1917号台风“塔巴”对浙江沿海风场的影响及其成因分析

通过分析浙江省区域自动站加密资料、常规观测资料、NCEP/NCAR 1°×1°和0.25°×0.25°再分析资料以及卫星TBB (Black Body Temperature)资料,研究2019年第17号台风"塔巴"影响期间,浙江沿海风场分布的特点及其成因,以寻找台风影响时浙江沿海风场预报的着眼点。此次台风大风具有影响时间早、持续时间长、影响范围大和大风强度强的特点。台风环流与浙江沿海地面弱冷空气之间形成一定气压梯度的堆积,以及后续随着台风环流的发展加强,两者之间气压梯度进一步增大,是导致此次台风大风提早出现的原因之一。垂直环流有利于水平的动量输送和高层动量下传,导致此次台风大风范围大、强度强。冷空气在这次台风大风中起到非常重要的作用。随着台风外围环流与冷空气距离拉近,部分干冷空气侵入台风环流,冷、暖气团之间θse等值线密集,环流附近风速增强。由于干冷空气的继续侵入,冷、暖空气相互作用累积并释放斜压能。同时台风低层的暖心结构被冷空气占据,高层暖心结构上抬,形成上暖下冷的中心结构,导致台风开始变性减弱。地形的辐合、阻挡和摩擦作用对风场的再分布也有一定影响。     

In situ measurements of wind‐driven salt fluxes through constructed channels in a coastal wetland ecosystem

A suite of instruments was deployed in a coastal wetland ecosystem in the Albemarle estuarine system, North Carolina (USA), to characterize wind‐driven transport of saltwater through a constructed (man‐made) channel. Flow velocity, electrical conductivity, and stage were measured in a representative channel over a 2‐month period from May to July 2014, during which 4 wind tides were observed. Collected data show that thousands of metric tons of salt were advected through the channel into coastal wetlands during each event, which lasted up to 4 days. The results reveal that as much as 36% of advected salts accumulated in the wetlands, suggesting that the cumulative effects of these events on the health of coastal wetlands in the Albemarle system may be substantial due to the abundance of constructed channels and the frequency of wind‐driven tidal events. This study is the first to quantify wind‐driven salt fluxes through constructed channels in coastal wetland settings.     

An experimental investigation of the effects of thawed soil depth on rill flow velocity

Water flow velocity is an important hydraulic variable in hydrological and soil erosion models, and is greatly affected by freezing and thawing of the surface soil layer in cold high-altitude regions. The accurate measurement of rill flow velocity when impacted by the thawing process is critical to simulate runoff and sediment transport processes. In this study, an electrolyte tracer modelling method was used to measure rill flow velocity along a meadow soil slope at different thaw depths under simulated rainfall. Rill flow velocity was measured using four thawed soil depths (0, 1, 2 and 10 cm), four slope gradients (5°, 10°, 15° and 20°) and four rainfall intensities (30, 60, 90 and 120 mm·h⁻¹). The results showed that the increase in thawed soil depth caused a decrease in rill flow velocity, whereby the rate of this decrease was also diminishing. Whilst the rill flow velocity was positively correlated with slope gradient and rainfall intensity, the response of rill flow velocity to these influencing factors varied with thawed soil depth. The mechanism by which thawed soil depth influenced rill flow velocity was attributed to the consumption of runoff energy, slope surface roughness, and the headcut effect. Rill flow velocity was modelled by thawed soil depth, slope gradient and rainfall intensity using an empirical function. This function predicted values that were in good agreement with the measured data. These results provide the foundation for a better understanding of the effect of thawed soil depth on slope hydrology, erosion and the parameterization scheme for hydrological and soil erosion models.     

Rill flow resistance law under equilibrium bed‐load transport conditions

In this paper, a recently deduced flow resistance equation for open channel flow was tested under equilibrium bed‐load transport conditions in a rill. First, the flow resistance equation was deduced applying dimensional analysis and the incomplete self‐similarity condition for the flow velocity distribution. Then, the following steps were carried out for developing the analysis: (a) a relationship (Equation  13 ) between the Γ function of the velocity profile, the rill slope, and the Froude number was calibrated by the available measurements by Jiang et al.; (b) a relationship (Equation  17 ) between the Γ function, the rill slope, the Shields number, and the Froude number was calibrated by the same measurements; and (c) the Darcy–Weisbach friction factor values measured by Jiang et al. were compared with those calculated by the rill flow resistance equation with Γ estimated by Equations  13 and 17 . This last comparison demonstrated that the rill flow resistance equation, in which slope and Shields number, representative of sediment transport effects, are introduced, is characterized by the lowest values of the estimate errors.     

人居环境气候舒适度对城市创新的影响分析

以中国创新水平较高的91个地级及以上城市为研究对象,探讨人居环境气候舒适度对城市创新的影响程度。以城市发明专利申请数代表城市创新水平,采用温湿指数和风效指数的组合模型,参照相应的分级标准计算各城市年气候舒适期,分析城市人居环境气候舒适度与城市创新的关系。结果表明:气候舒适期每增加1%,发明专利申请数仅平均增加0.012%,相对于GDP、R&D人员全时当量、R&D经费等影响城市创新的关键因素,城市人居环境气候舒适度对城市创新有一定影响,但影响并不十分显著。因此,创新政策的着眼点在于关注城市创新投入、人力资本、经济规模等影响城市创新的关键因素。在此基础上,创新布局也应考虑人居环境气候舒适度因素。     

