黄、渤海二甲基硫化物的浓度分布与迁移转化速率研究   总被引：2，自引：1，他引：1  

闫士博  靳娜  张洪海  曹晓燕  杨桂朋 《海洋学报》2018,40(10):84-95

于2015年8-9月对黄、渤海海域进行现场调查，研究了海水中二甲基硫（DMS）、β-二甲巯基丙酸内盐（DMSP）、二甲亚砜（DMSO）的浓度分布、相互关系及影响因素，测定了DMS的生物生产与消耗、光化学氧化和海-气扩散速率，对DMS的迁移转化速率进行综合评价。结果表明:表层海水中DMS、溶解态DMSP（DMSPd）、颗粒态DMSP（DMSPp）、溶解态DMSO（DMSOd）和颗粒态DMSO（DMSOp）浓度的平均值分别为（6.12±3.01）nmol/L、（6.03±3.45）nmol/L、（19.47±9.15）nmol/L、（16.85±8.34）nmol/L和（14.37±7.47）nmol/L，整体呈现近岸高远海低，表层高底层低的趋势。DMS、DMSPd和DMSOp浓度与叶绿素（Chl a）浓度存在显著的相关性。表层海水中DMS光氧化速率顺序为:k_UVA > k_UVB > k_可见，其中UVA波段占光氧化的70.8%。夏季黄、渤海微生物消耗、光氧化及海-气扩散对DMS去除的贡献率分别为32.4%、34.5%和33.1%，表明3种去除途径作用相当。黄、渤海DMS海-气通量变化范围为0.79~48.45 μmol/（m2·d），平均值为（11.87±11.35）μmol/（m2·d）。  相似文献   

胶州湾海水中DMS和DMSP的分布及其影响因素   总被引：1，自引：0，他引：1  

景伟文  杨桂朋  康志强 《中国海洋大学学报(自然科学版)》2010,40(11)

为了解人为活动对二甲基硫(DMS)和二甲巯基丙酸(DMSP)生物生产的干扰,分别于2005年8月、11月对胶州湾海域进行采样。测定结果表明:胶州湾海水中8月DMS、DMSPd和DMSPp在次表层的平均含量分别为4.89,17.9和23.93nmol·L-1,在微表层中的平均含量分别为4.58,19.98和21.49nmol·L-1,11月DMS、DMSPd和DMSPp在次表层的平均含量分别为2.07,12.99和16.74nmol·L-1,在微表层中的平均含量分别为1.44,16.13和19.62nmol·L-1。DMS和DMSP的水平分布由于受到陆源输入的影响,呈现出自湾内向湾外递降的趋势。DMS和DMSP的含量夏季高于秋季。DMS和Chl-a在每个季节具有一定的相关性。DMS浓度的增加导致DMS通量增加。对海水微表层和次表层的研究表明,DMS和DMSPp并未在微表层中富集,而DMSPd有一定程度的富集。DMS,DMSP,Chl-a在海水微表层和次表层之间浓度分布的相关性体现了2层水体之间存在强烈的交换作用。  相似文献   

秋季东海二甲基硫和二甲巯基丙酸内盐浓度分布及降解速率研究   总被引：1，自引：0，他引：1  

杨桂朋  刘龙  张洪海 《中国海洋大学学报(自然科学版)》2014,44(10):86-91

于2013年10~11月现场测定了东海中二甲基硫(DMS)及其前体物质二甲巯基丙酸内盐(DMSP,分为溶解态DMSPd和颗粒态DMSPp)的含量,研究其水平分布特征、DMSPp的粒径分布及DMSPd的降解速率,并对DMS的海-气交换通量进行了探讨。研究结果表明,表层海水中DMS、DMSPd和DMSPp的浓度平均值分别为(4.84±0.40)、(5.84±0.93)和(13.01±0.52)nmol·L-1。海水中DMSPd的降解速率在2.59~16.36nmol·L-1·d-1之间,平均值为(6.78±0.84)nmol·L-1·d-1。调查海域范围内,小型浮游植物(20μm)是DMSPp和叶绿素a(Chl a)重要贡献者。此外,秋季东海表层海水DMS的海-气交换通量为0.66~31.73μmol·m-2·d-1,平均值为(11.63±0.71)μmol·m-2·d-1。  相似文献   

