Athanasios Nenes scite author profile

Abstract. The present paper reviews existing knowledge with regard to Organic Aerosol (OA) of importance for global climate modelling and defines critical gaps needed to reduce the involved uncertainties. All pieces required for the representation of OA in a global climate model are sketched out with special attention to Secondary Organic Aerosol (SOA): The emission estimates of primary carbonaceous particles and SOA precursor gases are summarized. The up-to-date understanding of the chemical formation and transformation of condensable organic material is outlined. Knowledge on the hygroscopicity of OA and measurements of optical properties of the organic aerosol constituents are summarized. The mechanisms of interactions of OA with clouds and dry and wet removal processes parameterisations in global models are outlined. This information is synthesized to provide a continuous analysis of the flow from the emitted material to the atmosphere up to the point of the climate impact of the produced organic aerosol. The sources of uncertainties at each step of this process are highlighted as areas that require further studies.

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Iron mobilization in mineral dust: Can anthropogenic SO₂ emissions affect ocean productivity?

Meskhidze

Chameides

Nenes

et al. 2003

Geophysical Research Letters

315

371

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Abstract:In order for Fe contained in aeolian dust to act as a micronutrient for oceanic phytoplankton it must be first mobilized or dissolved. We propose that significant Femobilization can occur in mineral dust from East Asia as a result of the incorporation of SO 2 from pollutant emissions into the advecting dust plumes and the subsequent acidification of the dust by heterogeneous SO 2 oxidation. To test this acid-mobilization hypothesis, we consider a dust plume that originated from the gobi deserts and advected over the Yellow Sea in March of 2001. Data collected during the TRACE-P field campaign confirm that this plume contained high concentrations of both dust and SO 2 .Measurements within the plume of significant concentrations of gaseous HNO 3 suggest that the dust particles were highly acidified (i.e., pH< 2). At these pH's, approximately 1-2% of the Fe contained in a deliquescent mineral dust particle would be mobilized within the nominal 3-5 day lifetime of the particle. These results suggest that there may be a link between the rate of C-fixation in so-called High-Nitrate-Low-Chlorophyll regions of the ocean and the rate of SO 2 emissions from East Asia.2

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Droplet nucleation: Physically-based parameterizations and comparative evaluation

Ghan

Abdul-Razzak

Nenes

et al. 2011

J. Adv. Model. Earth Syst.

178

251

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One of the greatest sources of uncertainty in simulations of climate and climate change is the influence of aerosols on the optical properties of clouds. The root of this influence is the droplet nucleation process, which involves the spontaneous growth of aerosol into cloud droplets at cloud edges, during the early stages of cloud formation, and in some cases within the interior of mature clouds. Numerical models of droplet nucleation represent much of the complexity of the process, but at a computational cost that limits their application to simulations of hours or days. Physically-based parameterizations of droplet nucleation are designed to quickly estimate the number nucleated as a function of the primary controlling parameters: the aerosol number size distribution, hygroscopicity and cooling rate. Here we compare and contrast the key assumptions used in developing each of the most popular parameterizations and compare their performances under a variety of conditions. We find that the more complex parameterizations perform well under a wider variety of nucleation conditions, but all parameterizations perform well under the most common conditions. We then discuss the various applications of the parameterizations to cloudresolving, regional and global models to study aerosol effects on clouds at a wide range of spatial and temporal scales. We compare estimates of anthropogenic aerosol indirect effects using two different parameterizations applied to the same global climate model, and find that the estimates of indirect effects differ by only 10%. We conclude with a summary of the outstanding challenges remaining for further development and application.

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Can chemical effects on cloud droplet number rival the first indirect effect?

Nenes

Charlson

Facchini

et al. 2002

Geophysical Research Letters

209

226

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An increase in cloud droplet number concentration resulting from an increase in ambient aerosol (and subsequent albedo increase) is typically identified as the first indirect (or “Twomey”) climatic effect of aerosols [Twomey, 1974]. A key question is whether chemical effects (dissolution of soluble gases and slightly soluble substances, surface tension depression by organic substances and accommodation coefficient changes) could potentially rival changes in droplet number from changes in aerosol number concentration. We assess the sensitivity of cloud droplet number concentration to such chemical factors, using a cloud parcel model. We find that numerous conditions exist, for which chemical influences on cloud droplet activation can indeed rival the Twomey effect.

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Kinetic limitations on cloud droplet formation and impact on cloud albedo

et al. 2001

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Under certain conditions mass transfer limitations on the growth of cloud condensation nuclei (CCN) may have a significant impact on the number of droplets that can form in a cloud. The assumption that particles remain in equilibrium until activated may therefore not always be appropriate for aerosol populations existing in the atmosphere. This work identifies three mechanisms that lead to kinetic limitations, the effect of which on activated cloud droplet number and cloud albedo is assessed using a one-dimensional cloud parcel model with detailed microphysics for a variety of aerosol size distributions and updraft velocities. In assessing the effect of kinetic limitations, we have assumed as cloud droplets not only those that are strictly activated (as dictated by classical Kö hler theory), but also unactivated drops large enough to have an impact on cloud optical properties. Aerosol number concentration is found to be the key parameter that controls the significance of kinetic effects. Simulations indicate that the equilibrium assumption leads to an overprediction of droplet number by less than 10% for marine aerosol; this overprediction can exceed 40% for urban type aerosol. Overall, the effect of kinetic limitations on cloud albedo can be considered important when equilibrium activation theory consistently overpredicts droplet number by more than 10%. The maximum change in cloud albedo as a result of kinetic limitations is less than 0.005 for cases such as marine aerosol; however albedo differences can exceed 0.1 under more polluted conditions. Kinetic limitations are thus not expected to be climatically significant on a global scale, but can regionally have a large impact on cloud albedo.

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