TY - JOUR
T1 - Net zero-emission pathways reduce the physical and economic risks of climate change
AU - Drouet, Laurent
AU - Bosetti, Valentina
AU - Padoan, Simone A.
AU - Aleluia Reis, Lara
AU - Bertram, Christoph
AU - Dalla Longa, Francesco
AU - Després, Jacques
AU - Emmerling, Johannes
AU - Fosse, Florian
AU - Fragkiadakis, Kostas
AU - Frank, Stefan
AU - Fricko, Oliver
AU - Fujimori, Shinichiro
AU - Harmsen, Mathijs
AU - Krey, Volker
AU - Oshiro, Ken
AU - Nogueira, Larissa P.
AU - Paroussos, Leonidas
AU - Piontek, Franziska
AU - Riahi, Keywan
AU - Rochedo, Pedro R.R.
AU - Schaeffer, Roberto
AU - Takakura, Jun’ya
AU - van der Wijst, Kaj Ivar
AU - van der Zwaan, Bob
AU - van Vuuren, Detlef
AU - Vrontisi, Zoi
AU - Weitzel, Matthias
AU - Zakeri, Behnam
AU - Tavoni, Massimo
N1 - Publisher Copyright:
© 2021, The Author(s), under exclusive licence to Springer Nature Limited.
PY - 2021/12
Y1 - 2021/12
N2 - Mitigation pathways exploring end-of-century temperature targets often entail temperature overshoot. Little is known about the additional climate risks generated by overshooting temperature. Here we assessed the benefits of limiting overshoot. We computed the probabilistic impacts for different warming targets and overshoot levels on the basis of an ensemble of integrated assessment models. We explored both physical and macroeconomic impacts, including persistent and non-persistent climate impacts. We found that temperature overshooting affects the likelihood of many critical physical impacts, such as those associated with heat extremes. Limiting overshoot reduces risk in the right tail of the distribution, in particular for low-temperature targets where larger overshoots arise as a way to lower short-term mitigation costs. We also showed how, after mid-century, overshoot leads to both higher mitigation costs and economic losses from the additional impacts. The study highlights the need to include climate risk analysis in low-carbon pathways.
AB - Mitigation pathways exploring end-of-century temperature targets often entail temperature overshoot. Little is known about the additional climate risks generated by overshooting temperature. Here we assessed the benefits of limiting overshoot. We computed the probabilistic impacts for different warming targets and overshoot levels on the basis of an ensemble of integrated assessment models. We explored both physical and macroeconomic impacts, including persistent and non-persistent climate impacts. We found that temperature overshooting affects the likelihood of many critical physical impacts, such as those associated with heat extremes. Limiting overshoot reduces risk in the right tail of the distribution, in particular for low-temperature targets where larger overshoots arise as a way to lower short-term mitigation costs. We also showed how, after mid-century, overshoot leads to both higher mitigation costs and economic losses from the additional impacts. The study highlights the need to include climate risk analysis in low-carbon pathways.
U2 - 10.1038/s41558-021-01218-z
DO - 10.1038/s41558-021-01218-z
M3 - Journal article
AN - SCOPUS:85120085327
SN - 1758-678X
VL - 11
SP - 1070
EP - 1076
JO - Nature Climate Change
JF - Nature Climate Change
IS - 12
ER -