挪威海和格陵兰海海水DMS分布特征及影响因素研究     

厉丞烜  王保栋  杨桂朋 《海洋学报》2015,37(8):9-25

于2012年7—9月现场测定了北极挪威海和格陵兰海区域海水二甲基硫(DMS)及其前体物质二甲巯基丙酸内盐(DMSP,分溶解态DMSPd和颗粒态DMSPp)的含量,研究了其空间分布格局及其影响因素,探讨了表层海水DMS的生物周转和去除途径。结果表明,表层海水DMS、DMSPd和DMSPp的平均浓度分别为5.36nmol/L、15.63nmol/L和96.73nmol/L,受挪威海流和北极深层水影响,表层海水二甲基硫化物浓度呈现出由低纬度向高纬度海域递减的趋势。DMSPd和DMSPp浓度与Chl a浓度均有显著的相关性,说明浮游植物生物量是影响挪威海和格陵兰海二甲基硫化物生产的重要因素。表层海水DMS生物生产和消费速率平均值分别为18.19nmol/(L·d)、15.67nmol/(L·d)。DMS微生物周转时间变化范围为0.03~1.80d,平均值为0.49d,DMS海-气周转时间是微生物消费时间的90倍,说明夏季挪威海和格陵兰海表层海水中DMS微生物消费过程是比海-气扩散更具优势的去除机制。  相似文献   

胶州湾及青岛近海微表层与次表层中二甲基硫(DMS)与二甲巯基丙酸(DMSP)的浓度分布   总被引：3，自引：0，他引：3       下载免费PDF全文

张洪海  杨桂朋 《海洋与湖沼》2010,41(5):683-691

以胶州湾及青岛近海为研究区域,利用吹扫-捕集气相色谱法研究了二甲基硫(DMS)和二甲巯基丙酸(DMSP,分为溶解态DMSPd和颗粒态DMSPp)在微表层与次表层中的浓度以及它们在微表层中的富集行为。结果表明,DMS、DMSPd和DMSPp在微表层中的浓度高于次表层,它们在微表层中的富集因子分别为1.17、1.84和1.51。研究发现,DMS及DMSPp浓度与叶绿素a(Chl-a)浓度有很好的相关性,但它们的周日变化与Chl-a并不完全同步。DMS/Chl-a和DMSPp/Chl-a的比值在次表层和微表层分别为4.35、13.47mmol/g和3.99、15.88mmol/g。胶州湾及青岛近海生态环境受人为活动干扰严重,使本海域DMS含量较高,从而贡献出较大的DMS海-气通量。  相似文献   

不同氮磷比及铁浓度对球形棕囊藻二甲基硫和二甲巯基丙酸内盐生产的影响     

朱蓉  杨桂朋  于娟  张洪海 《中国海洋大学学报(自然科学版)》2013,(10):67-75

本文通过实验室培养研究了不同氮磷比(0∶1、5∶1、20∶1、50∶1)以及铁浓度(10、100、1 000nmol·L-1)对球形棕囊藻二甲基硫(DMS)和二甲巯基丙酸内盐(DMSP)产生的影响。富磷浓度(36.12μmol·L-1)条件下的球形棕囊藻DMS和DMSP的产量明显高于贫磷浓度条件下(0.361 2μmol·L-1)的DMS和DMSP的产量,N/P比为50∶1时球形棕囊藻的DMS和DMSP产量明显高于其他N/P比(0∶1、5∶1、20∶1)的DMS和DMSP产量,但N/P比为50∶1时单位Chl-aDMS/DMSP产量在4个N/P比(0∶1、5∶1、20∶1、50∶1)中却最低。贫磷培养液的DMSPd在N/P比为0∶1时峰值显著高于其它N/P比(5∶1、20∶1、50∶1)条件下的DMSPd,并且N/P比为50∶1时DMS的释放量最大。低Fe3+浓度有助于球形棕囊藻藻液中DMSPd的形成,Fe3+浓度为1 000nmol·L-1时单位Chl-a的DMSPp产量最小,而单位Chl-a的DMS生产能力在Fe3+浓度为100nmol·L-1时得到加强。  相似文献   

白令海东陆架区 生源硫化合物的时空特征变化          下载免费PDF全文

《海洋科学进展》2021,39(3)

