基于轴对准法的坐标系生成与转换

轴对准法可以较好地解决小范围内空间坐标系的生成与转换问题。本文详细介绍利用轴对准法进行空间坐标系生成与转换的算法,并将其应用到相机标定控制架的稳定性检验与测量成果的实际精度评定中。研究表明,轴对准法是小范围内坐标系生成与转换的有效方法。     

胶州湾沉积物中有机质的来源与组成及其对百年尺度环境变化的指示

The Jiaozhou Bay is characterized by heavy eutrophication that is associated with intensive anthropogenic activities. Four core sediments from the Jiaozhou Bay are analyzed using bulk technologies, including sedimentary total organic carbon(TOC), total nitrogen(TN), the stable carbon(δ~(13)C) and nitrogen(δ~(15) N) isotopic composition to obtain the comprehensive understanding of the source and composition of sedimentary organic matter and further shed light on the environmental changes of the Jiaozhou Bay on a centennial time scale.Results suggest that the TOC and TN concentrations increase in the upper core, having indicated a probable eutrophication process since the 1920 s in the inner bay and the 2000 s in the bay mouth. The TOC and TN concentrations outside the bay have also changed since 1916 owing to the variation of terrigenous input.Considering TOC/TN ratio, δ~(13) C and δ~(15) N, it can be concluded there is a mixture of terrigenous and marine organic matter sources in the study area. A simple two end-member(terrigenous and marine) mixing model usingδ~(13) C indicats that 45%–79% of TOC in the Jiaozhou Bay is from the marine source. The environmental changes of the Jiaozhou Bay are recorded by geochemical proxies, which are influenced by the intensive anthropogenic activities(e.g., extensive use of fertilizers, and discharge of sewage) and climate changes(e.g., rainfall).     

Carbon sinks/sources in the Yellow and East China Seas—Air-sea interface exchange,dissolution in seawater,and burial in sediments

The sinks/sources of carbon in the Yellow Sea(YS) and East China Sea(ECS), which are important continental shelf seas in China, could exert a great influence on coastal ecosystem dynamics and the regional climate change process. The CO_2 exchange process across the seawater-air interface, dissolved and particulate carbon in seawater, and carbon burial in sediments were studied to understand the sinks/sources of carbon in the continental shelf seas of China. The YS and the ECS generally have different patterns of seasonal air-sea CO_2 exchange. In the YS, regions west of 124°E can absorb CO_2 from the atmosphere during spring and winter, and release CO_2 to the atmosphere during summer and autumn. The entire YS is considered as a CO_2 source throughout the year with respect to the atmosphere, but there are still uncertainties regarding the exact air-sea CO_2 exchange flux. Surface temperature and phytoplankton production were the key controlling factors of the air-sea CO_2 exchange flux in the offshore region and nearshore region of the YS, respectively. The ECS can absorb CO_2 during spring, summer, and winter and release CO_2 to the atmosphere during autumn. The annual average exchange rate in the ECS was-4.2±3.2 mmol m~(-2) d~(-1) and it served as an obvious sink for atmospheric CO_2 with an air-sea exchange flux of 13.7×10~6 t. The controlling factors of the air-sea CO_2 exchange in the ECS varied significantly seasonally. Storage of dissolved inorganic carbon(DIC) and dissolved organic carbon(DOC) in the YS and the ECS were 425×10~6 t and 1364×10~6 t, and 28.2×10~6 t and 54.1×10~6 t,respectively. Long-term observation showed that the DOC content in the YS had a decreasing trend, indicating that the "practical carbon sink" in the YS was decreasing. The total amount of particulate organic carbon(POC) stored in the YS and ECS was10.6×10~6 t, which was comparable to the air-sea CO_2 flux in these two continental shelf seas. The amounts of carbon sequestered by phytoplankton in the YS and the ECS were 60.42×10~6 t and 153.41×10~6 t, respectively. Artificial breeding of macroalgae could effectively enhance blue carbon sequestration, which could fix 0.36×10~6–0.45×10~6 t of carbon annually. Organic carbon(OC) buried in the sediments of the YS was estimated to be 4.75×10~6 t, and OC of marine origin was 3.03×10~6 t, accounting for5.0% of the TOC fixed by phytoplankton primary production. In the ECS, the corresponding depositional flux of OC in the sediment was estimated to be 7.4×10~6 t yr~(-1), and the marine-origin OC was 5.5×10~6 t, accounting for 5.4% of the phytoplankton primary production. Due to the relatively high average depositional flux of OC in the sediment, the YS and ECS have considerable potential to store a vast amount of "blue carbon."     

