R. D. Ardi, A. Aswan, K. Maryunani, E. Yulianto, P. Putra, S. H. Nugroho
{"title":"末次盛冰期(~23 ka bp)以来萨武海峡西部有孔虫堆积速率的Ea表层古生产力重建","authors":"R. D. Ardi, A. Aswan, K. Maryunani, E. Yulianto, P. Putra, S. H. Nugroho","doi":"10.17794/rgn.2023.1.14","DOIUrl":null,"url":null,"abstract":"Despite its importance, sea surface paleoproductivity of the western Savu Strait is not well studied. Results from previous studies at the nearby Southwest Sumba and Sumba Strait might not be applicable due to the oceanographic difference. Foraminiferal proxies from gravity core ST10 were applied to generate sea surface paleoproductivity and thermocline depth reconstruction. Foraminiferal Accumulation Rate and Benthic Foraminiferal Accumulation Rate were used as paleoproductivity proxies while the thermocline dwellers’ relative abundance was applied as the thermocline depth proxy. This study suggested paleoproductivity increase during the Last Glacial Maximum (LGM)–~16 ka BP and Holocene (after ~11.65 ka BP) in the western Savu Strait. Thermocline depth was relatively shallower during the LGM–Last Deglaciation and became deeper afterwards. Paleoproductivity increase at LGM–~16 ka BP was caused by the Australian-Indonesian winter monsoon (AIWM)-like condition, characterized by intense coastal upwelling while the Holocene paleoproductivity increase was related to the abrupt rainfall increase which enhanced terrestrial/riverine input. Thermocline depth variability in the western Savu Strait is in-phase with thermocline depth variability in the Java upwelling region, characterized by a shallower thermocline during the LGM–Last Deglaciation (before ~11.65 ka BP) and a deeper thermocline during the Holocene (after ~11.65 ka BP). This thermocline depth shifting indicates a strong Australian-Indonesian Monsoon (AIM) influence on the paleoceanography of the western Savu Strait since LGM.","PeriodicalId":44536,"journal":{"name":"Rudarsko-Geolosko-Naftni Zbornik","volume":"1 1","pages":""},"PeriodicalIF":1.2000,"publicationDate":"2023-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"EA SURFACE PALEOPRODUCTIVITY RECONSTRUCTION BASED ON FORAMINIFERAL ACCUMULATION RATE IN THE WESTERN SAVU STRAIT SINCE THE LAST GLACIAL MAXIMUM (~23 KA BP)\",\"authors\":\"R. D. Ardi, A. Aswan, K. Maryunani, E. Yulianto, P. Putra, S. H. Nugroho\",\"doi\":\"10.17794/rgn.2023.1.14\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Despite its importance, sea surface paleoproductivity of the western Savu Strait is not well studied. 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Paleoproductivity increase at LGM–~16 ka BP was caused by the Australian-Indonesian winter monsoon (AIWM)-like condition, characterized by intense coastal upwelling while the Holocene paleoproductivity increase was related to the abrupt rainfall increase which enhanced terrestrial/riverine input. Thermocline depth variability in the western Savu Strait is in-phase with thermocline depth variability in the Java upwelling region, characterized by a shallower thermocline during the LGM–Last Deglaciation (before ~11.65 ka BP) and a deeper thermocline during the Holocene (after ~11.65 ka BP). 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引用次数: 1
摘要
尽管萨武海峡西部的海面古生产力具有重要意义,但目前对其研究还不够深入。先前在附近的西南松巴海峡和松巴海峡进行的研究结果可能由于海洋学的差异而不适用。利用ST10重力岩心有孔虫代用物进行了海表古生产力和温跃层深度重建。以有孔虫积累率和底栖有孔虫积累率作为古生产力指标,以温跃层生物相对丰度作为温跃层深度指标。研究表明,萨武海峡西部的古生产力在末次盛冰期(LGM) - ~16 ka BP和全新世(~11.65 ka BP之后)期间有所增加。在lgm -末次消冰期,温跃层深度相对较浅,之后逐渐变深。LGM - ~16 ka BP古生产力的增加是由澳大利亚-印度尼西亚冬季风(AIWM)样条件引起的,其特征是强烈的海岸上升流,而全新世古生产力的增加与降雨量的突然增加有关,增加了陆地/河流的输入。萨武海峡西部的温跃层深度变化与爪哇上升流区的温跃层深度变化相一致,表现为lmg -末次脱冰期(~11.65 ka BP之前)的温跃层较浅,全新世(~11.65 ka BP之后)的温跃层较深。这种温跃层深度变化表明,自LGM以来,澳大利亚-印度尼西亚季风(AIM)对萨武海峡西部的古海洋学有强烈的影响。
EA SURFACE PALEOPRODUCTIVITY RECONSTRUCTION BASED ON FORAMINIFERAL ACCUMULATION RATE IN THE WESTERN SAVU STRAIT SINCE THE LAST GLACIAL MAXIMUM (~23 KA BP)
Despite its importance, sea surface paleoproductivity of the western Savu Strait is not well studied. Results from previous studies at the nearby Southwest Sumba and Sumba Strait might not be applicable due to the oceanographic difference. Foraminiferal proxies from gravity core ST10 were applied to generate sea surface paleoproductivity and thermocline depth reconstruction. Foraminiferal Accumulation Rate and Benthic Foraminiferal Accumulation Rate were used as paleoproductivity proxies while the thermocline dwellers’ relative abundance was applied as the thermocline depth proxy. This study suggested paleoproductivity increase during the Last Glacial Maximum (LGM)–~16 ka BP and Holocene (after ~11.65 ka BP) in the western Savu Strait. Thermocline depth was relatively shallower during the LGM–Last Deglaciation and became deeper afterwards. Paleoproductivity increase at LGM–~16 ka BP was caused by the Australian-Indonesian winter monsoon (AIWM)-like condition, characterized by intense coastal upwelling while the Holocene paleoproductivity increase was related to the abrupt rainfall increase which enhanced terrestrial/riverine input. Thermocline depth variability in the western Savu Strait is in-phase with thermocline depth variability in the Java upwelling region, characterized by a shallower thermocline during the LGM–Last Deglaciation (before ~11.65 ka BP) and a deeper thermocline during the Holocene (after ~11.65 ka BP). This thermocline depth shifting indicates a strong Australian-Indonesian Monsoon (AIM) influence on the paleoceanography of the western Savu Strait since LGM.