Variations of atomic mercury concentration in atmospheric surface layer over the Ussuri Bay of the Sea of Japan during the typhoon Bolaven passage in 2012

Presented are the results of measuring the concentration of atomic mercury Hg⁰ on August 28–30, 2012 in the atmospheric surface layer over the Ussuri Bay in the Sea of Japan during the typhoon Bolaven passage. It is revealed that the Hg⁰ concentration during this period varied from 1.7 to 3.3 ng/m³. The maximum values were observed at the coming of mercury-enriched air masses from the Yellow Sea area at the simultaneous decrease in the air pressure and increase in the wind speed.     

On the air‐sea interaction in areas of thermal marine fronts in the Greenland Sea

Abstract

The effects of marine fronts on the local atmospheric surface layer and air‐sea interaction were studied. Several mesoscale fronts were crossed by a research vessel in the Greenland Sea. Air temperature, humidity and stability conditions, and the fluxes of momentum, as well as sensible and latent heat, were investigated. For relatively calm conditions, close air‐sea coupling was observed in the temperature whereas for stronger winds, the air temperature of the surface layer was not markedly modified by the front below. Changes in the moisture content in the frontal area were observed and, in one case, evaporation was observed on the warm water side and condensation on the cold water side of the front. Frontal differences in heating from the sea were assumed to affect the surface‐layer wind field.     

Numerical Simulation of the Novaya Zemlya Bora

The development of the bora in case of strong southeastern wind in the area of Novaya Zemlya in the winter-spring of 2016 is simulated using the WRF-ARW numerical atmosphere circulation model with high spatial resolution. The features of wind speed and air temperature fields are considered which define the formation of the intensive near-surface flow, the bora, over the lee western slope of the mountain range. It is demonstrated that the bora development leads to the air temperature rise over the eastern part of the Barents Sea, to the increased surface heat fluxes, and to the formation of the cloudless zone over the sea westward of Novaya Zemlya. It was found that the main reason for the bora development is the high stability of the atmospheric boundary layer over the Kara Sea. It is shown that in case of western wind the Novaya Zemlya archipelago does not exert considerable influence on the air exchange in the Kara Sea area.     

青岛一次中到大雪过程的综合分析

2005年2月17～18日，受冷空气和较强暖湿气流共同影响，青岛发生中到大雪降雪过程。对这次过程的环流背景和雷达资料进行综合分析表明，低空暖平流、垂直风切变和高空西风急流提供了有利的动力条件，中空西南气流和近地层从黄渤海海面的水汽输送提供了降水所需的水汽。随着2．0～2．7km高度上，一个以青岛为中心的中尺度气旋性风场的出现，降雪强度迅速达到最强，该风场破坏，降雪强度也迅速减弱；雷达回波首先出现在3．0～5．5km的高度上，然后向上下扩展加强；降雪初期，0．8～3．2km高度上有弱回波区。     

Interannual variations of sea water parameters and chlorophyll a concentration in the Japan Sea in autumn

Studied are the interannual variations of physical (temperature, salinity, and relative density) and chemical (dissolved oxygen and biogenic elements) parameters of sea water and chlorophyll a concentration in the Japan Sea in autumn. It is demonstrated that the increase in the water flow from the East China Sea through the Korea (Tsushima) Strait leads to the temperature rise and decrease in salinity and dissolved oxygen content in the surface water layer of the Japan Sea. It is revealed that in the central part of the Japan Sea from 1978 to 2012 trends were observed towards the increase in the content of dissolved inorganic nitrogen N, decrease in the content of inorganic phosphorus, and decrease in the concentration of chlorophyll a at the level of 50 m and its increase in the layer of 0–30 m. The observed trends are explained by the intensification of the effect of coastal water of the East China Sea subjected to the significant anthropogenic load on the water of the central part of the Japan Sea.     

