共查询到20条相似文献,搜索用时 561 毫秒
1.
简要介绍了全球海洋Argo 网格资料集的制作过程,并着重探讨了该数据集与历史观测资料集(如WOA09 和TAO),
以及同类型的Argo 网格数据集等进行的比较与验证结果,发现利用逐步订正法构建的Argo 网格资料与其他数据集相比,除
了相互间吻合程度较高,能较客观地呈现出全球海洋中的一些大、中尺度海洋特征外,由Argo 资料揭示的一些重要物理海
洋特征的结构显得更细致,更能反映这些现象的演变过程和变化规律;加上Argo 资料严格的质量控制过程,确保了重构的
网格数据集的质量和可靠性。该资料集不仅可以作为研究全球海洋状况或揭示物理海洋现象的基础资料,还可为海洋数值模
式的开边界和初始场提供参考依据。 相似文献
2.
参考数据集对Argo剖面浮标盐度观测资料校正的影响 总被引:4,自引:0,他引:4
国际Argo计划采用新颖的Argo剖面浮标来监测全球大洋中上层的变化,对浮标盐度观测资料进行质量控制是非常重要的。本文采用历史水文观测资料集得到的温-盐度(-S)关系,并利用Wong等人开发的WJO延时模式盐度校正方法,对电导率传感器出现漂移、偏移等故障的Argo剖面浮标盐度资料进行校正。对影响校正结果的历史水文资料集(或参考数据集)的选取进行了初步研究,并在不同的海区进行试验。结果表明,选取合适的参考数据集可以提高盐度校正的精度。 相似文献
3.
提出了海表温度(SST)和海表盐度(SSS)可统一由混合层深度内对应的平均温、盐度作零阶近似的理论假设,据此利用Chu等提出的最大角度法构建混合层模型,并考虑障碍层和补偿层的影响,得到合成的混合层深度,从而实现了基于混合层模型反推SST和SSS。以太平洋海域为例,分别利用WOA13气候态(1-12月)资料、TAO逐年逐月资料以及历史船载CTD资料检验了这一假设。不同资料检验结果均表明,反推得到的SST、SSS与实测值相关性较高,两者之间残差也较小。将此方法应用于Argo剖面,反推出对应的SST和SSS,并利用逐步订正法对散点资料进行客观分析,生成2004年1月-2014年12月逐年逐月的1°×1°的网格化SST和SSS。对网格资料进行检验,结果发现由Argo反推的SST和SSS气候态分布特征与WOA13资料非常相似,差异不大;与TAO实测资料相关性较好,甚至略高于同类型网格资料与TAO资料的相关系数;EOF分析表明,无论是空间还是时间的主要变化模态,与同类型的网格资料符合性较好。综合来看,构建的混合层模型可以用于Argo表层温、盐度的反推,获得较高质量的SST和SSS,能较好弥补Argo缺乏表层资料的不足。 相似文献
4.
利用逐步订正法构建了2002年1月-2009年12月期间太平洋海域(60oS-60oN,120oE-80oW)的逐月温、盐度网格资料,其垂向分辩率在5-1950m水深范围内为48层,水平分辨率为1o×1o。对网格资料的误差分析表明,整个太平洋海域温度和盐度标准差的平均值分别为0.097℃和?0.017。将构建的Argo(Array?for?Real-time?Geostrophic?Oceanography,Argo)网格资料集与研究海域获取的CTD(Conductance-Temperature-Depth,)、TAO(Tropical?Atmosphere/Ocean?array,TAO)和WOA05(World?Ocean?Alta?5)等资料集进行的比较和分析发现,2006年之前,由于Argo资料相对较少,导致构建的网格资料集存在一定的误差;而在2006年以后的Argo网格资料则与历史观测资料比较一致。况且,由构建的Argo网格资料集揭示的太平洋海域温、盐度分布的主要特征来看,其与WOA05资料集所反映的结果也十分吻合,且前者揭示的特征比后者要更加细致些。这充分说明了,利用逐步订正法构建的Argo网格资料集是值得信赖的,也是可靠的。 相似文献
5.
