As an ongoing effort, the scientific results (beyond the state of the art) and impact of the project during the current reporting period have been monitored, primarily targeting new breakthrough scientific discoveries in currently unregulated emissions formation, evolution, and abatement; emissions air quality, climate, and human health impacts; emissions measurement systems and methods. Examples of the scientific progress, also heavily informed by the latest literature, are as follows:
• Characterisation of a wide volatility range of volatile and I/SVOC emissions (from carbon number 1 (C1) to ~C40) from the same source thanks to combining measurements and samplings utilising Fourier transform infrared spectroscopy (FTIR), compact Proton-transfer-reaction time-of-flight mass spectrometry (compact-PTR-ToF-MS), and comprehensive two-dimensional gas chromatography with ToF-MS (GC×GC-ToF-MS);
• Onboard vehicle emissions (RDE) measurement with the compact-PTR-ToF-MS, developed by an industrial consortium partner, and an advanced portable emissions measurement system featuring FTIR and particle number quantification with 10 and 23 nm cut-off;
• Enhancement of 1-12 nm particles measurement from the engine exhaust (fresh and aged) thanks to the developments in the particle size magnifier (PSM) technology by an industrial consortium partner;
• Work towards volatile and I/SVOC emissions measurement under transient engine and exhaust aftertreatment operation using bespoke testing setups and protocols;
• Work towards health impact prediction, and holistic taxonomisation and prioritisation of volatile and I/SVOC emissions and secondary aerosols (SA) developing/utilising AI/ML.
Furthermore, the project’s economic/technological progress, e.g. two new instruments by EU companies, as well as societal/environmental progress, e.g. health/social impact of air pollution, offering technologies to monitor unregulated emissions towards regulatory frameworks, have been monitored.