Trans‐Pacific transport of black carbon and fine aerosols (<i>D</i> &lt; 2.5 <i>μ</i>m) into North America

Hadley, O. L.; Ramanathan, V.; Carmichael, G. R.; Tang, Youhua; Corrigan, C.; Roberts, Grégory; Mauger, Guillaume

doi:10.1029/2006jd007632

Cited by 84 publications

(88 citation statements)

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“…Then it is plausible that, in densely populated regions, decadal trends in aerosol emissions induce decadal trends in SWIR with opposite sign; and, since aerosols are transported over large distances [e.g., Shaw, 1981;Uematsu et al, 1983;Ramanathan et al, 2001b;Prospero et al, 2003;Colarco et al, 2003;Heald et al, 2006;Hadley et al, 2007] these trends may also affect SWIR in adjacent regions and possibly even at remote sites. These speculations are reconcilable with (1) the trends in aerosols as reported by Streets et al [2006], (2) the measurements of atmospheric transmission in Figure 12 of Ohmura [2006] and (3) the increase in SWIR under clearsky conditions at remote BSRN sites in the period from 1992 through to 2002 estimated by Wild et al [2005].…”

Section: Summary and Concluding Remarksmentioning

confidence: 99%

Decadal changes in shortwave irradiance at the surface in the period from 1960 to 2000 estimated from Global Energy Balance Archive Data

Gilgen¹,

Roesch²,

Wild³

et al. 2009

J. Geophys. Res.

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Decadal changes in shortwave irradiance at the Earth's surface are estimated for the period from approximately 1960 through to 2000 from pyranometer records stored in the Global Energy Balance Archive. For this observational period, estimates could be calculated for a total of 140 cells of the International Satellite Cloud Climatology Project grid (an equal area 2.5° × 2.5° grid at the equator) using regression models allowing for station effects. In large regions worldwide, shortwave irradiance decreases in the first half of the observational period, recovers from the decrease in the 1980s, and thereafter increases, in line with previous reports. Years of trend reversals are determined for the grid cells which are best described with a second‐order polynomial model. This reversal of the trend is observed in the majority of the grid cells in the interior of Europe and in Japan. In China, shortwave irradiance recovers during the 1990s in the majority of the grid cells in the southeast and northeast from the decrease observed in the period from 1960 through to 1990. A reversal of the trend in the 1980s or early 1990s is also observed for two grid cells in North America, and for the grid cells containing the Kuala Lumpur (Malaysia), Singapore, Casablanca (Morocco), Valparaiso (Chile) sites, and, noticeably, the remote South Pole and American Samoa sites. Negative trends persist, i.e., shortwave radiation decreases, for the observational period 1960 through to 2000 at the European coasts, in central and northwest China, and for three grid cells in India and two in Africa.

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Section: Summary and Concluding Remarksmentioning

confidence: 99%

Decadal changes in shortwave irradiance at the surface in the period from 1960 to 2000 estimated from Global Energy Balance Archive Data

Gilgen¹,

Roesch²,

Wild³

et al. 2009

J. Geophys. Res.

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“…BC in this region is mainly from North American anthropogenic emissions (Park et al, 2003), transpacific transport of Asian emissions especially during spring Hadley et al, 2007;Park et al, 2003), and North American biomass burning emissions during the summer and fall fire season (Spracklen et al, 2009;Park et al, 2003). However, the relative contributions from these sources particularly biomass burning to BC in the WUS are still uncertain.…”

Section: Introductionmentioning

confidence: 99%

Biomass burning contribution to black carbon in the Western United States Mountain Ranges

Mao

Zhang

et al. 2011

Atmos. Chem. Phys.

