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1.
黄山地区春夏季气溶胶离子组分及其对云微物理特征的影响 总被引:1,自引:1,他引:0
利用2009年5-8月在华东地区高山——黄山顶取得的气溶胶和云微物理参数观测资料以及同期气溶胶离子成分数据,结合多种化学组分气溶胶绝热气块分档云模式,研究了黄山地区多化学组分气溶胶对云凝结核和云微物理特征的影响.气团轨迹和气溶胶离子成分的分析结果表明,3种气团影响着黄山地区气溶胶的化学组分,即北方大陆气团气溶胶富含CaCO3,局地污染气团气溶胶以可水溶性无机盐((NH4)2SO4、NH4 NO3)为主,而变性混合海洋性气团气溶胶中NaCl较多.数值模拟结果显示,在气溶胶谱一定时,不同天气形势下黄山气溶胶的化学组分的差异会对云微物理特征产生不同的影响.同一上升速度下实际多组分气溶胶模拟的云滴数浓度大于纯硫酸铵,主要体现在云滴谱第1个峰值3.3 μm之前;气块上升速度低于0.7 m/s时,含有较多不可水溶物质的混合气溶胶对云滴数浓度的影响较大;上升速度大于0.7 m/s时,气块中可凝结水增多,海盐对云滴数浓度增加的效果更显著.多组分气溶胶模拟云滴谱较纯硫酸铵窄,其中,北方气团方案造成云滴谱变窄的程度高于混合气团方案;而模拟的云滴数目增多,造成云滴有效半径减小,云光学厚度和反照率增加,将会对暖云降水及辐射效应产生不同的影响. 相似文献
2.
南京冬季持续性强浓雾天气中三级分档雾水的理化特性分析 总被引:1,自引:0,他引:1
2013年12月7—9日南京出现持续性强浓雾天气过程。利用观测试验中获取的三级分档雾水和分粒径气溶胶的水溶性离子浓度,气溶胶数浓度谱、雾滴谱以及自动气象站获取的气象要素等资料,通过对比研究浓雾过程中4—16 μm(3级)、16—22 μm(2级)、>22 μm(1级)3个粒径范围雾滴(雾水)与分粒径气溶胶的微物理特征和化学特性,探讨不同粒径气溶胶粒子吸湿增长对雾滴的贡献以及气溶胶离子组分对不同尺度雾滴化学性质的影响。结果表明,在强浓雾天气中,能见度为50 m左右,短波辐射减弱形成稳定逆温层,有助于污染气溶胶的累积并吸湿增长向雾滴转化。雾滴的增加主要集中在小滴范围, 直径在0.5—1 μm的气溶胶粒子对其贡献最大。各粒径段气溶胶中阴离子NO3-和SO42-均表现出较高值,阳离子中Ca2+浓度最高。三档雾水中各阴、阳离子浓度均在4—16 μm小滴雾水中最高,16—22 μm中滴雾水和>22 μm大滴雾水的阴、阳离子浓度没有明显的高低之分。阳离子中Ca2+的浓度在第1级小滴雾水中最高,2级和3级雾水中NH4+的浓度最高,阴离子中NO3-和SO42-在各级雾水中浓度相差不大。雾水pH值2.7—6.9,呈酸性,小雾滴酸性更强。 相似文献
3.