中国跨境风电项目的建设模式、梯度转移及减排潜力研究

作为“一带一路”倡议的样板工程和旗舰项目,中巴经济走廊中的风电项目建设已经初现规模。中国在巴基斯坦的工程建设中,风电优先项目涉及的项目金额约为6.47亿元,运营期累计发电量可以达到近180亿千瓦时,可累计减少二氧化碳排放13.90兆吨。伴随跨境风电项目的梯度转移,中国可再生能源项目落地并网取决于东道国的政策制度安排、建设运营模式、设备供应体系以及电价收购协议等。本研究有助于协助沿线国家完善能源政策制度、加快清洁电力发展、应对气候变化、落实碳减排承诺,为绿色“一带一路”建设中可再生能源项目的推广提供借鉴。     

郑州市市区风环境模拟研究

城市风环境是城市微气候研究的一个重要方向,对分析城市热岛效应、空气流通等具有重要意义。本文以郑州市市区为例,使用1971—2018年气象观测数据、2018年建筑分布数据（OSM）和2016年资源三号卫星数据作为数据源,通过运用气象学和GIS技术结合的方法,探究潜在通风廊道,科学量化城市形态对风环境的影响。研究首先借助WindNinja软件,对城市背景风环境进行模拟分析,该计算方法提高了风道定位的精度。然后利用卫星遥感数据制作了数字高程模型（DSM）,结合OSM计算下垫面地表粗糙度。进一步借助ArcGIS软件,利用最小成本路径法（LCP）确定城市潜在通风廊道的位置。结果表明：① 郑州市近年来平均风速缓慢下降,平均每10年下降0.26 m/s;全年主导风向东北风进入城市后受城市形态影响在京广铁路线附近以西逐渐转为东北偏东风,其中在京广快速路以东风速较高,在京广快速路以西风速较低;② 金水区西部、中原区、二七区以及管城区的地表粗糙度较高,通风环境较差;金水区东部和惠济区的地表粗糙度较低,通风环境较好;③根据盛行风向模拟的潜在通风廊道,其共同特点是趋向于低粗糙度的地区。     

DPM模型在塔克拉玛干沙漠地区的适用性研究

局限于仅有观测数据的情况下,利用模拟手段研究土壤风蚀引起的粉尘释放是非常必要的,有助于评估区域土壤风蚀及大气环境质量和气候效应。本文通过分析塔克拉玛干沙漠观测站不同高度层风速及计算平均摩阻风速,利用DPM模型计算粉尘释放通量,综合分析了摩阻风速与粉尘释放通量的相互关系。结果表明：1）不同观测日不同高度层的风速变化各不相同,2m高度层风速的变化范围是0.05～7.73 m·s-1,4m高度层风速的变化范围是0.09～7.19 m·s-1,10m高度层风速的变化范围是0.5～8.09 m·s-1。2）4月1日～4月30日各个观测日24小时内平均摩阻风速分别为0.423 m·s-1、0.344 m·s-1、0.271 m·s-1、0.343 m·s-1、0.161 m·s-1、0.315 m·s-1,其变化范围为0.16～0.42 m·s-1。3）DPM模型研究发现实测跃移通量约为模拟值的122%,模拟值与实测值相关性较好,R2为0.91。上述研究结果对定量评估区域乃至全疆的土壤风蚀对粉尘释放通量的影响具有重要意义。     

DPM模型在塔克拉玛干沙漠地区的适用性研究

局限于仅有观测数据的情况下,利用模拟手段研究土壤风蚀引起的粉尘释放是非常必要的,有助于评估区域土壤风蚀及大气环境质量和气候效应。本文通过分析塔克拉玛干沙漠观测站不同高度层风速及计算平均摩阻风速,利用DPM模型计算粉尘释放通量,综合分析了摩阻风速与粉尘释放通量的相互关系。结果表明：1）不同观测日不同高度层的风速变化各不相同,2m高度层风速的变化范围是0.05～7.73 m·s-1,4m高度层风速的变化范围是0.09～7.19 m·s-1,10m高度层风速的变化范围是0.5～8.09 m·s-1。2）4月1日～4月30日各个观测日24小时内平均摩阻风速分别为0.423 m·s-1、0.344 m·s-1、0.271 m·s-1、0.343 m·s-1、0.161 m·s-1、0.315 m·s-1,其变化范围为0.16～0.42 m·s-1。3）DPM模型研究发现实测跃移通量约为模拟值的122%,模拟值与实测值相关性较好,R2为0.91。上述研究结果对定量评估区域乃至全疆的土壤风蚀对粉尘释放通量的影响具有重要意义。     

珠江三角洲地区大气CO2浓度特征及地面风的作用

利用光腔衰荡光谱(CRDS)技术在线观测了广州番禺大气成分站(GPACS)的大气CO₂浓度特征,分析了地面风对CO₂的作用。结果表明：(1)大气CO₂在珠江三角洲地区存在明显的地域不均匀特征,2014—2016年期间GPACS的年均本底浓度比全球背景地区平均增加了22.5×10^-6(22.5 ppm);(2)大气CO₂浓度在春季最高,冬、秋季次之,夏季最低,年均值为426.64±15.76 ppm;(3) CO₂的日变化为双峰结构,峰值分别在05:00—07:00和21:00—22:00,谷值在13:00—15:00,表明受到了自然过程以及人为排放源的复合影响;(4)风场显著影响CO₂的浓度分布,春、夏季CO₂浓度距平日变化与地面风速为显著负相关,秋、冬季则为显著正相关。在春、夏季,S-WSW和NNE-N风向上CO₂浓度较低,在秋、冬季,SSE-S和N方向均导致CO₂浓...