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1.
海?气界面CO2通量的估算采用块体公式,其等于气体交换速率、CO2溶解度以及海水与大气的CO2分压差的乘积,其中的气体交换速率通常与风速相联系,不同作者提出了气体交换速率为风速不同幂次多项式的参数化方案。本文对比了气体交换速率为风速函数的主要研究结果,发现与风速多项式的依赖关系相比,观测数据所基于的观测方法对于气体交换速率的影响更大。在此基础上,本文用多种不同的气体交换速率参数化公式计算了1982?2018年全球的CO2通量,海洋整体上是大气CO2的汇,赤道海区是源,南北半球40°附近的海域构成沿纬向的强吸收带。37 a间,海洋CO2通量的年平均值(以碳计)为(?1.53±0.15) Pg/a, 1999年前,海洋吸收量逐年减小,1999年达到最小值,之后海洋吸收量开始增大,海洋吸收量的增大主要发生在南大洋。 相似文献
2.
海岸海洋接受大量来自陆源的碳物质和营养盐,涉及大量以碳为中心的相互作用,是重要的碳循环海域;同时,该区域也常发育具有良好圈闭条件的储-盖系统,具有明显的CO2储集潜力。该文以海岸海洋及其下发育的沉积盆地为研究对象,综述了碳物质在海岸海洋中的循环过程、CO2通量的影响因素和海岸海洋沉积盆地的储碳机理。从“双碳”角度,重点论述了海岸海洋在促进CO2负排放方面的意义、促进海洋负碳排放的潜在途径和在沉积盆地的储碳潜力及面临的问题。海岸海洋是重要的碳汇区域之一,高效率的微生物碳泵和碳酸盐碳泵是增强海岸海洋CO2负排放的核心过程;同时,海岸海洋沉积盆地中的储-盖系统,不但提供了额外的CO2封存空间,也保障了CO2封存的安全性。未来的研究应以抑制海岸海洋中碳物质向CO2转化的进程和保障沉积储层中CO2封存的安全性为主要方向,为CO2负排放提供理论依据与技术保障。 相似文献
3.
探究海气CO2交换有助于解析全球碳循环和全球气候变化。由于海水和大气的直接接触,研究表层海水碳酸盐系统变化成为探究海气碳交换的关键。基于已有热带西太平洋表层海水碳酸盐系统研究成果,本文总结了有孔虫壳体B/Ca和δ11B指标重建碳酸盐系统参数的原理、方法及优缺点。然后,从厄尔尼诺-南方涛动(El Ni?o-Southern Oscillation, ENSO)、东亚季风以及大气桥梁和海洋隧道三方面综述了晚第四纪热带西太平洋海气CO2交换影响因素的研究现状。结果显示,类ENSO通过横向平流和垂向变化分别影响热带西太平洋东端和西端的海气碳交换。东亚夏季风对热带西太平洋海气碳交换具有较强的调控作用,而东亚冬季风的调控作用较弱或不明显。冰消期南大洋深部流通状况增强,可通过大气桥梁(大气CO2)和海洋隧道(南极中层水)影响热带西太平洋海气碳交换。然而,为了更准确清晰地了解全球碳循环变化,还需针对指标记录的可靠性、覆盖范围以及海气碳交换在更长时间尺度的变化机理等方面开展更多研究。 相似文献
4.
长心卡帕藻(Kappaphycusalvarezii)是主要生长于热带海域的大型经济红藻,在营养物生物提取方面具有重要的经济和生态价值,作为提取κ-卡拉胶的重要原料,广泛应用于食品和医学等多种行业。由于人类活动导致大气中CO2浓度持续升高,引发海洋表层海水逐渐酸化和升温,对大型海藻产生耦合效应。因此,本文设置了两种CO2浓度梯度(450×10–6和1 200×10–6)和三种温度梯度(26℃、29℃和32℃),从光合作用、细胞代谢产物、碳氮积累和酶活性方面探讨长心卡帕藻响应海洋酸化和海水升温的环境适应性变化。结果表明, CO2浓度与温度变化对长心卡帕藻的Fv/Fm影响显著(P<0.05),在两种CO2浓度条件下,Fv/Fm均随温度升高而增加;酸化条件与非酸化条件下可溶性糖浓度变化趋势相反,海水升温对游离氨基酸浓度影响极显著(P<0.01),在两种CO2水平下,升温均会降低藻体游离... 相似文献
5.