11月初北黄海一次海龙卷风暴的中尺度特征分析

利用多普勒天气雷达资料及反演风场和常规观测资料,对2014年11月2日发生在北黄海（山东半岛北部海上）一次罕见海龙卷风暴的中尺度特征进行了分析。结果表明：冷空气、暖湿海面热力边界、山东半岛北部近海岸西北风与偏西风的辐合线是海龙卷风暴发生的天气背景。海龙卷风暴发生时雷达回波PPI最大分贝反射率因子为60 dBZ,高度为2.0 km,最高风暴顶为4.5 km,最大垂直累积液态水含量VIL为21 kg·m-2。利用雷达反演风场进行中尺度特征分析,结果表明：在海龙卷风暴发生发展过程中,低层风辐合对应4.0 km高度上是风辐散,海上有较强的偏南暖湿气流输送到雷暴区。中尺度动力特征：最大正涡度和散度辐合在1.0 km以下,低层正涡度和散度辐合、高层散度辐散是雷暴发生初期动力特征;低层没有正涡度和散度辐合、高层为正涡度和散度辐合是雷暴开始发展的动力特征;低层和高层为大的正涡度和散度辐合是雷暴成熟阶段的动力特征。高空冷空气叠加上低空强的偏南气流,造成局地涡度加大和低层辐合加强,使低层暖湿气流倾斜上升。海龙卷与辐合区的冷空气和暖湿气流有关。     

On the analysis of wind wave-induced disturbances in the atmospheric turbulent surface layer

Simultaneous measurements of wind velocity, air humidity and sea surface wave-elevation fluctuations obtained on a platform in the open Caspian Sea are analyzed.It is shown that wave noises exist in the spectra and cospectra of the lower part of the atmospheric boundary layer, not only for the frequency of the main energy transporting component of the sea waves, but also in other parts of the spectra, at both lower and higher frequencies. The high frequencies are noncoherent with the sea waves and could be considered as measurement errors due to the existence of the waves. A method of elimination of the coherent wave noises from the spectra and cospectra is suggested and the effectiveness of its application is demonstrated.The essential difference between cases of developing and decaying wind waves is demonstrated.     

Structures and characteristics of the windy atmospheric boundary layer in the South China Sea region during cold surges

An observational analysis of the structures and characteristics of a windy atmospheric boundary layer during a cold air outbreak in the South China Sea region is reported in this paper. It is found that the main structures and characteristics are the same as during strong wind episodes with cold air outbreaks on land. The high frequency turbulent fluctuations(period<1 min) are nearly random and isotropic with weak coherency, but the gusty wind disturbances(1 min相似文献   

华南沿海暖海雾过程中的湍流热量交换特征

湍流交换是海雾中的关键物理过程, 在海雾的热量和水汽平衡过程中起重要作用。本文根据2007年3月24～25日一次海雾的外场观测数据, 分析了海雾过程中近海面湍流热量交换特征; 并在区分风切变机械湍流与雾顶长波辐射冷却热力湍流的基础上, 着重分析了两种不同性质的湍流对海雾发展和维持的作用。结果表明: (1) 本次海雾是在西南低压和变性冷高压的控制下, 来自南海东部暖水区的空气平流在近岸冷海面上形成的暖海雾; 暖海雾中的湍流热量交换过程比冷海雾更为复杂; (2) 在暖海雾的形成和消散阶段, 风切变机械湍流的热量输送起主要作用; 而在发展和维持阶段, 既有风切变机械湍流的热量输送作用, 也有雾顶长波辐射冷却热力湍流的热量输送作用; (3) 风切变机械湍流向冷海面输送热量, 对近海面空气起到降温和增湿作用; 热力湍流同样向冷海面输送热量, 但对雾层起到增温和降湿作用; (4) 暖海雾中的湍流热量交换机制与雾层的非充分混合结构有密切关系。     