探究不同尺度雾滴化学特征是深化雾微物理化学研究的重要内容。2016年12月—2017年1月在庐山开展雾综合观测实验,利用主动式三级分档雾水采集器(CASCC 3_stage)收集到3次雾过程73个分档雾水样本,雾滴分档粒径:4—16 μm(3级),16—22 μm(2级)和≥22 μm(1级)。定量得到了分档雾水的pH、电导率(EC)及9种水溶性无机离子(Na+、NH4+、K+、Mg2+、Ca2+、Cl-、NO2-、NO3-、SO42-)浓度(μeq/L)。结果表明,庐山冬季雾水酸化严重,pH为3.96—5.82,pH < 5.6的样品占98.6%且直径4—16 μm小雾滴的强酸性(pH < 4.5)样品最多,占比达54.2%,小雾滴酸性和电导率更强;NH4+、Ca2+、NO3-、SO42-是雾水的主要离子组分,[NH4++Ca2++NO3-+SO42-]分别在三级分档雾水中占总离子浓度(TIC)的83.8%、88.0%和88.7%;综合3次雾过程,总离子浓度、NH4+、K+、NO3-、SO42-在4—16 μm小雾滴存在富集,表现出尺度依赖特征;86%雾水样品[SO42-]/[NO3-]介于0.5—3.0,属于硫酸和硝酸混合型酸化,雾水酸化主要原因是碱性缓冲物质与酸性组分不平衡以及可能存在有机酸贡献;同一观测点不同雾过程化学特征存在个例差异,第二次雾过程(12月25日14时—26日21时)(北京时),总离子浓度、NH4+、Ca2+、NO3-、SO42-在16—22 μm尺度雾滴存在富集,这可能是雾区气溶胶浓度较低、降温、采样间隔和污染气体及气溶胶输送共同作用的结果。后向轨迹聚类和潜在源(PSCF)分析表明,观测期间影响庐山的气团均来自西部,来自湖南北部的局地气团占总轨迹数的68.99%,最为重要;PM2.5、SO2、NO2具有相似潜在源区空间分布,主要位于湖北、湖南、安徽西南部和江西北部等邻近省份地区,以近距离输送为主。 相似文献
4.
利用2014年7月黄山光明顶观测获得的气溶胶数浓度、气溶胶数谱数据,对黄山夏季气溶胶数浓度及谱分布特征进行分析,并在此基础上对气溶胶数谱进行了对数正态分布拟合。研究结果表明:黄山夏季气溶胶平均数浓度约为3 518.27 cm~(-3),主要集中在爱根核模态;气溶胶平均数浓度日变化呈双峰分布,峰值浓度的出现伴随着小粒子的增多。气溶胶数浓度与相对湿度和风速成负相关,高浓度的气溶胶多出现在较弱的东南风时;积聚模态气溶胶数浓度受风向影响显著。不同气团背景下气溶胶数谱差异集中在小于100 nm和500~1 000 nm粒径范围。爱根核模态气溶胶在高湿的西南气团影响下数浓度最低、谱较窄,而高温、低湿的东南气团对应的气溶胶数浓度最高、谱最宽,北方气团对应的气溶胶数浓度和谱宽居中;500~1 000 nm粒径范围气溶胶数谱分布特征与之相反。不同背景的气溶胶数谱和体积谱均可采用爱根模态、积聚模态1和积聚模态2三个模态进行对数正态分布拟合,但不同气团背景下的各模态谱型参数差异较大。 相似文献
5.
南京地区冬季大气冰核特征及其与气溶胶关系的研究 总被引:6,自引:1,他引:5
2011年11月15日~12月2日期间对南京地区近地面大气气溶胶和冰核进行了同步观测,综合分析了 冰核浓度的特征及其与气溶胶粒子浓度的关系。结果表明:活化温度Ta为-20℃,水面过饱和度为1%时,南京地区冰核浓度NIN为0.352 L-1,与0.01~10 μm气溶胶数浓度比值仅为4×10-8。冰核活化温度越低,湿度越大,冰核浓度越高。雾和降雨对冰核都有明显的清除作用。对比不同气团对南京地区冰核的影响发现,偏东方向的污染气团中冰核以及气溶胶的浓度最高,但是来自西北地区的气团中冰核占气溶胶的比例最高,这可能是由于冰相核化能力较强的沙尘气溶胶导致的。分析冰核与不同粒径段气溶胶的相关性发现,较大粒径气溶胶的表面积浓度与冰核相关性更高,本文也得到了由活化温度Ta和粒径大于0.5 μm气溶胶数浓度N0.5~10 μm共同计算冰核浓度的经验公式。 相似文献
6.
