Avaliação da contribuição das fontes poluentes para a assinatura isotópica de Pb, Zn e Cu do aerossol atmosférico da cidade de São Paulo / not available

Souto-Oliveira, Carlos Eduardo

12 May 2017

As altas concentrações de aerossol fino e ultrafino observadas na atmosfera de áreas urbanas possuem um importante papel no clima local e global, devido sua interação com a radiação solar e também pela característica de formação dos núcleos de condensação de nuvens (CCN). Essas altas concentrações de partículas são responsáveis pela poluição do ar, atualmente considerada como o principal problema ambiental para a saúde pública no mundo, sendo relacionada ao câncer, doenças respiratórias, cardiovasculares e o mal de Alzheimer. Nesse contexto, o presente trabalho almejou a caracterização e discriminação de fontes poluentes para o aerossol atmosférico da cidade de São Paulo, utilizando os isótopos de Pb, Zn e Cu simultaneamente. Além disso, nesse estudo também foi realizada a avaliação do efeito das fontes locais e remotas para a ativação do CCN na atmosfera dessa região. São Paulo é a maior cidade da Região Metropolitana de São Paulo (RMSP), que por sua vez é a maior megacidade da América do Sul, e está entre as dez maiores do mundo. Amostras de aerossol urbano foram coletadas no inverno de 2013 e verão de 2014 na cidade de São Paulo. Ao mesmo tempo foram coletadas, em São Paulo e Cubatão, amostras de fontes poluentes importantes para a RMSP, como aquelas relacionadas ao tráfego veicular (combustíveis, pneu, poeira de rua e aerossol de túnel), construção civil (cimento) e à área industrial de Cubatão (aerossol). Adicionalmente, foram medidas no inverno de 2014 a concentrações de CCN, a distribuição por tamanho e a concentração em número das partículas. As determinações das composições isotópicas de Pb, Zn e Cu foram realizadas com um novo procedimento analítico, desenvolvido para a separação sequencial e purificação desses elementos, a partir de uma mesma solubilização de amostra, seguida pelas análises por espectrometria de massas empregando MC-ICP-MS e TIMS. A validação da exatidão e precisão desse procedimento foi realizada pela análise de amostras de materiais de referência, aerossol e fontes poluentes. Com base nos dados isotópicos das fontes poluentes, o tráfego veicular foi diferenciado da área industrial de Cubatão utilizando as assinaturas isotópicas de Pb dessas fontes, que demonstraram grande reprodutibilidade quando comparadas com estudos anteriores. Adicionalmente, as assinaturas isotópicas da poeira de rua e dos pneus foram discriminadas das emissões veiculares em um diagrama \'delta\'66ZnJMC vs 206Pb/207Pb. As assinaturas isotópicas de Zn e Cu da poeira de rua, emissões veiculares e cimento foram discriminadas em um diagrama \'delta\'65CuNIST vs \'delta\'66ZnJMC. As contribuições das fontes para as composições isotópicas de Pb e Zn, determinadas no aerossol da cidade de São Paulo, foram quantificadas utilizando modelos de mistura ternária. Nesses modelos o tráfego veicular (57 a 66%) foi predominante, seguido pela fonte não-caracterizada (25 a 32%), que mostrou uma assinatura isotópica de Pb e Zn específica observada nas duas campanhas. A área industrial de Cubatão apresentou contribuições de 11 a 17%, enquanto a poeira de rua contribuiu em até 18% para as assinaturas de Pb e Zn no aerossol. No inverno de 2014, o tráfego veicular local, o sal marinho e a queima de biomassa foram identificadas nas amostras de aerossol por análises de PMF, trajetórias de massas de ar e pelo sistema lidar. Também foram observados eventos de formação de aerossol secundário em 35% dos dias de medição. A ativação de CCN foi menor durante o dia em relação ao período noturno, sendo esse padrão associado principalmente as emissões do tráfego veicular local. Comparando os dias com contribuições das fontes remotas, pôde-se concluir que o material particulado proveniente do tráfego veicular durante o dia mostrou o maior efeito nos parâmetros de ativação de CCN em comparação com as fontes remotas de sal marinho e queima de biomassa. / Fine and ultrafine aerosol particles in high concentrations found in the atmosphere of urban areas, play an important role in local and global climate through interaction with solar radiation and cloud condensation nuclei (CCN) formation. These high concentrations of particles are related to the air pollution, which is the major environmental problem to the public health in the world, related with cancer, cardiovascular, respiratory and Alzheimer diseases. In this context, this study reports the simultaneous use of Pb, Zn and Cu to characterize and discriminate pollutant sources of the atmospheric aerosol from São Paulo City and evaluate the effect of local and remote sources to CCN activation in the atmosphere of this area. São Paulo is the main city of Metropolitan Area of São Paulo (MASP), which is the largest megacity in South America and rank among the ten most populous in the world. Urban aerosol samples were collected during winter of 2013 and summer of 2014 in the São Paulo city. At the same time, samples of the main pollutant sources of MASP, were sampled in São Paulo and Cubatão, such as vehicular traffic (fuels, tyres, road dust and tunnel aerosol), construction (cement) and aerosol from Cubatão industrial area. In addition, CCN concentrations, particle number concentrations and size distributions were measured during the winter of 2014 in the same sampling site. The Pb, Zn and Cu isotopic composition were determined by a new analytical procedure, developed to sequential separation of these elements, using a unique sample dissolution, followed by mass spectrometry analysis by MC-ICP-MS and TIMS. Analytical procedure validation of Accuracy and precision was carried with reference materials, aerosol and pollutant source samples. Based on isotopic data obtained on the pollutant sources, vehicular traffic was differentiated from Cubatão industrial area, using Pb isotopic fingerprints of this sources, which showed long term reproducibility when compared with previous studies. In addition, road dust and tyre isotopic signatures were discriminated from vehicular emissions in a \'delta\'66ZnJMC vs 206Pb/207Pb four isotope plot. Interestingly, Zn and Cu isotopic fingerprints of road dust, vehicular emission and cement was distinguished in a \'delta\'65CuNIST vs \'delta\'66ZnJMC four isotope plot. In order to quantify contributions of sources to Pb and Zn isotopic compositions determined in aerosol from São Paulo city, ternary mixing models were performed. In these models, vehicular traffic accounted to the main contribution (57 to 66%), followed by non-characterized source (25 to 32%), with a specific Pb and Zn isotopic signature identified in aerosol during the two campaigns. Cubatão industrial area showed contributions of 11 to 17%, whereas road dust contributed 18% to Pb and Zn isotopes in aerosol. In the winter of 2014, local vehicular traffic, sea salt and biomass burning were identified in aerosol by PMF, air masses trajectories and lidar analysis. Some new particle formation (NPF) events were identified on 35% of the sampling days. CCN activation was lower during the daytime compared to nightime periods, a pattern that was found to be associated mainly with local road-traffic emissions. Comparing the days with remote sources events, we concluded that particulate matter from local vehicular emissions during the daytime have a greater effect on CCN activation parameters than that from sea salt and biomass burning remote sources.