基于2017版全球海洋Argo网格数据集(BOA-Argo),利用最大角度法和梯度比值法等客观分析方法计算了2004年1月—2016年12月期间,西太平洋海域(25°S~40°N,120°~180°E)的上混合层和温跃层上、下界深度,并计算了混合层温盐度以及温跃层强度等海洋环境参数,制作完成水平分辨率为1°×1°的月平均Argo数据衍生产品。将本数据产品和采用阈值法计算得到MILA GPV数据集做比较,结果显示:对于混合层的主要空间分布特征和时间序列变化特征,两者都十分吻合;将西太平洋海域温跃层上、下界深度和强度等参数与人们利用传统的温度梯度法计算结果相比较,其季节分布特征及变化趋势也大体相符。 相似文献
6.
Argo浮标观测已成为全球海洋观测系统的重要支柱,但因缺乏表层观测,使得Argo观测资料在海洋和大气研究中的应用仍有一定的局限性。基于一个简化的海洋温度参数模型,由Argo剖面观测及气候态数据所确定的垂向海洋温度参数,得到表层与次表层温度的函数关系,进而利用太平洋海域的Argo次表层温度数据来推算表层温度场。其中,海温参数模型的相关参数采用最大角度法求得,利用此方法得到的混合层深度,温跃层梯度,温跃层下边界等参数较以往的迭代法更精确。与传统采用外插方式得到的表层温度场及卫星反演的SST相比,推算的Argo表层温度与GTSPP、Argo NST等实测资料的标准差有了显著地降低;与Argo NST现场观测数据的相关性分析也表明,推算的表层温度与实测资料有着更好地一致性;通过相关分析检验,在理论上验证了在太平洋海域利用海温参数模型推算海表温度的可行性。本研究为弥补当前Argo资料缺乏表层观测的缺陷,构建完备的Argo网格化温度数据集提供了新途径,具有重要的科学意义和应用价值。 相似文献
7.
8.
数据集整体的时空覆盖率制约了海洋科学研究的时空尺度,而海洋仪器的性能和观测方式直接决定了海洋数据的可靠性。以观测仪器作为主要衡量指标,结合数据集的时空覆盖率,对以温度和盐度为数据集主体的自持式拉格朗日环流剖面观测(Argo)数据集、全球温盐剖面数据集(GTSPP)、世界海洋数据集(WOD)进行分析和比对,确定了三者关系:Argo和GTSPP都是WOD的数据源,而GTSPP中包含了Argo实时数据的80%。在此基础上研究确定了目前温盐数据的主要观测仪器为Argo浮标、XBT和CTD,并对这三种仪器的误差来源和量级进行详细分析:由于全球自动观测与传输需求,Argo数据存在电子信号不稳定导致的随机误差,而且在高纬度强温跃层地带出现较强的虚假盐度尖峰,再是自由漂移的特性导致1%~2%盐度剖面漂移超过0.02 PSS-78;由于下降方程的不断演变,全球半数XBT数据提供者并未提供仪器型号,导致数据整体的可靠性下降;由于CTD基本采用船载观测,因此成本高、共享数据少且多集中近海。因此在对全球温盐数据进行应用时,应综合考虑观测仪器的可靠性和时空覆盖率,有效实现对资料本身误差和真实海洋现象的甄别。 相似文献
9.
本文应用一个经验证的全球尺度FVCOM海浪模型,模拟了2012年全球海洋海浪场的分布和演变,分析了海表面风场、海浪场与混合层深度的全球尺度分布及相关性。综合观测资料和模型结果显示,海表面10 m风速、有效波高与混合层深度的全球尺度分布随季节发生显著的变化,并且其分布态势存在明显的相似性。从相关系数的全球分布来看,海表面10 m风速在印度洋低纬度海区(纬度0°~20°)与混合层深度间有较强的相关性,相关系数大于0.5;有效波高与混合层深度间相关系数大于0.5的网格分布在北半球高纬度海区和印度洋北部。谱峰周期与混合层深度间在部分海区存在负相关关系,这些网格主要分布在低纬度海区(纬度0°~30°)。统计结果显示,有效波高、海表面10 m风速和谱峰周期与混合层深度间的平均相关系数分别为0.31、0.25和0.12。综合以上结果表明,有效波高较谱峰周期能更有效地表征波浪能对海洋上层混合的影响;相比于海表面风速,有效波高与混合层深度间存在更强的相关关系,其变化对海洋上层混合有更显著的影响。 相似文献
10.