为了对黄山地区云凝结核(Cloud Condensation Nuclei,CCN)进行闭合研究,2014年6月30日至7月28日在黄山光明顶对大气气溶胶理化性质和CCN数浓度进行观测,分析了气溶胶化学组分、谱分布以及CCN数浓度随时间变化的特征,通过κ-Köhler理论并使用离子配对法计算得到CCN数浓度与观测得到的CCN数浓度进行对比。结果表明:计算与观测的CCN闭合结果较好,低过饱和度CCN闭合结果好于高过饱和度,过饱和度较低时低估了CCN数浓度,而过饱和度较高时则高估了CCN数浓度,由此说明气溶胶的化学组分数据对预测CCN数浓度至关重要,同时说明该方法可以实现CCN的闭合。考虑到40%水溶性有机碳(Water Soluble Organic Carbon,WSOC)对气溶胶粒子吸湿性影响,在较低过饱和度CCN闭合结果较好,但影响效果并不显著,尤其是在拟合结果相对较差的高过饱和度下基本没有影响。因此,气溶胶粒子中水溶性无机组分对CCN活化有重要影响,而含量较多、化学组分复杂并且吸湿性不确定的WSOC对CCN活化影响较为有限,这与一些研究得出无机组分对于气溶胶吸湿性的影响比具有复杂特征的有机组分更重要的结论相符合。 相似文献
7.
应用多种化学组分气溶胶的绝热气块分档模式,对2008年春季黄山地区气溶胶吸湿增长特性进行了模拟分析.结果表明:黄山地区气溶胶吸湿增长因子f的大小与粒子半径、相对湿度、粒子化学组分、上升速度及上升高度密切相关,且小粒子吸湿增长比大粒子显著.吸湿增长因子与相对湿度呈正相关,相对湿度越接近粒子的临界饱和比,吸湿增长因子变化越显著.可溶性有机气溶胶,通过增加溶液中溶质的百分比来影响临界饱和比,使吸湿增长因子增大.若不考虑不可溶粒子的成核作用,会高估粒子的吸湿性.随着上升速度增大,吸湿增长因子降低,降低程度与粒子初始高度的相对湿度有关.上升高度通过改变气块相对湿度的变化来影响气溶胶吸湿增长因子. 相似文献
8.
2016年11月13日在北京地区上空存在持续稳定的层状云天气背景下,利用飞机开展气溶胶粒径谱、化学组成、云滴谱等参量的垂直观测,研究该个例云底气溶胶的活化能力。结果表明:探测期间北京地区为轻度污染天气,地面气溶胶浓度(0.11~3 μm)达到4600 cm-3。云层高度为800~1200 m,云底气溶胶数浓度相对于近地面大幅度降低,有效粒径显著增大(0.3~0.6 μm)。同时,近地面气溶胶中疏水性的一次有机气溶胶贡献显著,而云底气溶胶中一次有机气溶胶的贡献大幅降低,无机组分和二次有机气溶胶的贡献明显增大,造成吸湿性参数κ由0.25(地面)增大至0.32(云底)。云中气溶胶和云滴的谱分布衔接较好,且两者的数浓度之和与云底气溶胶浓度一致,可分别代表未活化和已活化的粒子。基于云底气溶胶粒径谱和吸湿性参数计算得到不同过饱和比下云凝结核的活化率,通过与云中观测结果对比,反推得到云底过饱和度约为0.048%。 相似文献
9.
天津大气气溶胶化学组分的粒径分布和垂直分布 总被引:7,自引:1,他引:6
2006年8月在天津气象铁塔的10、120、220 m 3个不同高度.利用Andersen分级采样器同步进行大气气溶胶采样,样品用离子色谱和电感耦合等离子体质谱仪进行分析.结果表明,K元素主要集中在细粒子,Mg、Ca、Al、Fe元素主要集中在粗粒子,Na元素则具有双峰结构;总离子浓度随着高度的升高有增加的趋势,SO42-、N3-、NH4+、Ca2+是最主要的水溶性尤机离子;二次源是水溶性离子重要的贡献源.NO3-、SO42-、NH4+随着高度升高,浓度有向小粒径集中的趋势;各层气溶胶阴阳离子平衡值小于1,表明气溶胶偏碱性,与天津地处北方,土壤偏碱性,且非采暖期地面扬尘是主要的气溶胶来源有关;各层NO3-/SO42-平均值为0.48,表明非采暖期固定排放源(燃煤)仍然是天津大气细粒子中水溶性离子的主要来源. 相似文献
10.