基于2012年和2014年中国北极科学考察航次白令海现场调查数据,分析白令海东陆架区二甲基硫(DMS)及其前体物质β-二甲基硫巯基丙酸内盐(DMSP)的空间分布特征和年际变化。结果显示,白令海东部陆架区DMS浓度呈自西向东递减的趋势,浓度平均值由2012年0.80 nmol·L~(-1)(范围为0.11～2.27 nmol·L~(-1))增加至2014年1.33 nmol·L~(-1)(范围为0.07～4.49 nmol·L~(-1))。DMSP浓度的空间变化与DMS不一致,高值区位于断面东部,主要受近岸阿拉斯加沿岸流以及育空河淡水输入的影响。2012—2014年,溶解态DMSP(DMSPd)和颗粒态DMSP(DMSPp)浓度平均值分别从4.21 nmol·L~(-1)、16.83 nmol·L~(-1)提高至14.94 nmol·L~(-1)、49.77 nmol·L~(-1),应是冷水团范围缩减以及浮游植物群落变化所引起的。DMS浓度同温度、c_(PO~(3-)_4)、c_(SiO~(2-)_3)显著相关,而DMS和DMSP浓度同无机氮浓度、盐度均存在显著相关性。表层海水DMS和DMSPd的生物生产速率均高于消费速率,且呈现出东高西低的趋势,原因是温度影响了微生物代谢活动。2014年的生产和消费速率均高于2012年的,主要由于表层海水DMS和DMSPd浓度升高和水团的年际变化。2012年和2014年表层海水中DMS微生物消耗速率平均值分别为13.66 nmol·L~(-1)·d~(-1)和33.87 nmol·L~(-1)·d~(-1),海-气通量平均值分别为3.66μmol·m~(-2)·d~(-1)和5.33μmol·m~(-2)·d~(-1),表层海水DMS通过海气扩散去除的周转时间分别是微生物消费的7.4和5.7倍。白令海东部陆架区表层水体中微生物消费是比海气释放更重要的DMS去除途径。  相似文献   

夏季长江口及其邻近海域挥发性卤代烃的分布和海-气通量研究     

汪浩  何真  张婧  杨桂朋 《海洋学报》2018,40(10):96-109

运用吹扫-捕集气相色谱法测定了2017年夏季长江口及其邻近海域海水中4种常见的挥发性卤代烃（VHCs，包括一氟三氯甲烷（CFC-11）、碘甲烷（CH₃I）、三氯甲烷（CH₃CCl₃）和四氯乙烯（C₂Cl₄））以及大气中CFC-11、CH₃I和C₂Cl₄的浓度。结果表明，表层海水中4种VHCs浓度的水平分布受长江径流输入影响强烈，整体上呈现近岸高、远海低的趋势。垂直方向上4种VHCs浓度最高值出现在10 m水层，长江口内断面的浓度整体高于口外断面的浓度。海水中VHCs的浓度分布受水文环境、生物释放和人为因素等的共同影响。相关性分析表明CH₃I与Chl a浓度不存在明显的相关性，而CFC-11与CH₃I、C₂Cl₄浓度存在显著相关性（P<0.01），表明调查海域人为源对CH₃I和C₂Cl₄的影响大于天然源。大气中CFC-11、CH₃I和C₂Cl₄的浓度分布整体上呈现近岸高、远海低的趋势。CFC-11的浓度低于全球平均值，表明我国CFC-11的排放得到了有效控制。后向轨迹分析表明来自近岸的陆源污染物的扩散和输送是调查海域大气中3种VHCs的重要来源。CFC-11、CH₃I和C₂Cl₄的海-气通量平均值分别为24.99 nmol/（m2·d）、7.80 nmol/（m2·d）、1.55 nmol/（m2·d），表明夏季长江口及其邻近海域是大气中这3种VHCs的源。  相似文献   

渤海溶解CH₄分布和通量的季节变化及其影响因素          下载免费PDF全文

孙悦  罗畅  杜冠祥  王浩男  宋国栋  刘素美  张桂玲 《海洋与湖沼》2023,54(2):444-456

甲烷(CH₄)是影响地球辐射平衡的主要温室气体,海洋是大气CH₄的自然源,而陆架等近海是释放CH₄的热点海域。于2021年4月、7月和10月对渤海进行了调查,以认识其分布特征并估算其海-气交换通量。春、夏和秋季表层海水CH₄浓度分别为(4.56±2.60)、(8.31±4.01)和(4.99±1.31) nmol/L,夏季明显高于春秋季。CH₄的垂直分布规律为底层普遍高于表层,不同站位的垂直分布空间差异较大。渤海CH₄分布主要受河流输入、油气泄漏、生物活动以及沉积物-水界面交换等因素的影响,其中黄河向渤海输入CH₄约为每月1.4×104～2.8×105mol,秋冬季沉积物-水界面CH₄交换通量范围为–4.0～0.42μmol/(m²·d),表明秋冬季沉积物既可能是渤海水体CH₄的源,也可能是其汇。春、夏和秋季渤海CH₄海-气交换通量分别为(1.1±...  相似文献   

