Abstract
Abstract. Evaluation of the aerosol schemes in current climate models is dependent upon the available observational data. In-situ observations from flight campaigns can provide valuable data about the vertical distribution of aerosol that is difficult to obtain from satellite or ground-based platforms, although they are localised in space and time. Using single-particle soot-photometer (SP2) measurements from the HIAPER Pole-to-Pole Observations (HIPPO) campaign, which consists of many vertical profiles over a large region of the Pacific, we evaluate the meridional and vertical distribution of black carbon (BC) aerosol simulated by the HadGEM3–UKCA and ECHAM5–HAM2 models. Both models show a similar pattern of overestimating the BC column burden compared to that derived from the observations, in many areas by an order of magnitude. However, by sampling the simulated BC mass mixing ratio along the flight track and comparing to the observations, we show that this discrepancy has a rather different vertical structure in the two models: in HadGEM3–UKCA the discrepancy is dominated by excess aerosol in the tropical upper troposphere, while in ECHAM5–HAM2 areas of discrepancy are spread across many different latitudes and altitudes. Using this methodology, we conduct sensitivity tests on two specific elements of the models: biomass-burning emissions and scavenging by convective precipitation. We show that, by coupling the convective scavenging more tightly with convective transport, both the column burden and vertical distribution of BC in HadGEM3–UKCA are much improved with respect to the observations, with a substantial and statistically significant increase in correlation – this demonstrates the importance of a realistic representation of this process. In contrast, updating from GFED2 to GFED3.1 biomass-burning emissions makes a more modest improvement in both models, which is not statistically significant. By comparing our results with a more traditional approach using regional- and monthly-mean vertical profile curves, we show that the point-by-point analysis allows the model improvements to be demonstrated more clearly. We also demonstrate the important role that nudged simulations (where the large-scale model dynamics are continuously relaxed towards a reanalysis) can play in this type of evaluation, allowing statistically significant differences between configurations of the aerosol scheme to be seen where the differences between the corresponding free-running simulations would not be significant.
Highlights
We demonstrate the important role that nudged simsimulated Black carbon (BC) mass mixing ratio along the flight track and ulations ccaien nplcayein this type of ancy has a rather different vertical structure in the two mod- evaluation, allowing statistically significant differences beels: in HadGEM3–UKCA the discrepancy is dominated by tween configurations of the aerosol scheme to be seen where excess aerosol in the tropical upper troposphere, while in the differences between the corresponding free-running sim
It is clear from these difference plots that, at least for HIPPO-1 and HIPPO-2, the upper-tropospheric excess seen in the BASE configuration is largely removed when the inplume convective scavenging scheme is switched on, suggesting that the lack of realistic convective scavenging may have been responsible
We develop methods for evaluating aerosol– climate models against large-scale aircraft campaigns, and apply these to investigate the impact of convective scavenging and biomass-burning emissions on the vertical profile of black carbon
Summary
Aerosol particles in the atmosphere play an important role in the climate system on both global and regional scales, through several mechanisms: direct modification of the short-wave radiation budget by scattering and absorption (Angstrom, 1962; Schulz et al, 2006; Myhre et al, 2013); effects on clouds and the hydrological cycle, indirectly modifying the radiation budget (Twomey, 1977; Albrecht, 1989; Lohmann and Feichter, 2005); and “semi-directly” by altering the temperature profile of the atmosphere, and evaporating or suppressing cloud, through absorption of radiation (Hansen, 1997; Koch and Del Genio, 2010). Black carbon (BC) aerosol can contribute to all of these classes of effect, its absorption of short-wave radiation makes it of particular interest in the context of the direct and semi-direct effects (Stier et al, 2007; Ramanathan and Carmichael, 2008). “aged” BC particles with a soluble coating can act as cloud condensation nuclei (Penner et al, 1996; Lohmann et al, 2000), and contribute to indirect effects; ageing may reduce the lifetime of black carbon (by increasing susceptibility to wet deposition) and enhance its absorption of radiation (Ackerman and Toon, 1981; Stier et al, 2006; Schwarz et al, 2008)
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