代谢组学法在中药方剂中的应用概况          下载免费PDF全文

赵群菊  邱林  李美红 《应用海洋学学报》2018,34(5):222-224

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呼出气一氧化氮在哮喘缓解期的应用研究进展          下载免费PDF全文

朱海燕  王涛丽  李小娟 《应用海洋学学报》2018,34(12):140-142

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膝骨关节炎物理疗法的研究进展          下载免费PDF全文

向伟  杨娇  严旭洪 《应用海洋学学报》2018,34(12):170-172

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亚急性甲状腺炎的中医治疗进展          下载免费PDF全文

尹家宁  刘春红 《应用海洋学学报》2018,34(8):223-225

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葫芦巴的研究进展          下载免费PDF全文

马波  王志军  付滨 《应用海洋学学报》2018,34(8):243-246

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血管性痴呆中西医机制及相关危险因素研究概况          下载免费PDF全文

卓晓贵  方兴 《应用海洋学学报》2020,36(9):184

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吕宋和台湾岛以东黑潮季节与年际变化规律的对比分析     

武杰  张林林  闫晓梅 《海洋与湖沼》2020,51(4):839-850

黑潮是北太平洋副热带环流系统的一支重要的西边界流。前人对不同流段黑潮的季节和年际变化进行了诸多研究,然而基于不同数据所得结论仍存在差异,尤其是不同模式计算所得流量差别很大,而且以往研究往往着眼于某一流段,对不同流段黑潮变化之间的异同及其原因涉及较少。本文基于卫星高度计数据,评估了OFES(Ocean generalcir culation model For the Earth Simulator)和HYCOM(Hybrid Coordinate Ocean Model)两个模式对吕宋岛和台湾岛以东黑潮季节与年际变化的模拟能力,进而对两个海域黑潮变化的异同及其物理机制进行了分析。结果表明:HYCOM模式对黑潮季节变化的模拟较好,而OFES模式对黑潮年际变化的模拟较好。吕宋岛以东黑潮和台湾岛以东黑潮在季节与年际尺度上的变化规律均不相同,且受不同动力过程控制。吕宋岛以东黑潮呈现冬春季强而秋季弱的变化规律,主要受北赤道流分叉南北移动的影响;而台湾岛以东黑潮呈现夏季强冬季弱的变化特点,主要受该海区反气旋涡与气旋涡相对数目的季节变化影响。在年际尺度上,吕宋岛以东黑潮与北赤道流分叉及风应力旋度呈负相关,当风应力旋度超前于流量4个月时相关系数达到了-0.56;而台湾岛以东黑潮的流量变化则受制于副热带逆流区涡动能的变化,且滞后于涡动能9个月时达到最大正相关,相关系数为0.44。本研究对于深入理解不同流段黑潮的多尺度变异规律及其对邻近海区环流与气候的影响具有重要意义,同时对于黑潮研究的数值模式选取具有重要参考价值。  相似文献   

西太平洋海域现场培养实验中挥发性卤代烃浓度的变化及其影响因素     

韩钰  何真  刘珊珊  高旭旭  杨桂朋 《海洋学报》2020,42(2):1-9

CH₃I、CHCl₃、C₂HCl₃和CH₂Br₂是挥发性卤代烃4种重要成分，对大气化学产生重要影响。于2018年10月在西太平洋进行船基现场培养实验，研究微量元素Fe (50 nmol/L)、酸化(pH=7.9)、酸化(pH=7.9)和微量元素Fe (50 nmol/L)耦合作用、微量元素Fe (50 nmol/L)和N/P (16∶1)耦合作用及沙尘(4 mg/L)对浮游植物释放CH₃I、CHCl₃、C₂HCl₃和CH₂Br₂含量的影响。结果表明，与对照组相比，实验组CH₃I、C₂HCl₃和CH₂Br₂的释放均被不同程度抑制；CHCl₃的释放除添加沙尘时表现抑制作用外，其他条件下均为促进作用；实验组培养周期内叶绿素a浓度较高，而营养盐浓度变化规律不明显。总的来说，酸化和微量元素Fe可能是影响浮游植物释放挥发性卤代烃的重要限制因素，沙尘对促进浮游植物生长繁殖的影响更为显著。  相似文献   

赤道东印度洋和孟加拉湾障碍层厚度的年际变化及其影响机制     

马天  程旭华  齐义泉  陈佳佳 《海洋学报(英文版)》2020,39(7):19-31

Interannual variability(IAV) in the barrier layer thickness(BLT) and forcing mechanisms in the eastern equatorial Indian Ocean(EEIO) and Bay of Bengal(BoB) are examined using monthly Argo data sets during 2002–2017. The BLT during November–January(NDJ) in the EEIO shows strong IAV, which is associated with the Indian Ocean dipole mode(IOD), with the IOD leading the BLT by two months. During the negative IOD phase, the westerly wind anomalies driving the downwelling Kelvin waves increase the isothermal layer depth(ILD). Moreover, the variability in the mixed layer depth(MLD) is complex. Affected by the Wyrtki jet, the MLD presents negative anomalies west of 85°E and strong positive anomalies between 85°E and 93°E. Therefore, the BLT shows positive anomalies except between 86°E and 92°E in the EEIO. Additionally, the IAV in the BLT during December–February(DJF) in the BoB is also investigated. In the eastern and northeastern BoB, the IAV in the BLT is remotely forced by equatorial zonal wind stress anomalies associated with the El Ni?o-Southern Oscillation(ENSO). In the western BoB, the regional surface wind forcing-related ENSO modulates the BLT variations.  相似文献   

2017年春季季风间期南海中北部浮游植物生长与微型浮游动物摄食     

陈大伟  郭聪聪  余凌晖  鲁远征  孙军 《海洋学报(英文版)》2020,39(6):84-95

Phytoplankton growth rates and mortality rates were experimentally examined at 21 stations during the 2017 spring intermonsoon(April to early May) in the northern and central South China Sea(SCS) using the dilution technique, with emphasis on a comparison between the northern and central SCS areas which had different environmental factors. There had been higher temperature but lower nutrients and chlorophyll a concentrations in the central SCS than those in the northern SCS. The mean rates of phytoplankton growth(μ_0) and microzooplankton grazing(m) were(0.88±0.33) d~(–1) and(0.55±0.22) d~(–1) in the central SCS, and both higher than those in the northern SCS with the values of μ_0((0.81±0.16) d~(–1)) and m((0.30±0.09) d~(–1)), respectively.Phytoplankton growth and microzooplankton grazing rates were significantly coupled in both areas. The microzooplankton grazing impact(m/μ_0) on phytoplankton was also higher in the central SCS(0.63±0.12) than that in the northern SCS(0.37±0.06). The microzooplankton abundance was significantly correlated with temperature in the surface. Temperature might more effectively promote the microzooplankton grazing rate than phytoplankton growth rate, which might contribute to higher m and m/μ_0 in the central SCS. Compared with temperature, nutrients mainly affected the growth rate of phytoplankton. In the nutrient enrichment treatment,the phytoplankton growth rate(μn) was higher than μ_0 in the central SCS, suggesting phytoplankton growth in the central SCS was nutrient limited. The ratio of μ_0/μn was significantly correlated with nutrients concentrations in the both areas, indicating the limitation of nutrients was related to the concentrations of background nutrients in the study stations.  相似文献