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Abstract. Forest fires are an important source to carbonaceous aerosols in the Western United States (WUS). We quantify the relative contribution of biomass burning to black carbon (BC) in the WUS mountain ranges by analyzing surface BC observations for 2006 from the Interagency Monitoring of PROtected Visual Environment (IMPROVE) network using the GEOS-Chem global chemical transport model. Observed surface BC concentrations show broad maxima during late June to early November. Enhanced potassium concentrations and potassium/sulfur ratios observed during the high-BC events indicate a dominant biomass burning influence during the peak fire season. Model surface BC reproduces the observed day-to day and synoptic variabilities in regions downwind of but near urban centers. Major discrepancies are found at elevated mountainous sites during the July-October fire season when simulated BC concentrations are biased low by a factor of two. We attribute these low biases largely to the underestimated (by more than a factor of two) and temporally misplaced biomass burning emissions of BC in the model. Additionally, we find that the biomass burning contribution to surface BC concentrations in the USA likely was underestimated in a previous study using GEOS-Chem (Park et al., 2003), because of the unusually low planetary boundary layer (PBL) heights in the GEOS-3 meteorological reanalysis data used to drive the model. PBL heights from GEOS-4 and GEOS-5 reanalysis data are comparable to those from the North American Regional Reanalysis (NARR). Model simulations show slightly improved agreements with the observations when driven by GEOS-5 reanalysis data, but model results are still biased low. The use of biomass burning emisCorrespondence to: Q. B. Li (qli@atmos.ucla.edu) sions with diurnal cycle, synoptic variability, and plume injection has relatively small impact on the simulated surface BC concentrations in the WUS.

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“…For example, the strong anthropogenic emissions over East Asia have led to an increasing interest in quantifying the impact of aerosols exported from East Asia. Recent studies indicate that the transpacific transport of sulfate from East Asia contributes to 30-50 % of the background (sulfate produced from non-local emissions) surface concentrations in the western US and 10-30 % in the eastern US (Park et al, 2004;Hadley et al, 2007;Liu et al, 2008), which are larger than contributions from all other foreign sources (Liu et al, 2009). In addition, among the major emitting regions assessed for 2001 conditions, European sources were shown to account for 1-5 µg m −3 of surface sulfate concentrations over northern Africa and western Asia, and their contribution to East Asia (0.2-0.5 µg m −3 ) was twice as much as the contribution (0.1-0.2 µg m −3 ) of Asian sources to North America (Chin et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

Global source attribution of sulfate concentration and direct and indirect radiative forcing

et al. 2017

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Abstract. The global source-receptor relationships of sulfate concentrations, and direct and indirect radiative forcing (DRF and IRF) from 16 regions/sectors for years 2010-2014 are examined in this study through utilizing a sulfur source-tagging capability implemented in the Community Earth System Model (CESM) with winds nudged to reanalysis data. Sulfate concentrations are mostly contributed by local emissions in regions with high emissions, while over regions with relatively low SO 2 emissions, the near-surface sulfate concentrations are primarily attributed to non-local sources from long-range transport. Regional source efficiencies of sulfate concentrations are higher over regions with dry atmospheric conditions and less export, suggesting that lifetime of aerosols, together with regional export, is important in determining regional air quality. The simulated global total sulfate DRF is −0.42 W m −2 , with −0.31 W m −2 contributed by anthropogenic sulfate and −0.11 W m −2 contributed by natural sulfate, relative to a state with no sulfur emissions. In the Southern Hemisphere tropics, dimethyl sulfide (DMS) contributes 17-84 % to the total DRF. East Asia has the largest contribution of 20-30 % over the Northern Hemisphere mid-and high latitudes. A 20 % perturbation of sulfate and its precursor emissions gives a sulfate incremental IRF of −0.44 W m −2 . DMS has the largest contribution, explaining −0.23 W m −2 of the global sulfate incremental IRF. Incremental IRF over regions in the Southern Hemisphere with low background aerosols is more sensitive to emission perturbation than that over the polluted Northern Hemisphere.

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Trans‐Pacific transport of black carbon and fine aerosols (D < 2.5 μm) into North America

Cited by 84 publications

References 50 publications

Decadal changes in shortwave irradiance at the surface in the period from 1960 to 2000 estimated from Global Energy Balance Archive Data

Decadal changes in shortwave irradiance at the surface in the period from 1960 to 2000 estimated from Global Energy Balance Archive Data

Biomass burning contribution to black carbon in the Western United States Mountain Ranges

Global source attribution of sulfate concentration and direct and indirect radiative forcing

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