基于Argo浮标的热带印度洋混合层深度季节变化研究 总被引:2,自引:0,他引:2
根据2004-2005年热带印度洋(30°S以北)的Argo浮标(自持式海洋剖面观测浮标)温度-盐度剖面观测资料,采用位势密度判据(Δσθ=0.03 kg/m3),针对每个Argo浮标的温度-盐度观测剖面确定了海洋混合层的深度,然后采用Krig插值方法构建了3°×3°空间分辨率的月平均网格化混合层深度产品。通过与已有气候平均混合层深度资料的比较表明了该产品的合理性,在此基础上进一步对热带印度洋海盆尺度的混合层深度空间特征和季节变化规律进行了讨论。研究结果表明,Argo浮标资料可用于热带印度洋混合层变化的研究,为进一步研究热带印度洋海-气相互作用提供了基础资料。 相似文献
11.
A new 0.1° gridded daily sea surface temperature(SST) data product is presented covering the years 2003–2015. It is created by fusing satellite SST data retrievals from four microwave(Wind Sat, AMSR-E, ASMR2 and HY-2 A RM)and two infrared(MODIS and AVHRR) radiometers(RMs) based on the optimum interpolation(OI) method. The effect of including HY-2 A RM SST data in the fusion product is studied, and the accuracy of the new SST product is determined by various comparisons with moored and drifting buoy measurements. An evaluation using global tropical moored buoy measurements shows that the root mean square error(RMSE) of the new gridded SST product is generally less than 0.5℃. A comparison with US National Data Buoy Center meteorological and oceanographic moored buoy observations shows that the RMSE of the new product is generally less than 0.8℃. A comparison with measurements from drifting buoys shows an RMSE of 0.52–0.69℃. Furthermore, the consistency of the new gridded SST dataset and the Remote Sensing Systems microwave-infrared SST dataset is evaluated, and the result shows that no significant inconsistency exists between these two products. 相似文献
12.
A global data set describing the gridded mixed-layer depth (MLD) in 10-day intervals was produced using high-quality Argo
float data from 2001 to 2009. The characteristics and advantages provided by the new MLD data set are described here, including
a comparison based on two different thresholds and using data sets of different vertical and temporal resolution. The MLD
in the data set was estimated on the basis of a shallower depth of the iso-thermal layer (TLD) or iso-pycnal layer (PLD),
calculated using the finite difference method. The MLD data are incorporated into 2° × 2° grid in the global ocean, including
marginal seas. Also, two threshold values were used to examine differences in the MLD and its seasonal temporal variability.
The characteristics and advantages of using the Argo 10-day intervals to determine the MLD were then confirmed by comparing
those data with the station buoy daily means and the Argo monthly means. With respect to vertical and temporal resolutions,
the Argo 10-day data has two distinct advantages: (1) improved representation of the MLD vertical change due to high vertical
resolution, especially during periods of large MLD variability and (2) more detailed representation of the temporal change
in MLD than achieved with the Argo monthly mean data, especially from winter to spring in mid and high latitudes. These advantages
were maintained in the case of a larger threshold despite the fact that the MLD is rather deep and the detailed variation
in its distribution differs depending on the season and location. This study also investigated the relative influence of TLD
and PLD to the MLD calculation for each grid. Generally, the MLD is primarily determined based on the PLD at low and mid latitudes
(TLD > PLD), whereas the TLD is more important at high latitudes, especially in winter (TLD < PLD). In the case of a larger
threshold, the area of the larger PLD influence spreads polewards because of the greater effect of salinity in winter. Although
there are some differences in the effect of temperature and salinity in estimations of the MLD, both are indispensable factors
for the MLD estimations even at different thresholds. 相似文献
13.
