2008
Assessing meteorological parameters on the performance of PUF disks passive air samplers for POPs.
KLÁNOVÁ, Jana, Pavel ČUPR, Jiří KOHOUTEK a Tom HARNERZákladní údaje
Originální název
Assessing meteorological parameters on the performance of PUF disks passive air samplers for POPs.
Název česky
Studium vlivu meteorologických parametrů na aplikaci pasivních vzorkovačů POP v ovzduší
Autoři
KLÁNOVÁ, Jana (203 Česká republika, garant), Pavel ČUPR (203 Česká republika), Jiří KOHOUTEK (203 Česká republika) a Tom HARNER (124 Kanada)
Vydání
Environmental Science and Technology, Columbus, Ohio, USA, American Chemical Society, 2008, 0013-936X
Další údaje
Jazyk
angličtina
Typ výsledku
Článek v odborném periodiku
Obor
10511 Environmental sciences
Stát vydavatele
Spojené státy
Utajení
není předmětem státního či obchodního tajemství
Impakt faktor
Impact factor: 4.458
Kód RIV
RIV/00216224:14310/08:00025729
Organizační jednotka
Přírodovědecká fakulta
UT WoS
000252317700040
Klíčová slova anglicky
Passive air sampling; Polyurethane foam; PUF disk; Wind speed; Temperature; Meteorology; POPs
Štítky
Příznaky
Mezinárodní význam, Recenzováno
Změněno: 25. 6. 2009 12:51, prof. RNDr. Luděk Bláha, Ph.D.
V originále
PUF disk passive air samplers were evaluated under field conditions to assess the effect of temperature and windspeed on sampling rate for polycyclic aromatic hydrocarbons (PAHs), polychlorinated biphenyls (PCBs) and organochlorine pesticides (OCPs). Passive samples integrated over 28-day periods were compared to high volume air samples collected for 24-h, every 7 days. This provided a large data set of 42 passive sampling events and 168 high volume samples over a 3-year period, starting in October 2003. Average PUF disk sampling rates for gas-phase chemicals was ~7 m3d-1 and comparable to previous reports. The high molecular weight PAHs, that are mainly particle-bound, experienced much lower sampling rates of ~0.7m3d-1. This small rate was attributed to the ability of the sampling chamber to filter out coarse particles with only the fine/ultrafine fraction capable of penetration and collection on the PUF disk. Passive sampler derived data was converted to equivalent air volumes (VEQ, m3) using the high volume air measurement results. Correlations of VEQ against meteorological data collected on-site yielded different behaviour for gas- and particle-associated compounds. For gas-phase chemicals, sampling rates varies by about a factor of 2 with temperature and windspeed. The higher sampling rates at colder temperatures were explained by the wind-effect on sampling rates. Temperature and wind were strongly correlated with greatest winds at colder temperatures. Mainly particle-phase compounds (namely, the high molecular weight PAHs) had more variable sampling rates. Sampling rates increased greatly at warmer temperaures as the high molecular weight PAH burden was shifted toward the gas-phase, and subject to higher gas-phase sampling rates. At colder temperatures, sampling rates were reduced as the partitioning of the high molecular weight PAHs was shifted toward the particle-phase. The observed wind effect on sampling for the particle-phase compounds is believed to be tied to this strong temperature dependence on phase partitioning and hence sapling rate. For purposes of comparing passive sampler derived data for POPs, the factor of two variability observed for mainly gas-phase compounds is deemed to be acceptable in many instances for semi-quantitative analysis. Depuration compounds may be used to improve accuracy and provide site specific sampling rates although this adds another level of complexity to the analysis. More research is needed to develop and test passive air samplers for particle-associated chemicals.
Česky
PUF disk passive air samplers were evaluated under field conditions to assess the effect of temperature and windspeed on sampling rate for polycyclic aromatic hydrocarbons (PAHs), polychlorinated biphenyls (PCBs) and organochlorine pesticides (OCPs). Passive samples integrated over 28-day periods were compared to high volume air samples collected for 24-h, every 7 days. This provided a large data set of 42 passive sampling events and 168 high volume samples over a 3-year period, starting in October 2003. Average PUF disk sampling rates for gas-phase chemicals was ~7 m3d-1 and comparable to previous reports. The high molecular weight PAHs, that are mainly particle-bound, experienced much lower sampling rates of ~0.7m3d-1. This small rate was attributed to the ability of the sampling chamber to filter out coarse particles with only the fine/ultrafine fraction capable of penetration and collection on the PUF disk. Passive sampler derived data was converted to equivalent air volumes (VEQ, m3) using the high volume air measurement results. Correlations of VEQ against meteorological data collected on-site yielded different behaviour for gas- and particle-associated compounds. For gas-phase chemicals, sampling rates varies by about a factor of 2 with temperature and windspeed. The higher sampling rates at colder temperatures were explained by the wind-effect on sampling rates. Temperature and wind were strongly correlated with greatest winds at colder temperatures. Mainly particle-phase compounds (namely, the high molecular weight PAHs) had more variable sampling rates. Sampling rates increased greatly at warmer temperaures as the high molecular weight PAH burden was shifted toward the gas-phase, and subject to higher gas-phase sampling rates. At colder temperatures, sampling rates were reduced as the partitioning of the high molecular weight PAHs was shifted toward the particle-phase. The observed wind effect on sampling for the particle-phase compounds is believed to be tied to this strong temperature dependence on phase partitioning and hence sapling rate. For purposes of comparing passive sampler derived data for POPs, the factor of two variability observed for mainly gas-phase compounds is deemed to be acceptable in many instances for semi-quantitative analysis. Depuration compounds may be used to improve accuracy and provide site specific sampling rates although this adds another level of complexity to the analysis. More research is needed to develop and test passive air samplers for particle-associated chemicals.
Návaznosti
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