Atmospheric hydrogen peroxide and organic hydroperoxides during PRIDE-PRD'06, China: their concentration, formation mechanism and contribution to secondary aerosols

Hua, W.; Chen, Z. M.; Jie, C. Y.; Kondo, Yasuyuki; Hofzumahaus, A.; Takegawa, N.; Chang, Chih-Chung; Lu, Keding; Miyazaki, Y.; Kita, K.; Wang, H. L.; Zhang, Y. H.; Hu, Minghao

doi:10.5194/acp-8-6755-2008

Cited by 181 publications

(174 citation statements)

References 110 publications

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“…The INTEX-NA and HOOVER 2 campaigns were both carried out over continental regions and during summer months and are thus particulary interesting for comparison. The H 2 O 2 mixing ratios from the DL (25 pmol mol −1 ) up to 5.5 nmol mol −1 observed during HOOVER are comparable to previous studies that also show a range of the values of up to an order of magnitude (Balasubramanian and Husain, 1997;Weinstein-Lloyd et al, 1998;Hua et al, 2008). During INTEX-NA maximum values reached up to 13 nmol mol −1 , but similar median values were measured as shown later on.…”

Section: Comparison Of Hoover To Former Field Studiessupporting

confidence: 89%

“…However, former studies show that the largest amount (90−100 % in the following cited studies) of the free tropospheric organic hydroperoxides consists of MHP (Heikes et al, 1996a;Jackson and Hewitt, 1996;Walker et al, 2006;Hua et al, 2008 . Since this interference is not only dependent on O 3 but also on H 2 O mixing ratios, it cannot be completely linearly corrected.…”

Section: Measurements Of H 2 O 2 and Ch 3 Ooh *mentioning

confidence: 92%

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Distribution of hydrogen peroxide and formaldehyde over Central Europe during the HOOVER project

et al. 2011

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Abstract. In this study we report measurements of hydrogen peroxide (H 2 O 2 ), methyl hydroperoxide* (MHP* as a proxy of MHP based on an unspecific measurement of total organic peroxides) and formaldehyde (HCHO) from the HO x OVer EuRope (HOOVER) project (HO x = OH+HO 2 ). HOOVER included two airborne field campaigns, in October 2006 and July 2007. Measurement flights were conducted from the base of operation Hohn (Germany, 54 • N, 9 • E) towards the Mediterranean and to the subpolar regions over Norway. We find negative concentration gradients with increasing latitude throughout the troposphere for H 2 O 2 and CH 3 OOH * . In contrast, observed HCHO is almost homogeneously distributed over central and northern Europe and is elevated over the Mediterranean. In general, the measured gradients tend to be steepest entering the Mediterranean region, where we also find the highest abundances of the 3 species. Mixing ratios of these tracers generally decrease with altitude. H 2 O 2 and CH 3 OOH * show maxima above the boundary layer at 2-5 km, being more distinct over southern than over northern Europe.We also present a comparison of our data with simulations by two global 3-D-models, MATCH-MPIC and EMAC, and with the box model CAABA. The models realistically represent altitude and latitude gradients for both HCHO and hydroperoxides (ROOH). In contrast, the models have problems reproducing the absolute mixing ratios, in particular of H 2 O 2 . Large uncertainties about retention coefficients and Correspondence to: H. Fischer (horst.fischer@mpic.de) cloud microphysical parameters suggest that cloud scavenging might be a large source of error for the simulation of H 2 O 2 . A sensitivity study with EMAC shows a strong influence of cloud and precipitation scavenging on the budget of H 2 O 2 as simulations improve significantly with this effect switched off.

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Section: Comparison Of Hoover To Former Field Studiessupporting

confidence: 89%

Section: Measurements Of H 2 O 2 and Ch 3 Ooh *mentioning

confidence: 92%

Distribution of hydrogen peroxide and formaldehyde over Central Europe during the HOOVER project

et al. 2011

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“…The interference of SO 2 on the sampling was estimated using the theoretical thermodynamic and kinetic analysis presented in Hua et al (2008). Considering the rate constant for reaction between peroxides and S(IV) reported by Ervens et al (2003) and the mean level of SO 2 was 7.0 ± 7.0 ppbv during the campaign, the negative artifact caused by SO 2 interference for peroxides was calculated to be less than 15 %.…”

Section: Measurement Methods For Atmospheric Peroxidesmentioning

confidence: 99%

“…The uncertainty of our observational data is estimated to be ∼ 15 %. Further details about our measurement method for atmospheric peroxides can be obtained from Hua et al (2008).…”

Section: Measurement Methods For Atmospheric Peroxidesmentioning

confidence: 99%

Observation of atmospheric peroxides during Wangdu Campaign 2014 at a rural site in the North China Plain

Wang

Chen

et al. 2016

Atmos. Chem. Phys.