大连地区大雾特征

选取2007年2月和4月出现在大连及其沿海地区的两次大雾过程, 采用GTS1型数字式探空仪探测资料、常规观测资料和NCEP/NCAR再分析资料, 对其环境场、热力和动力作用等进行诊断分析。结果表明:大雾期间, 中高纬度地区高空纬向暖干气流和对流层中下层西南暖湿气流, 为大雾形成提供了有利的水汽和风场条件。低层大气稳定层结的建立及暖干空气与雾层的上下叠置, 有利于大雾的维持。黄渤海的海温作用使冬季地面冷高压进一步增温变性, 有利于辐射雾形成发展, 使春季的暖气团冷却凝结, 有利于平流冷却雾的生成维持。伴有冷平流东移南下的偏北风是促使持续大雾消散的动力因子。     

变分方法在渤海海域ASCAT风场订正中的应用

利用渤海观测站风场对ASCAT风场进行检验,发现其风速、风向均有较大误差,尤其在渤海中部以外的海域可信度相对较低。为提高ASCAT风场在渤海海域的精度,基于变分方法,利用渤海观测站风场对2017年9月—2018年2月的ASCAT风场进行订正,得到空间分辨率为12.5 km×12.5 km的订正风场。并对辽东湾、渤海湾、莱州湾、渤海中部和渤海海峡5个海域风场的订正误差进行检验,结果表明:ASCAT风场订正后精度提高显著,风速平均偏差从4 m·s-1减小为1 m·s-1,风向平均偏差从-30°~30°减小为-7°~4°,可见变分方法对渤海ASCAT风场有很好的订正效果,尤其对误差较大的渤海湾订正效果最为明显。对2017年12月18日的一次大风过程进行订正分析,结果表明:订正风场可以很好地反映沿岸风场信息和大风过程中的风速极值区,并能动态监测大风变化过程。变分方法解决了海面观测数据空间分辨率低、ASCAT数据精度低的问题,能够实时监测海上大风,且对大风预报有很好的指导意义,能够为海洋模式提供更精确的初始场。     

“09.4.15”渤海和山东强风过程的动力学诊断分析

2009年4月15日,渤海和山东大部出现了一次强风天气过程。本次过程具有强度大、持续时间短、强风在渤海及山东附近显著加强等特点。为探讨强风的成因,根据常规观测资料以及NCEP分析资料进行了诊断分析。结果表明,本次强风过程是在低层冷锋、高层低涡横槽影响下产生的。冷空气向南推进过程中,冷平流中心由高层向低层传播,850 hPa以下冷平流不断加强,使冷锋不断增强。冷空气到达渤海湾后,锋前的强暖平流与锋后的强冷平流造成低空锋区进一步增强。冷锋次级环流的下沉运动与地面正变压中心对应,变压梯度风与大尺度气压梯度风共同造成强风过程,而强风中的阵风可能与次级环流的强烈脉动有关。     

Atmospheric dispersion in the arctic: Winter-time boundary-layer measurements

The winter-time arctic atmospheric boundary layer was investigated with micrometeorological and SF₆ tracer measurements collected in Prudhoe Bay, Alaska. The flat, snow-covered tundra surface at this site generates a very small (0.03 cm) surface roughness. The relatively warm maritime air mass originating over the nearby, partially frozen Beaufort Sea is cooled at the tundra surface resulting in strong (4 to 30 °C · (100 m)^-1) temperature inversions with light winds and a persistent weak (1 to 2 °C · (100 m)^-1) surface inversion with wind speeds up to 17 m s^-1. The absence of any diurnal atmospheric stability pattern during the study was due to the very limited solar insolation. Vertical profiles were measured with a multi-level mast from 1 to 17 m and with a Doppler acoustic sounder from 60 to 450 m. With high wind speeds, stable layers below 17 m and above 300 m were typically separated by a layer of neutral stability. Turbulence statistics and spectra calculated at a height of 33 m are similar to measurements reported for non-arctic, open terrain sites and indicate that the production of turbulence is primarily due to wind shear. The distribution of wind direction recorded at 1 Hz was frequently non-Gaussian for 1-hr periods but was always Gaussian for 5-min periods. We also observed non-Gaussian hourly averaged crosswind concentration profiles and assume that they can be modeled by calculating sequential short-term concentrations, using the 5-min standard deviation of horizontal wind direction fluctuations () to estimate a horizontal dispersion coefficient ( _y ), and constructing hourly concentrations by averaging the short-term results. Non-Gaussian hourly crosswind distributions are not unique to the arctic and can be observed at most field sites. A weak correlation between horizontal ( _v ) and vertical ( _w ) turbulence observed for both 1-hr and 5-min periods indicates that a single stability classification method is not sufficient to determine both vertical and horizontal dispersion at this site. An estimate of the vertical dispersion coefficient, _z , could be based on or a stability classification parameter which includes vertical thermal and wind shear effects (e.g., Monin-Obukhov length, L).     