海浪对北太平洋海-气二氧化碳通量的影响 总被引:1,自引:0,他引:1
利用4种海-气界面气体传输速率公式对比研究了北太平洋气体传输速率及其CO2通量的季节变化特征。与单纯依赖风速的算法相比, 考虑波浪影响的气体传输速率和CO2通量在空间分布和季节变化上具有明显差异。在低纬度地区(0°~30°N), 波浪参数使气体传输速率下降, 海洋对大气CO2的吸收减少, 而在30°N以北范围内则出现新的气体传输速率高值区, 海洋对大气的吸收增加。进一步研究了黑潮延伸体区域的气候态月平均气体传输速率和CO2通量。结果表明, 该区域气体传输速率和CO2通量最大值分别出现于冬季和春季, 引入波浪参数后, 虽然该区域气体传输速率和CO2通量平均值没有明显差异, 但季节变化强度显著增强。 相似文献
6.
挥发性卤代烃(volatilehalocarbon,VHCs)是大气中一类重要的臭氧层破坏者和环境污染物,海洋微藻释放是大气VHCs的重要来源,在调节全球气候中起着至关重要的作用。该研究在2个温度(T=20、25°C)和2个CO2分压(pCO2=395、790 mg/L)条件下,模拟研究了温度和pCO2升高对中肋骨条藻生长和3种VHCs (CHBr3、CHBr2Cl和CHBrCl2)释放量的影响。研究结果表明, pCO2=395 mg/L,T=25°C时,中肋骨条藻的生长情况最佳; pCO2=790 mg/L, T=20°C时,中肋骨条藻的生长情况最差。温度升高时,CHBr3、CHBr2Cl和CHBrCl2的平均浓度分别增加了10.55%、9.45%和12.18%;pCO2升高时, CHBr3和CHBrCl2的平均浓度分别降低了19.29%和30.... 相似文献
7.
8.
自然资源部第一海洋研究所地球系统模式FIO-ESM是自主研发的、以耦合海浪模式为特色的地球系统模式,包括物理气候模式和全球碳循环模式。该模式从第一代版本FIO-ESM v1.0发展到第二代版本FIO-ESM v2.0,其物理气候模式和全球碳循环模式都取得了改进与提升。FIO-ESM v2.0全球碳循环模式的海洋碳循环模式由v1.0的营养盐驱动模型升级为NPZD(Nutrient-Phytoplankton-Zooplankton-Detritus)型的海洋生态动力学碳循环模型,陆地碳循环模型由v1.0的简单的光能利用率模型升级为考虑碳氮相互作用的碳氮(CN)耦合模型;大气碳循环模型仍为CO2的传输过程,考虑了化石燃料排放、土地利用排放等人为CO2排放量。在物理过程参数化方案方面,FIO-ESM v2.0全球碳循环过程在考虑浪致混合作用对生物地球化学参数的作用的基础上,增加了海表面温度的日变化过程对海-气CO2通量的影响。已有数值模拟试验结果表明,FIO-ESM v2.0在考虑了更加复杂的碳循环过程后仍具有较好的全球碳循环模拟能力,为进一步开展海洋与全球碳循环研究提供了更有力的支撑工具,从而更好地服务于国家的双碳目标。 相似文献
9.
河口红树林湿地CH4通量的日变化研究 总被引:10,自引:0,他引:10
甲烷(CH4)是大气中除CO2外最为丰富的含碳组分,其浓度以每年0.7%-1.1%的速率递增[1,2].尽管大气CH4含量仅为CO2的二百分之一,但却对预计的全球变暖约有20%的贡献率,而CO2的贡献率约为50%[3,4],由这些数据推算得一个分子的CH4比一个分子的CO2(目前最重要的温室气体)的增暖潜值高约80倍.很多研究者对全球大气CH4的预算结果均表明,湿地是大气CH4最重要的生物源[5,6],约占全球CH4源的40%~50%[7].湿地CH4通量的日变化研究是正确估算大时间尺度下CH4排放量(如平均年排放量和季节排放量)的基础,因而具有相当的重要性. 相似文献
10.