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Abstract. Measurements of atmospheric peroxides were made during Wangdu Campaign 2014 at Wangdu, a rural site in the North China Plain (NCP) in summer 2014. The predominant peroxides were detected to be hydrogen peroxide (H 2 O 2 ), methyl hydroperoxide (MHP) and peroxyacetic acid (PAA). The observed H 2 O 2 reached up to 11.3 ppbv, which was the highest value compared with previous observations in China at summer time. A box model simulation based on the Master Chemical Mechanism and constrained by the simultaneous observations of physical parameters and chemical species was performed to explore the chemical budget of atmospheric peroxides. Photochemical oxidation of alkenes was found to be the major secondary formation pathway of atmospheric peroxides, while contributions from alkanes and aromatics were of minor importance. The comparison of modeled and measured peroxide concentrations revealed an underestimation during biomass burning events and an overestimation on haze days, which were ascribed to the direct production of peroxides from biomass burning and the heterogeneous uptake of peroxides by aerosols, respectively. The strengths of the primary emissions from biomass burning were on the same order of the known secondary production rates of atmospheric peroxides during the biomass burning events. The heterogeneous process on aerosol particles was suggested to be the predominant sink for atmospheric peroxides. The atmospheric lifetime of peroxides on haze days in summer in the NCP was about 2-3 h, which is in good agreement with the laboratory studies. Further comprehensive investigations are necessary to better understand the impact of biomass burning and heterogeneous uptake on the concentration of peroxides in the atmosphere.

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“…The PSCF value in the ijth cell is defined as mij / nij, where n ij is denoted as the number of endpoints that fall in the ijth cell and m ij represents the numbers of "polluted" trajectory endpoints in the ijth cell. In this analysis, average concentrations were considered to be the threshold of pollution (Hsu et al, 2003;Zhang et al, 2013). To minimize the effect of small values of n ij , following the method of Polissar et al (1999), the seasonal PSCF values were multiplied by arbitrary seasonal weight functions W ij , expressed by WPSCF, to better reflect the uncertainty in the values for these cells.…”

Section: Potential Source Contribution Functionmentioning

confidence: 99%

Characterization of atmospheric trace gases and particulate matter in Hangzhou, China

Zhang

et al. 2018

Atmos. Chem. Phys.

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Abstract. The Yangtze River Delta (YRD) is one of the most densely populated regions in China with severe air quality issues that have not been fully understood. Thus, in this study, based on 1-year (2013) continuous measurement at a National Reference Climatological Station (NRCS, 30.22 • N, 120.17 • E; 41.7 m a.s.l.) in the center of Hangzhou in the YRD, we investigated the seasonal characteristics, interspecies relationships, and the local emissions and the regional potential source contributions of trace gases (including O 3 , NO x , NO y , SO 2 , and CO) and particulate matter (PM 2.5 and PM 10 ). Results revealed that severe two-tier air pollution (photochemical and haze pollution) occurred in this region, with frequent exceedances in O 3 (38 days) and PM 2.5 (62 days). O 3 and PM 2.5 both exhibited distinct seasonal variations with reversed patterns: O 3 reaching a maximum in warm seasons (May and July) but PM 2.5 reaching a maximum in cold seasons (November to January). The overall results from interspecies correlation indicated a strong local photochemistry favoring the O 3 production under a volatile organic compound (VOC)-limited regime, whereas it moved towards an optimum O 3 production zone during warm seasons, accompanied by the formation of secondary fine particulates under high O 3 . The emission maps of PM 2.5 , CO, NO x , and SO 2 demonstrated that local emissions were significant for these species on a seasonal scale. The contributions from the regional transport among inland cities (Zhejiang, Jiangsu, Anhui, and Jiangxi Province) on a seasonal scale were further confirmed to be crucial to air pollution at the NRCS site by using backward trajectory simulations. Air masses transported from the offshore areas of the Yellow Sea, East Sea, and South Sea were also found to be highly relevant to the elevated O 3 at the NRCS site through the analysis of potential source contribution function (PSCF). Case studies of photochemical pollution (O 3 ) and haze (PM 2.5 ) episodes both suggested the combined importance of local atmospheric photochemistry and synoptic conditions during the accumulation (related with anticyclones) and dilution process (related with cyclones). Apart from supplementing a general picture of the air pollution state in the city of Hangzhou in the YRD region, this study specifically elucidates the role of local emission and regional transport, and it interprets the physical and photochemical processes during haze and photochemical pollution episodes. Moreover, this work suggests that cross-regional control measures are crucial to improve air quality in the YRD region, and it further emphasizes the importance of local thermally induced circulation for air quality.

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Atmospheric hydrogen peroxide and organic hydroperoxides during PRIDE-PRD'06, China: their concentration, formation mechanism and contribution to secondary aerosols

Cited by 181 publications

References 110 publications

Distribution of hydrogen peroxide and formaldehyde over Central Europe during the HOOVER project

Distribution of hydrogen peroxide and formaldehyde over Central Europe during the HOOVER project

Observation of atmospheric peroxides during Wangdu Campaign 2014 at a rural site in the North China Plain

Characterization of atmospheric trace gases and particulate matter in Hangzhou, China

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