Conference Agenda

Sustainable energy transition aligns with UN Goal 7. Carbon-based fuel combustion emits CO₂, methane, and black carbon, worsening climate change. Contrasting hydrogen, ammonia (NH₃) is easier to store and transport but requires a pilot fuel for combustion because of bad ignition properties. In a dual-fuel engine study, replacing diesel with NH₃ reduced CO₂ emissions but increased N₂O and NOx. Nevertheless, at 80% diesel substitution, CO₂-equivalent greenhouse gas emissions dropped by 78%, while soot emissions also decreased. However, NH₃ and NOx emissions may enhance secondary aerosol formation, necessitating exhaust aftertreatment to mitigate environmental impacts for the low-carbon fuel alternative diesel/NH3.

Shipping is a significant source of light absorbing aerosols, i.e. black (BC) and brown carbon (BrC), which contribute to atmospheric warming. In 2020, the International Maritime Organization introduced a global regulation that reduced the maximum allowed sulfur content in fuels from 3.5 to 0.5% to mitigate sulfur pollution. We examined the light absorbing properties of fresh and aged aerosol emissions from a ship engine using fuels complying with the two major sulfur regulations. The results demonstrated that aerosol emissions from globally compliant LS-HFO can exhibit light-absorbing characteristics similar to SECA-compliant MGO, but with stronger overall absorption.

Brake wear particles, generated from the brake pad – brake disc contact, contribute significantly to particle emissions from vehicle transport. We use the pin on disc method to experimentally simulate mild and harsh braking using samples from comercial brake discs and brake pads. We find that BWP have substantial absorption at wavelengths spanning from UV to IR assessed with an aethalometer. The absorption is around 10% that of Black Carbon. We discuss the source of the absorbing material in BWP and the implications of the results on source apportionment of transport emissions.

A large waste treatment facility fire in Rusko, Tampere (November 2024) caused severe air pollution, with PM2.5 concentrations reaching 200 μg/m³ in nearby residential areas—almost 100 times the background level. Measurements using a mobile laboratory analyzed particle size, composition, and black carbon content. TEM analysis revealed diverse elements, including carbon, sulfur, and heavy metals. Despite high black carbon concentrations, organic compounds dominated. The smoke plume remained compact over long distances, worsening air quality. Findings highlight the severe impact of open waste burning on air pollution and health.