冲绳海槽沉积物孔隙水地球化学特征及其指示意义     

孙呈慧  窦衍光  赵京涛  孙治雷  白凤龙  蔡峰  李清  翟滨  王利波  邹亮 《海洋学报》2022,44(5):102-112

通过对东海外陆坡–冲绳海槽GSW1孔沉积物孔隙水δ₁₃C、δ₁₈O、δ₁₁B、δ₃₇Cl同位素和Cl_-、S O₄^2-、K₊、Na₊等离子指标的分析,探讨了沉积物早期成岩作用、流体来源、迁移和氧化环境的变化。研究发现,GSW1孔孔隙水溶解无机碳主要来自海水和有机质,SO₄^2-浓度随深度下降比较平缓,Cl_-浓度远低于海水,该孔表层沉积物中硫酸盐消耗主要由有机质硫酸盐还原作用（OSR）所控制,甲烷厌氧氧化作用（AOM）发生在4 m以下更深的层位。OSR产生的H₂S向上扩散富集并被氧化,是导致GSW1孔110～360 cm处SO ₄^2-浓度未明显下降的主要因素。孔隙水SO₄^2-浓度整体随着深度增加呈减小的趋势,表明GSW1孔沉...  相似文献   

Spatial variations of dimethylsulfide and dimethylsulfoniopropionate in the surface microlayer and in the subsurface waters of the South China Sea during springtime   总被引：3，自引：0，他引：3  

Yang GP  Jing WW  Kang ZQ  Zhang HH  Song GS 《Marine environmental research》2008,65(1):85-97

Spatial variations in dimethylsulfide (DMS) and dimethylsulfoniopropionate (DMSP) were surveyed in the surface microlayer and in the subsurface waters of the low productivity South China Sea in May 2005. Overall, average subsurface water concentrations of DMS and DMSP of dissolved (DMSPd) and particulate (DMSPp) fractions were 1.74 (1.00-2.50), 3.92 (2.21-6.54) and 6.06 (3.40-8.68) nM, respectively. No enrichment in DMS and DMSPp was observed in the microlayer. In contrast, the microlayer showed a DMSPd enrichment, with an average enrichment factor (EF, defined as the ratio of the microlayer concentration to subsurface water concentration) of 1.40. In the study area, none of the sulfur components were correlated with chlorophyll a. An important finding in this study was that DMS, DMSP and chlorophyll a concentrations in the surface microlayer were respectively correlated with those in the subsurface water, suggesting a close linkage between these two water bodies. The ratios of DMS:Chl-a and DMSPp:Chl-a showed a gradually increasing trend from North to South. This might be due to changes in the proportion of DMSP producers in the phytoplankton community with the increased surface seawater temperature. A clear diurnal variation in the DMS and DMSP concentrations was observed at an anchor station with the highest concentrations appearing during the day and the lowest concentrations during the night. The higher DMS and DMSP concentrations during daytime might be attributed to the light-induced increase in both algal synthesis and exudation of DMSP and biological production of DMS. The mean flux of DMS from the investigated area to the atmosphere was estimated to be 2.06 micromo lm(-2)d(-1). This low DMS emission flux, together with the low DMS surface concentrations was attributed to the low productivity in this sea.  相似文献   

Seasonal variations of dimethylsulfide (DMS) and dimethylsulfoniopropionate (DMSP) in the sea-surface microlayer and subsurface water of Jiaozhou Bay and its adjacent area   总被引：1，自引：0，他引：1  

ZHANG Honghai  YANG Guipeng  LIU Chunying  LI Chenxuan 《海洋学报(英文版)》2009,28(2):73-86