2003年夏季临安地区大气气溶胶离子成分的尺度分布特征 总被引:16,自引:0,他引:16
文中利用2003年夏季在浙江临安大气本底污染监测站观测的资料,分析了临安的气溶胶质量浓度、离子成分的尺度分布特点及主要离子间的相互关系。初步结果显示,该期间临安气溶胶主要以粒径小于2.1μm的细粒子为主,约占总质量浓度的66%,其中粒径小于0.65μm的粒子可达总质量浓度的50%,远高于其他各级尺度段上的粒子浓度。与质量浓度分布相似,可溶性无机离子成分主要集中在粒径小于2.1μm(记为PM2.1)的细粒子中,PM2.1粒子中可溶性无机离子约占所有尺度段(包括所有5级)离子质量浓度总和的88%。其中粒径小于0.65μm的亚微米粒子中的离子质量浓度是细粒子的主要部分,占所有尺度段上离子质量浓度总和的77%。SO42-,NH4+和K+是PM2.1中决定性的离子成分。相关分析和离子平衡表明,PM2.1中SO42-与NH4+和K+有很高的相关,在粒径小于0.65μm的亚微米粒子中,非海盐硫酸盐(Nss-SO42-)主要为(NH4)2SO4,由气-粒转化产生;而在粒径为0.65~2.1μm尺度段,Nss-SO42-除(NH4)2SO4外,可能还有K2SO4,Na2SO4等存在。 相似文献
11.
气溶胶粒子的吸湿增长对区域环境、气象与辐射收支都有巨大影响,精确的气溶胶吸湿特性观测对描述气溶胶吸湿增长特性,以及研究气溶胶对气候环境影响,拓展卫星气溶胶产品的应用有非常重要的意义。本研究提出一种基于常规气象观测(能见度、相对湿度)和空气质量观测(PM2.5浓度,即空气动力学当量直径小于等于2.5 μm的颗粒物浓度)相结合的气溶胶吸湿增长估算方法,在此基础上对浙江地区气溶胶吸湿特性的时空变化影响因素进行了探讨。研究发现,沿海的温州瓯海站的吸湿增长能力最高,长三角典型城市环境的杭州和睦小学站的吸湿增长能力次之,而地处较为洁净内陆的衢州实验学校站的吸湿增长能力最低。在时间变化中,同一站点不同湿度条件的吸湿增长变化趋势相同,温州瓯海站的吸湿性变化最为剧烈,杭州和睦小学站的吸湿性变化次之,衢州实验学校站变化较为平缓。本研究表明,浙江地区的气溶胶吸湿增长特性存在较大的时空差异,基于本方法能够在较大的时空范围内描述气溶胶的吸湿增长特性,为有限的精密观测提供重要补充。 相似文献
12.
A multifunctional HTDMA system with a robust temperature control 总被引:3,自引:0,他引:3
The hygroscopicity of atmospheric aerosols significantly influences their size distribution,
cloud condensation nuclei ability, atmospheric residence time, and climate forcing. In order to investigate
the hygroscopic behavior of aerosol particles and serious haze in China, a Hygroscopic Tandem Differential
Mobility Analyzers (HTDMA) system was designed and constructed at Fudan University. It can function as a
scanning mobility particle sizing system to measure particle size distribution in the range of 20--1000 nm
in diameter, as well as a hygroscopicity analyzer for aerosol particles with diameters between 20--400 nm
in the range of 20%--90% RH (relative humidity). It can also measure the effect of uptake of inorganic acids
or semi-VOCs on the hygroscopic behavior of aerosols, such as typical inorganic salts in atmospheric dust or
their mixtures. The performance tests show that the system measured particle size of the standard polystyrene
latex spheres (PSLs) is 197 nm, which is in excellent agreement with the certified diameter D=199±6 nm, as
well as a standard deviation of the repeated runs SD=8.9x10-4. In addition, the measured hygroscopic
growth factors of the model compounds, (NH4)2SO4 and NaNO3, agree with the Kohler theoretical
curves. The results indicate that the HTDMA system is an excellent and powerful tool for studying the
hygroscopic behavior of submicron aerosols and meets the demand required for laboratory research and
fieldwork on atmospheric aerosols in China. 相似文献
13.