In the Core of the Night-Effects of Intermittent Mixing on a Horizontally Heterogeneous Surface

Intermittent breakdowns that accompany wind gusts at the surface are responsible for a large fraction of the turbulent exchange between the surface and the upper boundary layer in the core of clear nights. Vertical and horizontal structure of the breakdowns are investigated using data from a network of 26 stations in an area of 30 km × 30 km. Surface heterogeneity in the area includes complex terrain with different types of land cover. We treat the fine-scale landscape structure near sensors (sheltering) as a separate component of heterogeneity. These features have important consequences on the spatial distribution of mean variables and surface fluxes. We found that breakdowns connect the surface layer to a higher level (level H_C). Weak wind gusts below a threshold (approximately 1.5 m s^-1) mix the air down to the colder ground, cooling the surface layer. On the other hand, wind gusts above this threshold promote mixing with upper levels, warming the surface layer. The spatial maximum of surface temperature over the network can be used as an estimate of the temperature at H_C, allowing vertical gradients and stability to be approximated. Minimum temperature is a function of topography and sheltering. Appreciable surface fluxes at night occur primarily at high, open locations, and can be large enough there to influencearea-averaged values. Surface-fluxparameterizations currently used in mesoscale models were tested first by estimating fluxes at each station and aggregating, and then by formingarea-averages before estimating fluxes. Results show that these formulations underestimate the average surface fluxes over a region for most of the nights.     

Evolution of Meteorological Conditions during a Heavy Air Pollution Event under the Influence of Shallow Foehn in Urumqi,China

The air pollution in Urumqi which is located on the northern slope of the Tianshan Mountains in northwestern China,is very serious in winter. Of particular importance is the influence of terrain-induced shallow foehn, known locally as elevated southeasterly gale(ESEG). It usually modulates atmospheric boundary layer structure and wind field patterns and produces favorable meteorological conditions conducive to hazardous air pollution. During 2013–17, Urumqi had an average of 50 d yr^–1...     

Extreme subsidence in the Agulhas-Benguela air mass transition

Analysis of three-dimensional wind profiles recorded by an acoustic sounder near Cape Town has indicated that extreme subsidence (-35 cm s^-1) is a mean feature throughout the atmospheric boundary layer (50–1000m) during summertime southerly winds. Over the SW Cape coast, the atmospheric subsidence translates into a N-S gradient of the mean summer water deficit (-20 to -32 cm month^-1). The rapid drying out of the air mass along a northward trajectory is linked to a number of factors including synoptic-scale divergence of the surface wind and the effects of the local orography which produce a hydraulic jump of the southerly wind. The along-coast reduction in sea surface temperature provides a major constraint on the height of the moist marine layer. As the depth of the marine air mass shrinks, its potential for inland penetration becomes limited. In addition, dry air is entrained towards the surface as evidenced by aerial survey data. A model is formulated which indicates the importance of the surface heat fluxes in reducing the depth of the Agulhas air mass as it passes northward over the SW tip of Africa during summer.     

