Conference Agenda

A one year-long campaign (03/2024–03/2025) in Athens used the new AE36s Aethalometer and Total Carbon Analyzer to analyze carbonaceous aerosols (CA) with high-time resolution. The study applied spectral clustering and the 2D BC tracer method to differentiate sources like traffic, wildfire plumes, and mineral dust. Results showed distinct absorption fingerprints and significant secondary organic carbon (SOC) contributions in summer. These findings enhance real-time source apportionment and targeted mitigation strategies to reduce PM2.5 pollution effectively.

Multiple sources of air pollution in Moscow, no using of biomass and coal, have complicated the identifying observed BrC light absorption.Four sources obtained using BrC PMF analysis: FF combustion; BB; secondary aerosols and city dust. The uniqueness of Moscow megacity for BB impact studies in Europe and Asia is highlighted by gas-fueled heating system,and) exposure by BB emissions transported from the region around at the level similar during HP and non-HP periods. BB impact increases during spring regional agriculture and summer wildfires. Moscow is mostly affected by BrC which contribution is higher from FF combustion than from BB

We present a ¹⁴C-based source apportionment study carried out at an urban background site in the Po Valley, a hotspot area in Europe. Fourteen PM₁ samples were collected in Jan-Mar 2021 in Bologna with 48-h resolution and were prepared using MISSMARPLE, a recently developed sample preparation line for ¹⁴C measurements on atmospheric aerosol carbon fractions. ¹⁴C-based source apportionment was performed separately for elemental carbon (EC) and organic carbon (OC), after suitable optimization of model parameters. Fossil fuel combustion remains the main source of EC in the investigated area (60%), while modern contributions generally dominate the OC fraction (66%)

Biomass burning (BB) aerosol impacts climate and atmospheric
chemistry. To quantify BB aerosol’s contributions to aerosol optical
depth (AOD) at a given location we developed a new framework that
integrats satellite fire data with aerosol transport, BB emissions, and
plume rise models. Applying it in Warsaw (2006–2022) revealed dominant
transatlantic influences, with Canada (33%) and the USA (33%) together
surpassing European sources. Accounting for
vertical plume dynamics is crucial; neglecting them leads to biases in
source estimates. This framework can be broadly applied, though future
work should refine aerosol characterization, including plume structure,
aging, and emission inventories.

Delhi experiences exceptionally high PM₂.₅-bound chlorine concentrations, with pronounced seasonal and diel variations, peaking in colder months and mornings due to meteorological influences like RH, temperature, and PBLH. Biomass burning, coal combustion, and industry contribute, but their relative impacts remain unclear. This study integrates Punjab field data (2023) with IIT Delhi observations (2019–2022) to assess stubble burning’s role. Elevated Cl levels in Punjab correlated with biomass-burning tracers (BC, K, OA, CO), with PMF analysis attributing 80% of Cl to stubble burning. Diagnostic ratios indicate mixed Cl sources in Delhi, including waste burning and industrial emissions.