Highly Biased Hygroscopicity Derived from Size-Resolved Cloud Condensation Nuclei Activation Ratios without Data Inversion 
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下载免费PDF全文 The impact of aerosols on the climate and atmospheric environment depends on the water uptake ability of particles; namely, hygroscopic growth and acti- vation into cloud condensation nuclei (CCN). The size-resolved activation ratios (SRAR), characterizing the fraction of aerosol particles that act as CCN at different particle sizes and supersaturations, can be measured using a combination of differential mobility analyzers (DMA) and particle counters. DMA-based measurements are in- fluenced by the multiply charged particles and the quasi-mono-dispersed particles (effect of DMA transfer function) selected for each prescribed particle size. A theoretical study, assuming different particle number size distributions and hygroscopicity of aerosols, is performed to study the effects of the DMA transfer function and multiple charging on the measured SRAR and the derived hygroscopicity. Results show that the raw SRAR can be significantly skewed and hygroscopicity may be highly biased from the true value if the data are not corrected. The effect of the transfer function is relatively small and depends on the sample to sheath flow ratio. Multiply charged particles, however, can lead to large biases of the SRAR. These results emphasize that the inversion algo- rithm, which is used to correct the effects of the DMA transfer function and multiple charging, is necessary for accurate measurement of the SRAR. 相似文献
14.
By N. KAADEN A. MASSLING A. SCHLADITZ T. MÜLLER K. KANDLER L. SCHÜTZ B. WEINZIERL A. PETZOLD M. TESCHE S. LEINERT C. DEUTSCHER M. EBERT S. WEINBRUCH A. WIEDENSOHLER 《Tellus. Series B, Chemical and physical meteorology》2009,61(1):51-63
The Saharan Mineral Dust Experiment (SAMUM) was conducted in May and June 2006 in Tinfou, Morocco. A H-TDMA system and a H-DMA-APS system were used to obtain hygroscopic properties of mineral dust particles at 85% RH. Dynamic shape factors of 1.11, 1.19 and 1.25 were determined for the volume equivalent diameters 720, 840 and 960 nm, respectively.
During a dust event, the hydrophobic number fraction of 250 and 350 nm particles increased significantly from 30 and 65% to 53 and 75%, respectively, indicating that mineral dust particles can be as small as 200 nm in diameter. Log-normal functions for mineral dust number size distributions were obtained from total particle number size distributions and fractions of hydrophobic particles. The geometric mean diameter for Saharan dust particles was 715 nm during the dust event and 570 nm for the Saharan background aerosol.
Measurements of hygroscopic growth showed that the Saharan aerosol consists of an anthropogenic fraction (predominantly non natural sulphate and carbonaceous particles) and of mineral dust particles. Hygroscopic growth and hysteresis curve measurements of the 'more' hygroscopic particle fraction indicated ammonium sulphate as a main component of the anthropogenic aerosol. Particles larger than 720 nm in diameter were completely hydrophobic meaning that mineral dust particles are not hygroscopic. 相似文献
During a dust event, the hydrophobic number fraction of 250 and 350 nm particles increased significantly from 30 and 65% to 53 and 75%, respectively, indicating that mineral dust particles can be as small as 200 nm in diameter. Log-normal functions for mineral dust number size distributions were obtained from total particle number size distributions and fractions of hydrophobic particles. The geometric mean diameter for Saharan dust particles was 715 nm during the dust event and 570 nm for the Saharan background aerosol.