CO2升高和阳光紫外辐射对坛紫菜生长和光合特性的耦合效应 总被引:1,自引:0,他引:1
大气CO2持续升高,导致溶入海水中的CO2增多,海水表层的H+浓度增加,从而引起海洋酸化。为了探讨近岸定生大型海藻对这种环境变化的响应,本文选择经济海藻坛紫菜为实验材料,研究海洋酸化与紫外辐射对藻体生长以及光合特性的影响。实验分两个CO2处理,分别为正常空气水平(390 ppmv)和高CO2水平(800 ppmv); 三种辐射处理,分别为全波长辐射(PAB)、滤除紫外线B(PA)和仅接受可见光处理(PAR)。研究结果表明,CO2培养下的坛紫菜,在仅有可见光(P)或者同时有紫外线A(PA)存在的情况下,显著促进藻体的生长;但在全波长辐射处理下(PAB),这种作用不明显。高CO2降低了藻体在P和PA处理下的光合作用速率,但对PAB处理作用不显著。高CO2处理下的藻体,UV-B显著降低了全波长辐射下藻体紫外吸收物质的含量,但在正常CO2水平下,紫外辐射的作用不显著。这表明高CO2导致的生长优势被紫外辐射的负面效应所抵消,在全球变化的过程中,紫外辐射的进一步加强在海洋酸化的背景下甚至有可能降低坛紫菜的产量。 相似文献
11.
Historical simulation and twenty-first century prediction of oceanic CO2 sink and pH change 总被引:1,自引:1,他引:0
A global ocean carbon cycle model based on the ocean general circulation model POP and the improved biogeochemical model OCMIP-2 is employed to simulate carbon cycle processes under the historically observed atmospheric CO 2 concentration and different future scenarios (called Rep- resentative Concentration Pathways, or RCPs). The RCPs in this paper follow the design of Inter- governmental Panel on Climate Change (IPCC) for the Fifth Assessment Report (AR5). The model results show that the ocean absorbs CO 2 from atmosphere and the absorbability will continue in the 21st century under the four RCPs. The net air-sea CO 2 flux increased during the historical time and reached 1.87 Pg/a (calculated by carbon) in 2005; however, it would reach peak and then decrease in the 21st century. The ocean absorbs CO 2 mainly in the mid latitude, and releases CO 2 in the equator area. However, in the Antarctic Circumpolar Current (ACC) area the ocean would change from source to sink under the rising CO 2 concentration, including RCP4.5, RCP6.0, and RCP8.5. In 2100, the anthropogenic carbon would be transported to the 40 S in the Atlantic Ocean by the North Atlantic Deep Water (NADW), and also be transported to the north by the Antarctic Bottom Water (AABW) along the Antarctic continent in the Atlantic and Pacific oceans. The ocean pH value is also simulated by the model. The pH decreased by 0.1 after the industrial revolution, and would continue to decrease in the 21st century. For the highest concentration sce- nario of RCP8.5, the global averaged pH would decrease by 0.43 to reach 7.73 due to the absorption of CO 2 from atmosphere. 相似文献
12.
Hideyuki Nakano Hiroyuki Tsujino Mikitoshi Hirabara Tamaki Yasuda Tatsuo Motoi Masao Ishii Goro Yamanaka 《Journal of Oceanography》2011,67(6):765-783
The uptake mechanism of anthropogenic CO2 in the Kuroshio Extension is examined by a Lagrangian approach using a biogeochemical model embedded in an ocean general circulation model. It is found that the uptake of anthropogenic CO2 is caused mainly by the increase of pCO2 dependency of seawater on temperature, which is caused by greater dissolved inorganic carbon concentration in the modern state than in the pre-industrial state. In contrast with the view of previous studies, the effect of the vertical entrainment, which brings waters that last contacted the atmosphere with the past lower CO2 concentration, is comparatively small. Winter uptake of anthropogenic CO2 increases with the rise of the atmospheric CO2 level, while summer uptake is relatively stable, resulting in a larger seasonal cycle of the uptake. This increase is significant, especially in the Kuroshio Extension region. It is newly suggested that this increase in the Kuroshio Extension region is largely caused by the combined effects of the increased pCO2 dependency of the sea water on the temperature and the seasonal difference in cooling. 相似文献
13.
The Canadian Model of Ocean Carbon (CMOC) has been developed as part of a global coupled climate carbon model. In a stand-alone integration to preindustrial equilibrium, the model ecosystem and global ocean carbon cycle are in general agreement with estimates based on observations. CMOC reproduces global mean estimates and spatial distributions of various indicators of the strength of the biological pump; the spatial distribution of the air-sea exchange of CO2 is consistent with present-day estimates. Agreement with the observed distribution of alkalinity is good, consistent with recent estimates of the mean rain ratio that are lower than historic estimates, and with calcification occurring primarily in the lower latitudes. With anthropogenic emissions and climate forcing from a 1850-2000 climate model simulation, anthropogenic CO2 accumulates at a similar rate and with a similar spatial distribution as estimated from observations. A hypothetical scenario for complete elimination of iron limitation generates maximal rates of uptake of atmospheric CO2 of less than 1 PgC y−1, or about 11% of 2004 industrial emissions. Even a ‘perfect’ future of sustained fertilization would have a minor impact on atmospheric CO2 growth. In the long term, the onset of fertilization causes the ocean to take up an additional 77 PgC after several thousand years, compared with about 84 PgC thought to have occurred during the transition into the last glacial maximum due to iron fertilization associated with increased dust deposition. 相似文献
14.
