AI Article Synopsis
- The study analyzes the formation of contrails from ammonia-powered engines compared to traditional jet fuel engines, focusing on thermodynamic processes like supersaturation and ice nucleation.
- It calculates how moisture from exhaust affects atmospheric conditions, determining the potential for contrail visibility based on temperature and humidity changes.
- Findings suggest that ammonia contrails are less dense but can form at lower altitudes and last longer due to higher moisture content, despite not producing soot which typically aids contrail formation.
Article Abstract
Condensation trail (contrail) formation in an airplane's wake requires thermodynamics supersaturation and ice nucleation to form visible ice crystals. Here, using a thermodynamic analysis, we evaluate the potential for forming contrails in a carbon-free, ammonia-powered propulsion system compared to conventional planes powered by jet fuel. The analysis calculates the moisture released by fuel into the atmosphere for each one-degree increase in air temperature due to exhaust gas. It then determines if this moisture can saturate the initially undersaturated atmosphere, maintain saturation as temperature rises, and result in supersaturation with respect to ice while leaving enough moisture for a visible cloud to form. With ammonia increases the critical temperature required for supersaturation. Although ammonia does not generate soot particles in the exhaust gas, various aerosols exist in the atmosphere through other sources that can facilitate heterogeneous ice nucleation. Hence, while ammonia's contrails might not be as dense, they can form at lower altitudes where the air is warmer and endure longer due to the increased water content, which preserves supersaturation for longer as fresh air dilutes the contrail.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11555222 | PMC |
| http://dx.doi.org/10.1038/s44172-024-00312-2 | DOI Listing |
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Article Synopsis
- The study analyzes the formation of contrails from ammonia-powered engines compared to traditional jet fuel engines, focusing on thermodynamic processes like supersaturation and ice nucleation.
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- Findings suggest that ammonia contrails are less dense but can form at lower altitudes and last longer due to higher moisture content, despite not producing soot which typically aids contrail formation.
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