Measurements of hygroscopic growth showed that the Saharan aerosol consists of an anthropogenic fraction (predominantly non natural sulphate and carbonaceous particles) and of mineral dust particles. Hygroscopic growth and hysteresis curve measurements of the 'more' hygroscopic particle fraction indicated ammonium sulphate as a main component of the anthropogenic aerosol. Particles larger than 720 nm in diameter were completely hydrophobic meaning that mineral dust particles are not hygroscopic. 相似文献
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Erik Swietlicki Jingchuan Zhou Olle H. Berg Bengt G. Martinsson Gran Frank Sven-Inge Cederfelt Ulrike Dusek Axel Berner Wolfram Birmili Alfred Wiedensohler Brett Yuskiewicz Keith N. Bower 《Atmospheric Research》1999,50(3-4)
The hygroscopic properties of sub-micrometer aerosol particles were studied in connection with a ground-based cloud experiment at Great Dun Fell, in northern England in 1995. Hygroscopic diameter growth factors were measured with a Tandem Differential Mobility Analyser (TDMA) for dry particle diameters between 35 and 265 nm at one of the sites upwind of the orographic cloud. An external mixture consisting of three groups of particles, each with different hygroscopic properties, was observed. These particle groups were denoted less-hygroscopic, more-hygroscopic and sea spray particles and had average diameter growth factors of 1.11–1.15, 1.38–1.69 and 2.08–2.21 respectively when taken from a dry state to a relative humidity of 90%. Average growth factors increased with dry particle size. A bimodal hygroscopic behaviour was observed for 74–87% of the cases depending on particle size. Parallel measurements of dry sub-micrometer particle number size distributions were performed with a Differential Mobility Particle Sizer (DMPS). The inorganic ion aerosol composition was determined by means of ion chromatography analysis of samples collected with Berner-type low pressure cascade impactors at ambient conditions. The number of ions collected on each impactor stage was predicted from the size distribution and hygroscopic growth data by means of a model of hygroscopic behaviour assuming that only the inorganic substances interacted with the ambient water vapour. The predicted ion number concentration was compared with the actual number of all positive and negative ions collected on the various impactor stages. For the impactor stage which collected particles with aerodynamic diameters between 0.17–0.53 μm at ambient relative humidity, and for which all pertinent data was available for the hygroscopic closure study, the predicted ion concentrations agreed with the measured values within the combined measurement and model uncertainties for all cases but one. For this impactor sampling occasion, the predicted ion concentration was significantly higher than the measured. The air mass in which this sample was taken had undergone extensive photochemical activity which had probably produced hygroscopically active material other than inorganic ions, such as organic oxygenated substances. 相似文献
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天空辐射计观测2006年春季北京地区气溶胶光学特性的研究 总被引:2,自引:0,他引:2
利用2006年3~5月天空辐射计观测数据反演得到北京地区春季大气气溶胶光学性质参数,包括大气气溶胶光学厚度(0.5μm)、Angstrm指数、单次散射反射比和粒子谱分布特征。结果表明:北京地区春季气溶胶平均光学厚度0.67,Angstrm指数0.54,单次散射比0.88,粒子吸收性质较弱,粒子谱呈双峰形,以粗粒子为主,粗、细模态粒子粒径分别集中在0.17μm和7.7μm左右。相比2004年此次观测期间气溶胶粒径较大,粒子体积浓度较高,散射作用在其消光特性中的比重略有下降。光学厚度日变化呈单峰型,日间单次散射比随时间逐渐递减,Angstrm指数在上午递减趋势明显,午后变得稳定。对同时观测的天空辐射计与CE-318不同波长光学厚度结果进行比较,结果显示两者得到的光学厚度相关性很好,各波长小时平均结果的相对误差小于7%。 相似文献
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Precipitation scavenging of aerosol particles is an important removal process in the atmosphere that can change aerosol physical and optical properties. This paper analyzes the changes in aerosol physical and optical properties before and after four rain events using in situ observations of mass concentration, number concentration, particle size distribution, scattering and absorption coefficients of aerosols in June and July 2013 at the Xianghe comprehensive atmospheric observation station in China. The results show the effect of rain scavenging is related to the rain intensity and duration, the wind speed and direction. During the rain events, the temporal variation of aerosol number concentration was consistent with the variation in mass concentration, but their size-resolved scavenging ratios were different. After the rain events, the increase in aerosol mass concentration began with an increase in particles with diameter 0.8 μm [measured using an aerodynamic particle sizer(APS)], and fine particles with diameter 0.1 μm [measured using a scanning mobility particle sizer(SMPS)]. Rainfall was most efficient at removing particles with diameter ~0.6 μm and greater than 3.5 μm. The changes in peak values of the particle number distribution(measured using the SMPS) before and after the rain events reflect the strong scavenging effect on particles within the 100–120 nm size range. The variation patterns of aerosol scattering and absorption coefficients before and after the rain events were similar, but their scavenging ratios differed, which may have been related to the aerosol particle size distribution and chemical composition. 相似文献