A monthly mean climatology of the mixed layer depth (MLD) in the North Pacific has been produced by using Argo observations.
The optimum method and parameter for evaluating the MLD from the Argo data are statistically determined. The MLD and its properties
from each density profile were calculated with the method and parameter. The monthly mean climatology of the MLD is computed
on a 2° × 2° grid with more than 30 profiles for each grid. Two bands of deep mixed layer with more than 200 m depth are found
to the north and south of the Kuroshio Extension in the winter climatology, which cannot be reproduced in some previous climatologies.
Early shoaling of the winter mixed layer between 20–30°N, which has been pointed out by previous studies, is also well recognized.
A notable feature suggested by our climatology is that the deepest mixed layer tends to occur about one month before the mixed
layer density peaks in the middle latitudes, especially in the western region, while they tend to coincide with each other
in higher latitudes. 相似文献
14.
过去对南大洋的研究受限于长期观测的缺乏,而现在地转海洋学实时观测阵(Arrayfor Real-timeGeostrophicOceanography,Argo)项目自开始以来持续提供了高质量的温度盐度观测,使系统地研究南大洋海洋上层结构成为可能。本研究使用2000—2018年的Argo浮标观测数据,分析了南大洋混合层深度(Mixed Layer Depth, MLD)的时空分布特征。结果表明:南大洋混合层存在明显的季节变化,冬春两季MLD在副南极锋面北侧达到最高值并呈带状分布,夏秋两季由于海表加热导致混合层变浅,季节变化幅度达到400m以上;在年际尺度上,MLD受南半球环状模(Southern HemisphereAnnularMode,SAM)调制,呈现纬向不对称空间分布特征,这与前人结果一致;本文指出在所研究时段,南大洋混合层在90°E以东,180°以西有加深趋势,而在60°W以西,180°以东有变浅趋势,显示出偶极子分布特征,并且这种趋势特征主要是风场的作用。 相似文献
15.
The role of meso-scale eddies in mixed layer deepening and mode water formation in the western North Pacific 总被引:3,自引:1,他引:2
Shinya Kouketsu Hiroyuki Tomita Eitarou Oka Shigeki Hosoda Taiyo Kobayashi Kanako Sato 《Journal of Oceanography》2012,68(1):63-77
Distributions of mixed layer depths around the centers of anti-cyclonic and cyclonic eddies in the North Pacific Ocean were
composited by using satellite-derived sea surface height anomaly data and Argo profiling float data. The composite distributions
showed that in late winter, deeper mixed layers were more (less) frequently observed inside the cores of the anti-cyclonic
(cyclonic) eddies than outside. This relationship was the clearest in the region of 140°E–160°W and 35°N–40°N, where the temperature
and salinity of the deep mixed layers were similar to those of the lighter variety of central mode water (L-CMW). A simple
one-dimensional bulk mixed layer model showed that both strong sea-surface heat and momentum fluxes and weak preexisting stratification
contributed to formation of the deep mixed layer. These conditions were associated with the anti-cyclonic eddies, suggesting
that these eddies are important in the formation of mode waters, particularly L-CMW. 相似文献
16.
Zeng’an Deng Jiye Jin Fengying Ji Feng Zhang Xiaoyi Jiang Wei Wang 《Marine Geodesy》2013,36(1):109-122
Tracer diffusion is an important issue in ocean modeling, and isoneutral slope is key to parameterization of tracer diffusion in the ocean interior when using the isoneutral/dianeutral scheme. In this study, multiyear mean temperature, salinity, and pressure-gridded products that cover the upper 2000 m of the global ocean are created by employing all the Argo float observations up to date. Comparison with WOA09 data indicates that Argo temperature and salinity depict the reality well. Based on the reliable Argo gridded products, the in situ density fields are calculated. Then isoneutral slope in the ocean interior deep to 2000 m was determined by using the Argo-derived density. Taking advantage of isoneutral slope, therefore, diffusion tensor as well as isoneutral tracer diffusion flux can be obtained in combination of the tracer diffusion coefficient. The aim of this work is to propose a procedure to estimate the isoneutral slope using Argo observations and to offer new isoneutral slope-gridded products in the hope of further facilitating the parameterization of isoneutral tracer diffusion in geopotential (Z-coordinate) ocean models. 相似文献
17.