The distributions of DMS and its precursor dimethylsulfoniopropionate, in both dissolved (DMSP_d) and particulate fractions (DMSP_p) were determined in the seasurface microlayer and corresponding subsurface water of the Jiaozhou Bay, China and its adjacent area in May and August 2006. The concentrations of all these components showed a clear seasonal variation, with higher concentrations occurring in summer. This can be mainly attributed to the higher phytoplankton biomass observed in summer. Simultaneously, the enrichment extents of DMSP_d and DMSP_p in the microlayer also exhibited seasonal changes, with higher values in spring and lower ones in summer. Higher water temperature and stronger radiant intensity in summer can enhance their solubility and photochemical reaction in the microlayer water, reducing their enrichment factors (the ratio of concentration in the microlayer to that in the corresponding subsurface water). A statistically significant relationship was found between the microlayer and subsurface water concentrations of DMS, DMSP and chlorophyll a, demonstrating that the biogenic materials in the microlayer come primarily from the underlying water. Moreover, our data show that the concentrations of DMSP_p and DMS were significantly correlated with the levels of chlorophyll a, indicating that phytoplankton biomass might play an important role in controlling the distributions of biogenic sulfurs in the study area. The ratios of DMS/chlorophyll a and DMSP_p/chlorophyll a varied little from spring to summer, suggesting that there was no obvious change in the proportion of DMSP producers in the phytoplankton community. The mean sea-to-air flux of DMS from the study area was estimated to be 5.70 μmol/(m²·d), which highlights the effects of human impacts on DMS emission.  相似文献   

Biogeochemistry of dimethylsulfide (DMS) and dimethylsulfoniopropionate (DMSP) in the surface microlayer and subsurface water of the western North Atlantic during spring   总被引：6，自引：0，他引：6  

Gui-Peng Yang  Maurice Levasseur  Sonia Michaud  Michael Scarratt 《Marine Chemistry》2005,96(3-4):315-329

Sixteen surface microlayer samples and corresponding subsurface water samples were collected in the western North Atlantic during April–May 2003 to study the distribution and cycling of dimethylsulfide (DMS) and dimethylsulfoniopropionate (DMSP) and the factors influencing them. In the surface microlayer, high concentrations of DMS appeared mostly in the samples containing high levels of chlorophyll a, and a significant correlation was found between DMS and chlorophyll a concentrations. In addition, microlayer DMS concentrations were correlated with microlayer DMSPd (dissolved) concentrations. DMSPd was found to be enriched in the microlayer with an average enrichment factor (EF) of 5.19. However, no microlayer enrichment of DMS was found for most samples collected. Interestingly, the DMS production rates in the microlayer were much higher than those in the subsurface water. Enhanced DMS production in the microlayer was likely due to the higher concentrations of DMSPd in the microlayer. A consistent pattern was observed in this study in which the concentrations of DMS, DMSPd, DMSPp (particulate) and chlorophyll a in the microlayer were closely related to their corresponding subsurface water concentrations, suggesting that these constituents in the microlayer were directly dependent on the transport from the bulk liquid below. Enhanced DMS production in the microlayer further reinforces the conclusion that the surface microlayer has greater biological activity relative to the underlying water.  相似文献   

春秋季南黄海二甲基硫(DMS)与二甲巯基丙酸(DMSP)的浓度分布研究   总被引：2，自引：0，他引：2  

杨剑  杨桂朋  张洪海  张生辉 《海洋学报(英文版)》2016,35(2):76-87

Temporal distributions of dimethylsulfide(DMS) and dimethylsulfoniopropionate(DMSP) were studied in the southern Yellow Sea(SYS) during April and September 2010. The mean concentrations(range) of DMS, dissolved and particulate DMSP(DMSPd and DMSPp) in the surface waters in spring are 1.69(0.48–4.92), 3.18(0.68–6.75)and 15.81(2.82–52.33) nmol/L, respectively, and those in autumn are 2.80(1.33–5.10), 5.45(2.19–11.30) and 30.63(6.24–137.87) nmol/L. On the whole, the distributions of DMS and DMSP in spring are completely different from those in autumn. In the central part of the SYS, the concentrations of DMS and DMSP in spring are obviously higher than those in autumn, but the opposite situation is found on the south of 34°N, which can be attributed to the differences in nutrients and phytoplankton biomass and composition between spring and autumn. Besides,the seasonal variations of water column stability and the Changjiang diluted water also have significant impact on the distributions of DMS and DMSP in spring and autumn on the south of 34°N. DMS and DMSPp concentrations coincide well with chlorophyll a(Chl a) levels in the spring cruise, suggesting that phytoplankton biomass may play an important role in controlling the distributions of DMS and DMSPp in the study area. Annual DMS emission rates range from 0.015 to 0.033 Tg/a(calculated by S), respectively, using the equations of Liss and Merlivat(1986) and Wanninkhof(1992). This result implies a significant relative contribution of the SYS to the global oceanic DMS fluxes.  相似文献   