气候变化下雅鲁藏布江拉孜以上流域径流过程模拟与预测

西部高寒河源区因冰川积雪冻土等特殊的地理环境,其径流过程的模拟与预测一直是水文学研究的难点和热点问题之一,全球气候变暖为这一地区的水文模拟提出了新的挑战。以雅鲁藏布江拉孜以上流域为研究区域,基于可考虑冰川积雪融水的SWAT分布式水文模型对拉孜站径流过程进行模拟,评估SWAT模型在高寒河源区的适用性。基于未来气候变化情景,统计分析了未来研究区降水、气温的变化趋势,预估了气候变化对区域径流过程的影响。结果表明:SWAT模型在拉孜以上流域径流过程模拟中具有较好的适用性,模型在率定期和验证期月尺度NS系数分别达到了0.78和0.84;未来研究区降水、气温均呈现出增加趋势,且随着排放情景的上升,气温、降水增加幅度有变大趋势;未来研究区不同时段径流量也呈现出不同的增加趋势,在2020～2049年的RCP2.6、RCP4.5和RCP8.5情景下,相较于基准期径流分别增加了约11.8%、14.0%、16.5%,为下游水资源可持续开发利用带来了更大的挑战。     

海洋沉积物/颗粒物在生源要素循环中的作用及生态学功能

海洋沉积物/颗粒物是生源要素循环过程中的关键源与汇，沉积物/颗粒物一方面是海水生源要素的主要归宿，生源要素从溶解态经复杂的生物-化学过程转变为颗粒态，颗粒物质再沉降形成沉积物，另一方面，海洋沉积物/颗粒物经过微生物-浮游动物-底栖生物作用分解形成溶解态的生源要素，并释放到海水中再次被浮游植物利用，进入下一轮循环，所以，海洋沉积物/颗粒物具有异常重要的生态学功能。浮游植物是海水溶解态生源要素的利用者和海源颗粒态生源要素的初始形成者，浮游动物通过摄食浮游植物或其他有机颗粒物可释放出溶解态生源要素或形成更大的颗粒物，颗粒物沉降后形成的沉积物又通过底栖生物摄食-扰动-破碎等过程将颗粒生源要素释放进入水体参与再循环。生态系统不同类群的生物在颗粒生源要素的释放-沉降中所起的作用不同而又相互关联，其中浮游动物-底栖生物的摄食与代谢、微生物参与的分解过程起着非常重要的作用。所以，海洋沉积物/颗粒物生态学功能研究作为支撑海洋环境和资源的持续利用的科学基础，已成为海洋科学的前沿领域，必将获得跨越发展。     

南海北部琼东南盆地冷泉区表层沉积物微量元素的分析及其对甲烷渗漏的指示

Recent studies have shown that specific geochemical characteristics of sediments can be used to reconstruct past methane seepage events. In this work, the correlation between the Sr/Ca and Mg/Ca ratios of sediment samples is analyzed and the sulfate concentration profile in Site C14 from cold-seep sediments in the Qiongdongnan Basin in northern South China Sea is obtained. The results confirmed that, sulfate at 0–247 cm below sea floor(Unit I) is mainly consumed by organic matter sulfate reduction(OSR), while sulfate at 247–655 cm(Unit II) is consumed by both the OSR and the anaerobic oxidation of methane(AOM). In addition, the bottom sediment layer is affected by weak methane seepage. The Mo and U enrichment factors also exhibit similar trends in their respective depth profiles. The responses of trace elements, including Co/Al, Ni/Al, Cr/Al and Zn/Al ratios to methane seepage allowed the study of depositional conditions and methane seepage events. Based on the results, it is speculated that the depositional conditions of Unit II changed with depth from moderate conditions of sulfidic and oxic conditions to locally anoxic conditions, and finally to suboxic conditions due to methane fluid leakage. The stable isotope values of chromium-reducible sulfide produced by AOM and those of sulfide formed by OSR in the early diagenetic environment suffered serious depletion of 34 S. This was probably due to weak methane leakage, which caused the slower upward diffusion and the effect of early diagenesis on the samples. It is necessary to consider the effects of depositional environments and diagenesis on these geochemical parameters.     

南海北部琼东南盆地浅表层沉积物的地球化学特征及对沉积环境的指示*

南海北部琼东南盆地海底存在着巨型麻坑, 现有研究多认为其形成主要与海底流体渗漏有关。目前对琼东南盆地深海沉积物地球化学特征及麻坑区的生物地球化学过程等尚不清楚。文章选取南海北部琼东南盆地C14、C19两个站位岩心样品, 进行了总硫(TS)、总碳(TC)、总有机碳(TOC)、铬还原性硫化物(CRS)及其δ³⁴S_CRS值测试, 并结合总氮/总碳(TN/TOC)比值和已发表的孔隙水中SO₄^2-浓度等进行了地球化学特征分析。研究表明: C14站位以3.91m bsf (below seafloor)为界, 上下分别存在有机质参与的硫酸盐还原反应(OSR)和甲烷厌氧氧化作用(AOM)驱动的硫酸盐还原反应(SR); 3.91m bsf以上的部位沉积物的TS、TC含量均低于3.91m bsf以下部位, 且沉积物孔隙水中SO₄^2-浓度由3.91m bsf以上的缓慢凹型减少变成3.91m bsf以下的线性减少, 说明该处成为沉积物中地球化学特征分界的明显标志; 在3.91m bsf以下, 受到甲烷渗漏的影响。C19站位沉积物中TS与TC含量由浅到深逐渐增加, 但与TN/TOC比值变化呈现几乎相反趋势, 即整个岩心以OSR为主, 并呈现出有机质早期成岩阶段的沉积现象。C14和C19两个站位柱状沉积物的δ³⁴S_CRS值变化范围分别为-50.2‰~-46.9‰和-50.1‰~-42.0‰ (V-CDT标准), 均显示出了较为偏负的硫同位素值, 表明研究区主要的生物化学过程是在相对开放体系下硫酸盐还原作用的结果, 综合说明该研究区麻坑的甲烷流体已经喷发, 目前可能处于衰退期, 甚至已经不活跃, 该结果与前人的认识基本一致。     