The ocean captures a large part of the anthropogenic carbon dioxide emitted to the atmosphere. As a result of the increase in CO2 partial pressure the ocean pH is lowered as compared to pre-industrial times and a further decline is expected. Ocean acidification has been proposed to pose a major threat for marine organisms, particularly shell-forming and calcifying organisms. Here we show, on the basis of meta-analysis of available experimental assessments, differences in organism responses to elevated pCO2 and propose that marine biota may be more resistant to ocean acidification than expected. Calcification is most sensitive to ocean acidification while it is questionable if marine functional diversity is impacted significantly along the ranges of acidification predicted for the 21st century. Active biological processes and small-scale temporal and spatial variability in ocean pH may render marine biota far more resistant to ocean acidification than hitherto believed. 相似文献
15.
Global air-sea surface carbon dioxide transfer velocity and flux estimated using 17 a altimeter data and a new algorithm 总被引:1,自引:1,他引:0
The global distributions of the air-sea CO2 transfer velocity and flux are retrieved from TOPEX/Poseidon and Jason altimeter data from October 1992 to December 2009 using a combined algorithm. The 17 a average global, area-weighted, Schmidt number-corrected mean gas transfer velocity is 21.26 cm/h, and the full exploration of the uncertainty of this estimate awaits further data. The average total CO2 flux (calculated by carbon) from atmosphere to ocean during the 17 a was 2.58 Pg/a. The highest transfer velocity is in the circumpolar current area, because of constant high wind speeds and currents there. This results in strong CO2 fluxes. CO2 fluxes are strong but opposite direction in the equatorial east Pacific Ocean, because the air-sea CO2 partial pressure difference is the largest in the global cceans. The results differ from the previous studies calculated using the wind speed. It is demonstrated that the air-sea transfer velocity is very important for estimating air-sea CO2 flux. It is critical to have an accurate estimation for improving calculation of CO2 flux within climate change studies. 相似文献
16.
The interannual variations of CO2 sources and sinks in the surface waters of the Antarctic Ocean (south of 50°S) were studied between 1986 and 1994. An existing, slightly modified one-dimensional model describing the mixed-layer carbon cycle was used for this study and forced by available satellite-derived and climatological data. Between 1986 and 1994, the mean Antarctic Ocean CO2 uptake was 0.53 Pg C year−1 with an interannual variability of 0.15 Pg C year−1.Interannual variation of the Antarctic Ocean CO2 uptake is related to the Antarctic Circumpolar Wave (ACW), which affects sea surface temperature (SST), wind-speed and sea-ice extent. The CO2 uptake in the Antarctic Ocean has increased from 1986 to 1994 by 0.32 Pg C. It was found that over the 9 years, the surface ocean carbon dioxide fugacity (fCO2) increase was half that of the atmospheric CO2 increase inducing an increase of the air–sea fCO2 gradient. This effect is responsible for 60% of the Antarctic Ocean CO2 uptake increase between 1986 and 1994, as the ACW effect cancels out over the 9 years investigated. 相似文献
17.
A. V. Eliseev I. I. Mokhov A. A. Karpenko 《Izvestiya Atmospheric and Oceanic Physics》2007,43(1):1-14
The climate model of intermediate complexity developed at the Oboukhov Institute of Atmospheric Physics, Russian Academy of Sciences (IAP RAS CM), has been supplemented by a zero-dimensional carbon cycle model. With the carbon dioxide emissions prescribed for the second half of the 19th century and for the 20th century, the model satisfactorily reproduces characteristics of the carbon cycle over this period. However, with continued anthropogenic CO2 emissions (SRES scenarios A1B, A2, B1, and B2), the climate-carbon cycle feedback in the model leads to an additional atmospheric CO2 increase (in comparison with the case where the influence of climate changes on the carbon exchange between the atmosphere and the underlying surface is disregarded). This additional increase is varied in the range 67–90 ppmv depending on the scenario and is mainly due to the dynamics of soil carbon storage. The climate-carbon cycle feedback parameter varies nonmonotonically with time. Positions of its extremes separate characteristic periods of the change in the intensity of anthropogenic emissions and of climate variations. By the end of the 21st century, depending on the emission scenario, the carbon dioxide concentration is expected to increase to 615–875 ppmv and the global temperature will rise by 2.4–3.4 K relative to the preindustrial value. In the 20th–21st centuries, a general growth of the buildup of carbon dioxide in the atmosphere and ocean and its reduction in terrestrial ecosystems can be expected. In general, by the end of the 21st century, the more aggressive emission scenarios are characterized by a smaller climate-carbon cycle feedback parameter, a lower sensitivity of climate to a single increase in the atmospheric concentration of carbon dioxide, a larger fraction of anthropogenic emissions stored in the atmosphere and the ocean, and a smaller fraction of emissions in terrestrial ecosystems. 相似文献
18.
