@misc{10481/71062,
year = {2021},
month = {9},
url = {http://hdl.handle.net/10481/71062},
abstract = {Levitation of single trapped particles enables the exploration of fundamental physicochemical aerosol properties never previously achieved. Experimental measurements showed that (NH4)(2)SO4's particle shape deviated from sphericity during the crystallization process. Despite that, salt aerosols are assumed to be spheres even in low relative humidity (RH) in most climate models. In the analysis performed here, Mie and T-Matrix codes were operated to simulate crucial parameters needed to estimate the radiative forcing efficiency: extinction efficiency, asymmetry parameter and backscattering fraction. The incorporation of non-spherical effects in (NH4)(2)SO4 particles can cause a difference of up to 46% radiative forcing efficiency compared to the assumption of sphericity in the 0.3-0.6 mu m particle radius range.},
organization = {European Commission	754446},
organization = {UGR Research and Knowledge Transfer Fund-Athenea3i},
publisher = {MDPI},
keywords = {Single levitated particle},
keywords = {Non-sphericity},
keywords = {Radiative forcing efficiency},
title = {Particle Shape Impact on the Radiative Forcing Efficiency Estimated from Single Levitated (NH4)2SO4 Particles},
doi = {10.3390/atmos12091231},
author = {Valenzuela Gutiérrez, Antonio},
}