利用三维地震资料追踪富钾卤水储层

江陵盐盆在石油勘探中陆续发现了多处富钾卤水,其卤水中KC1含量达到17～19g/L,在对卤水层勘查中,尝试利用地球物理资料进行富钾卤水层追踪.勘查的方法为:首先由卤水层段伽马与波阻抗交会图得出卤水层的波阻抗特征,进而利用三维地震资料对卤水层进行识别与追踪,并最终圈定富钾卤水层分布范围.江陵凹陷沙市组卤水层勘查实践表明,...     

Biogeochemical characteristics of nitrogen and phosphorus in Jiaozhou Bay sediments

Sediment samples were cored from 3 locations representing the inner bay, the outer bay and the bay mouth of Jiaozhou Bay in September 2003 to study the source and biogeochemical characteristics of nitrogen and phosphorus in the bay. The content and vertical distributions of total nitrogen （TN）, total phosphorus （TP）, organic nitrogen （ON）, organic phosphorus （OP）, inorganic nitrogen （IN）, inorganic phosphorus （IP）, the ratio of organic carbon and total nitrogen （OC/TN）, and the ratio of total nitrogen and total phosphorus （TN/TP） in the sediments were analyzed. The results show that both TN and TP in surface sediments decrease from the inner bay to the outer bay. In general, ON occupies 50%-70% of TN and IP accounts for more than 60% of TP. In ratio of OC：TN, the nitrogen accumulated in the sediments from the inner bay and the bay mouth came mainly from terrestrial sources, and the portion of autogenetic nitrogen was 28.9% and 13.1%, respectively. However, in the outer bay, nitrogen was mainly autogenetic, accounting for 62.1% of TN, whereas phosphorus was mainly land-derived. The sedimentation fluxes of nitrogen and phosphorus varied spatially. The overall diagenesis rate of nitrogen was higher than that of phosphorus. Specifically, the diagenesis rate of OP was higher than that of IP. However, the diagenesis rate of ON was not always higher than that of IN. In species, the diagenesis rate of IN is sometimes much higher than that of the OC. In various environments, the diagenesis rate is, to some degree, affected by OC, pH, Eh, and Es.     

水母(沙海蜇)降解与营养盐(氮、磷)释放的模拟与实证

The aim of this study was to investigate nitrogen and phosphorus released in the process of the decomposition of giant jellyfish in the laboratory and found the evidence to verify the influence of nutrients released by the decomposition of jellyfish on the ecosystem in the field. The release of nitrogen and phosphorus from the decomposition of Nemopilema nomurai was examined in a series of experiments under different incubation conditions such as different p H values, salinity values, temperatures and nitrogen and phosphorus concentrations. The results showed that the complete decomposition of Nemopilema nomurai generally took about 4–8 d. The release of nitrogen and phosphorus from the decomposition of Nemopilema nomurai could be divided into two stages: the early stage and the later stage, although the efflux rate of nitrogen was one order more than phosphorus. In the early stage of the decomposition of Nemopilema nomurai, the concentrations of dissolved nitrogen, dissolved phosphorus, total nitrogen and total phosphorus in seawater increased rapidly, and the concentration of nitrogen could reach the highest level in the whole degradation process. In the later stage of the decomposition, the concentrations of dissolved nitrogen and total nitrogen declined slowly, while the concentration of phosphorus in water could reach a maximum in the degradation process. High p H, low salinity,high temperature and N/P will promote the release of nitrogen; low p H is unfavorable to the release of nitrogen but favorable to the release of phosphorus. In addition, we found the concentrations of ammonium and phosphate in the bottom water were higher than those in the surface water during the period of jellyfish bloom in the Jiaozhou Bay, proving that nutrients released by the decomposition of jellyfish have significant influence on nitrogen and phosphorus in the field. For the whole Yellow Sea, nutrients released by jellyfish carcasses may reach up to(2.63±2.98)×107 mol/d of dissolved nitrogen(DN) and(0.74±0.84)×106 mol/d of dissolved phosphorus(DP) during the period of jellyfish bloom. The values are comparable to riverine inputs in a day, but much higher than sediment–water exchange flux in the Yellow Sea. The great amounts of nutrients must have significant influence on the nutrients balance of the Yellow Sea during the period of jellyfish dead and decomposition. Both the experimental data and field observations proved that the decomposition of jellyfish may release a great amount of nutrient to the surrounding environment during the period of jellyfish decomposition.