posted on 2012-08-21, 00:00authored byMarianne Tronstad Lund, Veronika Eyring, Jan Fuglestvedt, Johannes Hendricks, Axel Lauer, David Lee, Mattia Righi
We utilize a range of emission scenarios for shipping
to determine
the induced global-mean radiative forcing and temperature change.
Ship emission scenarios consistent with the new regulations on nitrogen
oxides (NOx) and sulfur dioxide (SO2) from the International Maritime Organization and two of
the Representative Concentration Pathways are used as input to a simple
climate model (SCM). Based on a complex aerosol-climate model we develop
and test new parametrizations of the indirect aerosol effect (IAE)
in the SCM that account for nonlinearities in radiative forcing of
ship-induced IAE. We find that shipping causes a net global cooling
impact throughout the period 1900–2050 across all parametrizations
and scenarios. However, calculated total net global-mean temperature
change in 2050 ranges from −0.03[−0.07,–0.002]°C
to −0.3[−0.6,–0.2]°C in the A1B scenario.
This wide range across parametrizations emphasizes the importance
of properly representing the IAE in SCMs and to reflect the uncertainties
from complex global models. Furthermore, our calculations show that
the future ship-induced temperature response is likely a continued
cooling if SO2 and NOx emissions
continue to increase due to a strong increase in activity, despite
current emission regulations. However, such cooling does not negate
the need for continued efforts to reduce CO2 emissions,
since residual warming from CO2 is long-lived.