18.
The Argo float observations are used to investigate the mesoscale characteristics of the Antarctic Intermediate Water(AAIW) in the South Pacific in this paper. It is shown that a subsurface mesoscale phenomenon is probably touched by an Argo float during the float's ascent-descent cycles and is identified by the horizontal salinity gradient between the vertical temperature-salinity profiles. This shows that the transportation of the AAIW may be accompanied with the rich mesoscale characteristics. To derive the spatial length, time, and propagation characteristics of the mesoscale variability of the AAIW, the gridded temperature-salinity dataset ENACT/ENSEMBLE Version 3 constructed on the in-situ observations in the South Pacific since 2005 is used. The Empirical Mode Decomposition method is applied to decompose the isopycnal-averaged salinity anomaly from26.8 σθ–27.4 σθ, where the AAIW mainly resides, into the basin scale and two mesoscale modes. It is found that the first mesoscale mode with the length scale on the order of 1 000 km explains nearly 50% variability of the mesoscale characteristics of the AAIW. Its westward-propagation speeds are slower in the mid-latitude(around 1cm/s) and faster in the low latitude(around 6 cm/s), but with an increasing in the latitude band on 25°–30°S. The second mesoscale mode is of the length scale on the order of 500 km, explaining about 30% variability of the mesoscale characteristics of the AAIW. Its westward-propagation speed keeps nearly unchanged(around 0.5cm/s). These results presented the stronger turbulent motion of the subsurface ocean on the spatial scale, and also described the significant role of Argo program for the better understanding of the deep ocean. 相似文献
19.
Naoto Iwasaka Fumiaki Kobashi Yosuke Kinoshita Yuko Ohno 《Journal of Oceanography》2006,62(4):481-492
A seasonal evolution of surface mixed layer in the western North Pacific around 24°N between 143°E and 150°E was observed
by using an Argo float for more than 9 months, from December 2001 through August 2002. The result showed that the mixed layer
deepened gradually in the first two months. It reached its maximum depth of about 130 m at the end of January, after which
the mixed layer varied largely and sometimes the pycnocline below the mixed layer was much weakened until the summer mixed
layer formed in late April. The thin surface mixed layer was maintained during the rest of the observation period. Heat budget
analysis suggests that the vertical and horizontal temperature advections are the two most dominant terms in the heat balance
in the upper layer on time scales from a few days to a month. The vertical motions that are possibly responsible for the vertical
temperature advection are discussed. 相似文献
20.
Seasonal evolution of surface mixed layer in the Northern Arabian Sea (NAS) between 17° N–20.5° N and 59° E-69° E was observed
by using Argo float daily data for about 9 months, from April 2002 through December 2002. Results showed that during April
- May mixed layer shoaled due to light winds, clear sky and intense solar insolation. Sea surface temperature (SST) rose by
2.3 °C and ocean gained an average of 99.8 Wm−2. Mixed layer reached maximum depth of about 71 m during June - September owing to strong winds and cloudy skies. Ocean gained
abnormally low ∼18 Wm−2 and SST dropped by 3.4 °C. During the inter monsoon period, October, mixed layer shoaled and maintained a depth of 20 to
30 m. November - December was accompanied by moderate winds, dropping of SST by 1.5 °C and ocean lost an average of 52.5 Wm−2. Mixed layer deepened gradually reaching a maximum of 62 m in December. Analysis of surface fluxes and winds suggested that
winds and fluxes are the dominating factors causing deepening of mixed layer during summer and winter monsoon periods respectively.
Relatively high correlation between MLD, net heat flux and wind speed revealed that short term variability of MLD coincided
well with short term variability of surface forcing. 相似文献