Abstract

Abstract. Improving the ability of global models to predict concentrations of black carbon (BC) over the Pacific Ocean is essential to evaluate the impact of BC on marine climate. In this study, we tag BC tracers from 13 source regions around the globe in a global chemical transport model, Model for Ozone and Related Chemical Tracers, version 4 (MOZART-4). Numerous sensitivity simulations are carried out varying the aging timescale of BC emitted from each source region. The aging timescale for each source region is optimized by minimizing errors in vertical profiles of BC mass mixing ratios between simulations and HIAPER Pole-to-Pole Observations (HIPPO). For most HIPPO deployments, in the Northern Hemisphere, optimized aging timescales are less than half a day for BC emitted from tropical and midlatitude source regions and about 1 week for BC emitted from high-latitude regions in all seasons except summer. We find that East Asian emissions contribute most to the BC loading over the North Pacific, while South American, African and Australian emissions dominate BC loadings over the South Pacific. Dominant source regions contributing to BC loadings in other parts of the globe are also assessed. The lifetime of BC originating from East Asia (i.e., the world's largest BC emitter) is found to be only 2.2 days, much shorter than the global average lifetime of 4.9 days, making the contribution from East Asia to the global BC burden only 36 % of that from the second largest emitter, Africa. Thus, evaluating only relative emission rates without accounting for differences in aging timescales and deposition rates is not predictive of the contribution of a given source region to climate impacts. Our simulations indicate that the lifetime of BC increases nearly linearly with aging timescale for all source regions. When the aging rate is fast, the lifetime of BC is largely determined by factors that control local deposition rates (e.g., precipitation). The sensitivity of lifetime to aging timescale depends strongly on the initial hygroscopicity of freshly emitted BC. Our findings suggest that the aging timescale of BC varies significantly by region and season and can strongly influence the contribution of source regions to BC burdens around the globe. Therefore, improving parameterizations of the aging process for BC is important for enhancing the predictive skill of global models. Future observations that investigate the evolution of the hygroscopicity of BC as it ages from different source regions to the remote atmosphere are urgently needed.

Highlights

  • Black carbon (BC) is an efficient absorber of solar radiation and heats the atmosphere and the Earth surface (Ramanathan and Carmichael, 2008)

  • We find that BC burden and source–receptor relationships are remarkably sensitive to the assumed aging timescale in the model; this motivates our use of HIAPER Pole-to-Pole Observations (HIPPO) observations to optimize the BC aging timescale by minimizing model–measurement differences

  • Based dry- and wet-deposition schemes and optimized aging timescales for different regions are employed in MOZART-4, which significantly improves the model’s performance over the Pacific Ocean relative to the default model; the campaign-averaged mean normalized absolute error is reduced by a factor of 4–10

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Summary

Introduction

Black carbon (BC) is an efficient absorber of solar radiation and heats the atmosphere and the Earth surface (Ramanathan and Carmichael, 2008). Estimates of BC’s direct radiative forcing vary widely, ranging from 0.19 W m−2 by Wang et al (2014) to 0.88 W m−2 by Bond et al (2013). The Intergovernmental Panel on Climate Change Fifth Assessment Report (IPCC, 2013) assesses the direct radiative forcing of BC to be 0.40 W m−2, with a large uncertainty range of 0.05 to 0.80 W m−2. J. Zhang et al.: Long-range transport of black carbon to the Pacific Ocean epidemiological studies have shown that BC is associated with increased hospital admissions and premature mortalities (Bell et al, 2009; Janssen et al, 2011)

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