Evangelia Krasakopoulou Ekaterini Souvermezoglou Catherine Goyet 《Deep Sea Research Part I: Oceanographic Research Papers》2011,58(11):1103-1114
This study presents the distribution and fluxes of dissolved inorganic carbon (CT), total alkalinity (AT) and anthropogenic carbon (Cant) along the Otranto strait, during February 1995. Based on a limited number of properties (temperature, dissolved oxygen, total alkalinity and dissolved inorganic carbon), the composite tracer TrOCA was used to estimate the concentration of anthropogenic CO2 in the Otranto strait.Total alkalinity exhibits high values and weak variability throughout the water column of the strait, probably associated with the dense water formation processes in the Adriatic basin that induce a rapid transport of the coastal alkalinity to the deep waters. Elevated Cant concentrations and high anthropogenic pH variations are observed in the bottom layer of the strait, associated with the presence of Adriatic Deep Water (ADW). The study shows that large amounts of Cant have penetrated the highly alkaline Eastern Mediterranean waters, thereby causing a significant pH reduction since the pre-industrial era.Estimates of the transports of CT and Cant through the strait indicate that during February 1995, the Adriatic Sea imports through the Otranto strait natural and anthropogenic carbon and acts as a net sink of carbon for the Ionian Sea. The anthropogenic carbon that is imported to the Adriatic Sea represents less than 1% of the net CT inflow. The Levantine Intermediate Water (LIW) contributes to about one-third of the total CT and Cant inflow. Although the amounts of Cant annually transported by LIW and ADW are almost equal, the contribution of Cant to the CT transported by each water mass is slightly higher in ADW (3.1%) than in LIW (2.6%), as a result of its higher mean Cant concentration. The ADW, despite its weak contribution to the total outflow of Cant, has a vital role for the sequestration and storage of the anthropogenic carbon, as this water mass is the main component of the Eastern Mediterranean Deep Waters and, thus, the anthropogenic CO2 is transferred in the deep horizons of the Eastern Mediterranean, where it remains isolated for many years. 相似文献
19.
Katsumi Matsumoto 《Journal of Oceanography》2006,62(6):887-902
Iron fertilization of nutrient-rich surface waters of the ocean is one possible way to help slow the rising levels of atmospheric
CO2 by sequestering it in the oceans via biological carbon export. Here, I use an ocean general circulation model to simulate
a patch of nutrient depletion in the subpolar northwest Pacific under various scenarios. Model results confirm that surface
fertilization is an inefficient way to sequester carbon from the atmosphere (Gnanadesikan et al., 2003), since only about 20% of the exported carbon comes initially from the atmosphere. Fertilization reduces future production
and thus CO2 uptake by utilizing nutrients that would otherwise be available later. Effectively, this can be considered as leakage when
compared to a control run. This “effective” leakage and the actual leakage of sequestered CO2 cause a significant, rapid decrease in carbon retention (only 30–45% retained after 10 years and less than 20% after 50 years).
This contrasts markedly with the almost 100% retention efficiency for the same duration using the same model, when carbon
is disposed directly into the northwest Pacific (Matsumoto and Mignone, 2005). As a consequence, the economic effectiveness
of patch fertilization is poor in two limiting cases of the future price path of carbon. Sequestered carbon in patch fertilization
is lost to the atmosphere at increasingly remote places as time passes, which would make monitoring exceedingly difficult.
If all organic carbon from one-time fertilization reached the ocean bottom and remineralized there, acidification would be
about −0.05 pH unit with O2 depletion about −20 μmol kg−1. These anomalies are probably too small to seriously threaten deep sea biota, but they are underestimated in the model because
of its large grid size. The results from this study offer little to advocate purposeful surface fertilization as a serious
means to address the anthropogenic carbon problem. 相似文献