Spatial variations of DMS, DMSP and phytoplankton in the Bay of Bengal during the summer monsoon 2001     

Shenoy DM  Paul JT  Gauns M  Ramaiah N  Kumar MD 《Marine environmental research》2006,62(2):83-97

Data on the distribution of dimethylsulphide (DMS) and dimethylsulphoniopropionate (DMSP) in relation to phytoplankton abundance in different oceanic environments is important to understand the biogeochemistry of DMS, which plays an important role in the radiation balance of the earth. During the summer monsoon of 2001 measurements were made for DMS and DMSPt (total DMSP) together with related biological parameters in the Bay of Bengal. Both DMS and DMSPt were restricted to the upper 40 m of the water column. Diatoms accounted for more than 95% of the phytoplankton and were the major contributors to the DMS and DMSPt pool. The mean concentration of DMS in the upper 40 m was observed to be around 1.8+/-1.9 nM in the study area, while DMSPt concentrations varied between 0.7 nM and 40.2 nM with a mean of 10.4+/-8.2 nM. The observed lower DMSPt in the northern Bay in spite of higher mean primary productivity, chlorophyll a and phytoplankton cell counts seemed to result from grazing. Though salinity divides the Bay into different biogeochemical provinces there is no relation between salinity and DMS or DMSPt. On the other hand DMS was linearly related to chlorophyll a:phaeopigments ratio. The results suggest the need for deeper insight into the role of diatoms in the biogeochemical cycling of DMS.  相似文献   

Occurrence and turnover of DMSP and DMS in deep waters of the Ross Sea,Antarctica     

Alison N. Rellinger  Ronald P. Kiene  Daniela A. del Valle  David J. Kieber  Doris Slezak  Hyakubun Harada  John Bisgrove  Jordan Brinkley 《Deep Sea Research Part I: Oceanographic Research Papers》2009,56(5):686-702

High concentrations of the phytoplankton metabolite dimethylsulfoniopropionate (DMSP) and its degradation product dimethylsulfide (DMS) are associated with blooms of Phaeocystis antarctica in the Ross Sea, Antarctica. Episodic and rapid vertical export of Phaeocystis biomass to deep water has been reported for the Ross Sea, therefore we examined the distribution and microbial consumption rates of DMSP and DMS throughout the sub-euphotic water column. Total DMSP (dissolved+particulate; DMSPt) was present at 0.5–22 nM at depths between 70 and 690 m during both the early bloom (November) and the late bloom (January). Sub-euphotic peaks of DMSP were sometimes associated with mid-water temperature maxima, and elevated DMSP below 70 m was found mainly in water masses characterized as Modified Circumpolar Deep Water or Antarctic Shelf Water. Overall, 50–94% of the integrated water-column DMSPt was found below the euphotic zone. At one station during the early bloom, local maxima of DMSPt (14 nM) and DMS (20 nM) were observed between 113 and 240 m and these maxima corresponded with high chlorophyll a concentrations, P. antarctica cell numbers, and Fv/Fm (the quantum yield of photosystem II). During the late bloom, a sub-euphotic maximum of DMSPt (15.8 nM) at 250 m cooccurred with peaks of chlorophyll a concentration, DMSP lyase activity, bacterial production and dissolved DMSP consumption rates. DMSP turnover contributed ～12% of the bacterial carbon demand between 200 and 400 m. DMS concentrations peaked at 286 m but the maximum concentration (0.42 nM) was far lower than observed during the early bloom, probably because of relatively rapid biological consumption of DMS (1–3 turnovers per day) which, in turn, contributed to elevated dissolved dimethylsulfoxide (DMSO) concentrations. Relatively stable DMSPt distributions at some sites suggest that rapid sinking of Phaeocystis biomass is probably not the major mechanism responsible for mesopelagic DMSP accumulations. Rather, subduction of near-surface water masses, lateral advective transport or trapping of slowly sinking P. antarctica biomass in intermediate water masses are more likely mechanisms. We found that a culture of P. antarctica maintained cellular integrity during 34 days of darkness, therefore the presence of intact cells (and DMSP) at depth can be explained even under a slow sinking/advection scenario. Whatever the mechanism, the large pools of DMSP and DMS below the euphotic zone suggest that export exerts a control on potential DMS emission from the surface waters of the Ross Sea.  相似文献   