Aerossol secundário

Aerossol urbano

Air pollution

Cloud Condensation Nuclei.

Cu

Fontes poluentes

isótopos Pb

Megacidades

Megacities

Núcleos de condensação de nuvens

Pb

Pollutant sources

Poluição do ar

Urban aerosol

Zn e Cu

Zn isotopes

Quantifying compositional impacts of ambient aerosol on cloud formation

Lance, Sara

14 November 2007

It has been historically assumed that most of the uncertainty associated with the aerosol indirect effect on climate can be attributed to the unpredictability of updrafts. We assess the sensitivity of cloud droplet number density to realistic variations in aerosol chemical properties and to variable updraft velocities using a 1-dimensional cloud parcel model. The results suggest that aerosol chemical variability may be as important to the aerosol indirect effect as the effect of unresolved cloud dynamics, especially in polluted environments. We next used a continuous flow streamwise thermal gradient Cloud Condesnation Nuclei counter (CCNc) to study the water-uptake properties of the ambient aerosol, by exposing an aerosol sample to a controlled water vapor supersaturation and counting the resulting number of droplets. The heat transfer properties and droplet growth within the CCNc were first modeled and experimentally characterized. We describe results from the MIRAGE field campaign at a ground-based site during March, 2006. Size-resolved CCN activation spectra and hygroscopic growth factor distributions of the ambient aerosol in Mexico City were obtained, and an analytical technique was developed to quantify a probability distribution of solute volume fractions for the CCN, as well as the aerosol mixing-state. The CCN were shown to be much less CCN active than ammonium sulfate, with water uptake properties more consistent with low molecular weight organic compounds. We also describe results from the GoMACCS field study, an airborne field campaign in Houston, Texas during August-September, 2006. GoMACCS tested our ability to predict CCN for highly polluted conditions with limited chemical information. Assuming the particles were composed purely of ammonium sulfate, CCN closure was obtained with a 10% overprediction bias on average for CCN concentrations ranging from less than 100 cm-3 to over 10,000 cm-3, but with on average 50% variability. Assuming measured concentrations of organics to be internally mixed and insoluble tended to reduce the overprediction bias for less polluted conditions, but led to underprediction bias in the most polluted conditions. Comparing the two campaigns, it is clear that the chemistry of the particles plays an important role in our ability to predict CCN concentrations.

Tandem differential mobility analyzer

Hygroscopicity

HTDMA

Scaled volume fraction

Solute volume fraction

DMT

MIRAGE

GOMACCS

Houston

Mexico City

Pollution

Aerosol

CCN

CCN closure

Cloud condensation nuclei

Clouds

Droplets

Volume fraction

Aerosols

Cloud physics

Hydrologic cycle

東シナ海近辺上におげる雲粒核の特性観測とその役割に関する研究

石坂, 隆

03 1900

科学研究費補助金 研究種目:基盤研究(C) 課題番号:17510006 研究代表者:石坂 隆 研究期間:2005-2006年度

MODIS

air pollutant

cloud condensation nuclei

cloud droplet

cloud physics

microstructure of lower clouds

satellite MODIS

下層雲

下層雲の微細構造

人工衛星MODIS

大気汚染物質

東シナ海

雲の光学的性質

雲の微物理学的性質

雲物理

雲粒

雲粒の光学的有効半径

雲粒核

黄砂