Joshua L. Bonesso, Michael V. W. Cuttler, Nicola K. Browne, Caroline C. Mather, Victorien Paumard, William T. Hiscock, John N. Callow, Michael O'Leary
{"title":"Reef island evolution in a turbid-water coral reef province of the Indo-Pacific","authors":"Joshua L. Bonesso, Michael V. W. Cuttler, Nicola K. Browne, Caroline C. Mather, Victorien Paumard, William T. Hiscock, John N. Callow, Michael O'Leary","doi":"10.1002/dep2.242","DOIUrl":null,"url":null,"abstract":"<p>Coral reef islands are vulnerable landforms to environmental change. Constructed of largely unconsolidated reef-derived sediments, they are highly sensitive to variations in metocean boundary conditions, raising global concern about their future resilience and stability in the face of increased natural hazards, sea-level rise and anthropogenic climate change. This study examines the evolution of an inshore turbid reef island from the southern Pilbara region of Western Australia (Indo-Pacific) using detailed analyses of island chronostratigraphy (composition, texture) and geochronology (21 <i>in-situ</i> radiometric dates) from Eva Island. Downcore, composition of island-grade (reef-derived) sediments were homogenous, dominated by molluscan (37%–42%) and coral (32%–37%) constituents. The <sup>14</sup>C radiometric dating of island sediments, beachrock and coral microatolls identified five stages of island formation across changing sea-level regimes over the mid to late Holocene: (1) limestone platform accretion at <i>ca</i> 6,000 cal yr BP, coinciding with reef decline or ‘give-up’ on neighbouring Exmouth Gulf reefs; (2) sand cay (i.e. core) initiation and vertical aggregation at <i>ca</i> 5,000 cal yr BP during the point of sea-level regression to current levels; (3) major accretion and lateral progradation of the island between 3,500 cal yr BP and 2,500 cal yr BP including the modification of island shorelines through alongshore reworking of sediment; (4) lateral accretion and minor expansion to the north and formation of beachrock pavement between 2,500 and 650 cal yr BP; and (5) planform adjustment (erosion of the north-west island) and backstepping under stabilised sea levels over the past 650 years. While this model is comparative to studies on island formation following incremental sea-level fall following the mid-Holocene highstand, it demonstrates active landform readjustment under stabilised sea levels over the past 2,000 years, probably the influence of local-scale metocean boundary conditions within climate windows across the mid to late Holocene period (i.e. independent of sea-level fluctuations). Importantly, while sediment production rates are predicted to be lower in turbid-water reef systems than clear water, Eva Island shows no change in carbonate producers (i.e. proportion of mollusc and coral) over the course of island building, indicating the carbonate factory has not experienced significant adjustments in reef ecology, but has remained stable despite low water quality.</p>","PeriodicalId":54144,"journal":{"name":"Depositional Record","volume":"9 4","pages":"921-934"},"PeriodicalIF":1.9000,"publicationDate":"2023-06-22","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/dep2.242","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Depositional Record","FirstCategoryId":"89","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/dep2.242","RegionNum":3,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"GEOLOGY","Score":null,"Total":0}
引用次数: 0
Abstract
Coral reef islands are vulnerable landforms to environmental change. Constructed of largely unconsolidated reef-derived sediments, they are highly sensitive to variations in metocean boundary conditions, raising global concern about their future resilience and stability in the face of increased natural hazards, sea-level rise and anthropogenic climate change. This study examines the evolution of an inshore turbid reef island from the southern Pilbara region of Western Australia (Indo-Pacific) using detailed analyses of island chronostratigraphy (composition, texture) and geochronology (21 in-situ radiometric dates) from Eva Island. Downcore, composition of island-grade (reef-derived) sediments were homogenous, dominated by molluscan (37%–42%) and coral (32%–37%) constituents. The 14C radiometric dating of island sediments, beachrock and coral microatolls identified five stages of island formation across changing sea-level regimes over the mid to late Holocene: (1) limestone platform accretion at ca 6,000 cal yr BP, coinciding with reef decline or ‘give-up’ on neighbouring Exmouth Gulf reefs; (2) sand cay (i.e. core) initiation and vertical aggregation at ca 5,000 cal yr BP during the point of sea-level regression to current levels; (3) major accretion and lateral progradation of the island between 3,500 cal yr BP and 2,500 cal yr BP including the modification of island shorelines through alongshore reworking of sediment; (4) lateral accretion and minor expansion to the north and formation of beachrock pavement between 2,500 and 650 cal yr BP; and (5) planform adjustment (erosion of the north-west island) and backstepping under stabilised sea levels over the past 650 years. While this model is comparative to studies on island formation following incremental sea-level fall following the mid-Holocene highstand, it demonstrates active landform readjustment under stabilised sea levels over the past 2,000 years, probably the influence of local-scale metocean boundary conditions within climate windows across the mid to late Holocene period (i.e. independent of sea-level fluctuations). Importantly, while sediment production rates are predicted to be lower in turbid-water reef systems than clear water, Eva Island shows no change in carbonate producers (i.e. proportion of mollusc and coral) over the course of island building, indicating the carbonate factory has not experienced significant adjustments in reef ecology, but has remained stable despite low water quality.
珊瑚礁岛是易受环境变化影响的地貌。它们主要由未固结的珊瑚礁沉积物构成,对海洋边界条件的变化高度敏感,这引起了全球对它们在面对日益增加的自然灾害、海平面上升和人为气候变化时的未来复原力和稳定性的关注。本研究通过对伊瓦岛岛屿年代地层(组成、质地)和地质年代学(21个原位放射性测年)的详细分析,考察了西澳大利亚(印度太平洋)皮尔巴拉地区南部一个近海混浊礁岛的演化。岛级(礁源)沉积物组成均匀,以软体动物(37% ~ 42%)和珊瑚(32% ~ 37%)为主。对岛屿沉积物、滩岩和珊瑚微环礁的14C辐射定年确定了全新世中晚期海平面变化过程中岛屿形成的五个阶段:(1)大约6,000 cal - yr BP的石灰岩台地增生,与邻近的埃克斯茅斯湾珊瑚礁的珊瑚礁衰退或“放弃”相吻合;(2)海平面回归到当前水平时,约5000 calyr BP的沙岩(即岩心)形成和垂直聚集;(3)在3,500 cal - 2,500 cal - yr BP之间,岛屿发生了主要的增生和侧向进积,包括通过沿岸沉积物的改造而改变了岛屿海岸线;(4) 2500 ~ 650 cal yr BP期间,向北有少量的侧向增生和扩张,形成了滩岩铺装层;(5)在过去650年的稳定海平面下,台地调整(西北岛的侵蚀)和后退。虽然该模式可与全新世中期高点后海平面逐渐下降后岛屿形成的研究相比较,但它表明,在过去2000年里,在稳定的海平面下,地貌发生了积极的再调整,这可能是全新世中期至晚期气候窗内局地尺度的海洋边界条件的影响(即与海平面波动无关)。重要的是,虽然预测浊水珊瑚礁系统的产沙率低于清水,但伊娃岛在造岛过程中碳酸盐生产者(即软体动物和珊瑚的比例)没有变化,这表明碳酸盐工厂在珊瑚礁生态中没有经历重大调整,但在低水质下仍保持稳定。