-flow season (39–42% reduction). The salinity gradient now extends much further upstream than under reference conditions. Hypersaline conditions along with a reverse salinity gradient were recorded in the estuary for the first time ever during the drought of 2015/17. Levels of dissolved inorganic nitrogen (NOx) reaching the estuary from the catchment have increased dramatically (6–7 fold) over the past five decades, dissolved reactive phosphate (PO4) slightly less so (2–3 fold), but ammonia (NH4) hardly at all. Increases in nutrient input from the catchment in the high-flow season are also much more dramatic than in the low-flow season. The estuary is no longer compliant with gazetted EWRs and requires urgent interventions to restore the quantity and quality of freshwater it receives.

查看原文本刊更多论文

长期流量减少和极端干旱对大型永久开放河口的影响及其对生态保护区设置的启示

为南非河口设定了环境用水要求(EWRs)，以确保它们保持在既可实现又与其保护和经济重要性水平相称的状态。然而，这些低水耗通常是在模式和情景分析的基础上确定的，需要在现有数据和经验之外进行外推，特别是在考虑气候变化的情况下。以南非的贝格河口为例，有关淡水流量和水质变化的现有数据至少跨度50年(1970年代至今)，在此期间观察到流量显著减少。监测数据还涵盖了2015年至2017年的三年极端干旱，这为研究严重淡水饥饿(长时间零流量)对这个大型永久开放系统的影响提供了独特的机会。我们的分析表明，在当前条件下，平均年径流量(MAR)已减少到参考(自然)条件下的50%左右，并且在低流量季节(夏季)的径流量减少更为严重(减少80-86%)，而在高流量季节(减少39-42%)。盐度梯度现在比参考条件下向上游延伸得更远。在2015/17年干旱期间，河口首次记录到高盐条件和反向盐度梯度。在过去的50年里，从集水区到达河口的溶解无机氮(NOx)的水平急剧增加(6-7倍)，溶解活性磷酸盐(PO4)的水平略有减少(2-3倍)，但氨(NH4)几乎没有增加。在高流量季节，来自集水区的养分输入的增加也比低流量季节显著得多。河口已不符合宪报公布的低水位计划，需要紧急干预，以恢复其接收的淡水的数量和质量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Water SA 环境科学-水资源

CiteScore

2.80

自引率

6.70%

发文量

审稿时长

18-36 weeks

期刊介绍： WaterSA publishes refereed, original work in all branches of water science, technology and engineering. This includes water resources development; the hydrological cycle; surface hydrology; geohydrology and hydrometeorology; limnology; salinisation; treatment and management of municipal and industrial water and wastewater; treatment and disposal of sewage sludge; environmental pollution control; water quality and treatment; aquaculture in terms of its impact on the water resource; agricultural water science; etc. Water SA is the WRC’s accredited scientific journal which contains original research articles and review articles on all aspects of water science, technology, engineering and policy. Water SA has been in publication since 1975 and includes articles from both local and international authors. The journal is issued quarterly (4 editions per year).