边界层对流对示踪物抬升和传输影响的大涡模拟研究

利用"西北干旱区陆气相互作用野外观测实验"加密观测期间敦煌站的实测资料以及大涡模式, 通过一系列改变地表热通量和风切变的敏感性数值试验, 分析了地表热通量和风切变对边界层对流的强度、形式, 以及对对流边界层结构和发展的影响。模拟结果显示风切变一定, 增大地表热通量时, 由于近地层湍流运动增强, 向上输送的热量也较多, 使对流边界层变暖增厚, 而且边界层对流的强度明显增强, 对流泡发展的高度也较高。当地表热通量一定, 增大风切变时, 由于风切变使夹卷作用增强, 将逆温层中的暖空气向下卷入混合层中, 使对流边界层增暖增厚, 但是对流泡容易破碎, 对流的强度也较弱。另外通过在模式近地层释放绝对浓度为100的被动示踪物方法, 用最小二乘法定量地分析了地表热通量和风切变分别与示踪物抬升效率和传输高度的关系。分析结果表明, 风切变小于10.5×10-3 s-1时, 增大地表热通量加强了上层动量的下传, 使示踪物的抬升效率也线性增大;地表热通量小于462.5 W m-2时, 增大风切变减弱了边界层对流的强度, 从而使示踪物的抬升效率减弱。当风切变一定时, 示踪物的平均传输高度随地表热通量增加而增大, 而地表热通量一定, 只有风切变大于临界值时, 示踪物平均传输高度才随风切变的增加而增大, 而临界风速的大小由地表热通量决定。     

On the Formation of an Elevated Nocturnal Inversion Layer in the Presence of a Low-Level Jet: A Case Study

We report on observed nocturnal profiles, in which an inversion layer is located at the core of a low-level jet, bounded between two well-mixed layers. High-resolution vertical profiles were collected during a field campaign in a small plain in the Israeli desert (Negev), distant 100 km from the eastern shore of the Mediterranean Sea. During the evening hours, the synoptic flow, superposed on the late sea breeze, forms a low-level jet characterized by a maximum wind speed of 12 m s ⁻¹ at an altitude of 150 m above the ground. The strong wind shear at the jet maximum generates downward heat fluxes that act against the nocturnal ground cooling. As a result, the typical ground-based nocturnal inversion is “elevated” towards the jet centre, hence a typical early morning thermal profile is observed a few hours after sunset. Since the jet is advected into the region, its formation does not depend on the presence of a surface nocturnal inversion layer to decouple the jet from surface friction. On the contrary, here the advected low-level jet acts to hinder the formation of such an inversion. These unusual temperature and wind profiles are expected to affect near-ground dispersion processes.     

Wind regime in the lower atmosphere over Moscow from the long-term acoustic sounding data

Presented are the results of the sounding of the lower atmospheric 500-meter layer for the period of 2004–2012 carried out at the Meteorological Observatory of the Moscow State University (MSU) with the MODOS Doppler acoustic radar (sodar) produced by METEK (Germany). Discussed is the methodological basis of the sodar wind data analysis. It is demonstrated that in the air layer up to 200 m the maximum values in the annual course of the wind speed are observed more often in autumn and winter, and the minimum values, in summer; this is associated with the fact that during the cold period of the year Moscow is often located in the zones of intense gradient currents. The diurnal course of the wind speed is characterized by the daytime maximum and night-time minimum in the layer up to 40–60 m from the surface; it is poorly pronounced and characterized by the minimum in the morning in the layer of 80–120 m; and the daytime minimum and night-time maximum are observed above 140–160 m. The layer from 80 to 120 m approximately corresponds to the height of the wind rotation. The amplitude of diurnal variations of the wind speed increases from 0.3 m/s at the height of 7 m and 0.6 m/s at the height of 15 m, to 4.5 m/s at the height of 400 m; however, its secondary minimum (0.5 m/s) associated with the rotation height is registered at the altitude of 80 m. The statistical relationship between the wind speed and surface air temperature is direct during the cold season, inverse during the warm season, and is absent in April and October. The average maximum wind speed over Moscow for ten minutes in the layer up to 500 m from the surface reaches 30–35 m/s in some cases if two conditions concur: the capital is located on the periphery of vast pressure formations (usually of deep cyclones) and the local low-level jet stream is present in the wind profile.