Morphology and tectonics of the Yap Trench   总被引：5，自引：0，他引：5  

Fujiwara  Toshiya  Tamura  Chiori  Nishizawa  Azusa  Fujioka  Kantaro  Kobayashi  Kazuo  Iwabuchi  Yo 《Marine Geophysical Researches》2000,21(1-2):69-86

We conducted swath bathymetry and gravity surveys the whole-length of the Yap Trench, lying on the southeastern boundary of the Philippine Sea Plate. These surveys provided a detailed morphology and substantial insight into the tectonics of this area subsequent the Caroline Ridge colliding with this trench. Horst and graben structures and other indications of normal faulting were observed in the sea-ward trench seafloor, suggesting bending of the subducting oceanic plate. Major two slope breaks were commonly observed in the arc-ward trench slope. The origin of these slope breaks is thought to be thrust faults and lithological boundaries. No flat lying layered sediments were found in the trench axis. These morphological characteristics suggest that the trench is tectonically active and that subduction is presently occurring. Negative peaks of Bouguer anomalies were observed over the arc-ward trench slope. This indicates that the crust is thickest beneath the arc-ward trench slope because the crustal layers on the convergent two plates overlap. Bouguer gravity anomalies over the northern portion of the Yap Arc are positive. These gravity signals show that the Yap Arc is uplifted by dynamic force, even though dense crustal layers underlie the arc. This overlying high density arc possibly forces the trench to have great water depths of nearly 9000 m. We propose a tectonic evolution of the trench. Subduction along the Yap Trench has continued with very slow rates of convergence, although the cessation of volcanism at the Yap Arc was contemporaneous with collision of the Caroline Ridge. The Yap Trench migrated westward with respect to the Philippine Sea Plate after collision, then consumption of the volcanic arc crust occurred, caused by tectonic erosion, and the distance between the arc and the trench consequently narrowed. Lower crustal sections of the Philippine Sea Plate were exposed on the arc-ward trench slope by overthrusting. Intense shearing caused deformation of the accumulated rocks, resulting in their metamorphism in the Yap Arc.  相似文献   

Experimental studies on dimethylsulfide (DMS) and dimethylsulfoniopropionate (DMSP) production by four marine microalgae     

LI Chengxuan  YANG Guipeng  PAN Jinfen  ZHANG Honghai 《海洋学报(英文版)》2010,29(4):78-87

The production of dimethylsulfide (DMS) and dimethylsulfoniopropionate (DMSP) by marine microalgae was investigated to elucidate more on the role of marine phytoplankton in ocean-atmosphere interactions in the global biogeochemical sulfur cycle.Axenic laboratory cultures of four marine microalgae–Isochrysis galbana 8701,Pavlova viridis,Platymonas sp.and Chlorella were tested for DMSP production and conversion into DMS.Among these four microalgae,Isochrysis galbana 8701 and Pavlova viridis are two species of Haptophyta,while Chlorella and Platymonas sp.belong to Chlorophyta.The results demonstrate that the four algae can produce various amounts of DMS(P),and their DMS(P) production was species specific.With similar cell size,more DMS was released by Haptophyta than that by Chlorophyta.DMS and dissolved DMSP (DMSPd) concentrations in algal cultures varied significantly during their life cycles.The highest release of DMS appeared in the senescent period for all the four algae.Variations in DMSP concentrations were in strong compliance with variations in algal cell densities during the growing period.A highly significant correlation was observed between the DMS and DMSPd concentrations in algal cultures,and there was a time lag for the variation trend of the DMS concentrations as compared with that of the DMSPd.The consistency of variation patterns of DMS and DMSPd implies that the DMSPd produced by phytoplankton cells has a marked effect on the production of DMS.In the present study,the authors’ results specify the significant contribution of the marine phytoplankton to DMS(P) production and the importance of biological control of DMS concentrations in oceanic water.  相似文献