[Blog 1] The global warming paradox of the colder winters
Global warming, caused by the greenhouse effect, makes the global average temperature to rise. This is clearly noted in the hotter summers and the more common heat waves. However, experience also showed that winters are getting colder, and extreme low temperatures are more frequent.
At first sight, it could be considered as a paradox against global warming. Nevertheless, this can be explained considering the changes caused on the jet streams of the Earth by the increasing temperature of the atmosphere. Jet streams are fast flowing, narrow, air currents flowing west to east, which separate masses of air with significant difference in temperature. The jet streams are caused by two factors: the atmospheric heating by solar radiation that produces the Hadley (1), Ferrel (2) and polar (3) circulation cells, and the action of the Coriolis force acting on those moving masses (caused by the planet’s rotation on its axis).
Source: National weather service
When global warming rises the temperature of the air contained in these cells, the air expands by thermal expansion. Because of the gravity force of Earth, the air mass is attracted and shifted to the north and south from the equator, causing a wavy jet stream.
Source: NOAA, Scientific American, CBC News
This wavy jet streams allows the colder air from the north to reach new geographical locations that were traditionally not affected by these extreme temperatures. Similarly, the more frequent heat waves are caused by the wavy jet stream that separates the Hadley and Ferrel cells, which allow the warm air of the equator to head north.
In the following animated gifs, from NASA, it can be seen the behavior of a wavy jet stream, and the consequences in the temperature of the Earth.
Source: NASA
Project info
1 April 2021 – 30 June 2023
Total budget: 188,442.24 €
Spain
• University of Zaragoza
Japan
• Waseda University (Nakagaki Lab)
Austria
• K1-MET GmbH
General coordinator
M. Bailera (mbailera@unizar.es)
University of Zaragoza
Further information: cordis.europa.eu
[1] A review on CO2 mitigation in the Iron and Steel industry through Power to X processes. M Bailera, P Lisbona, B Peña, LM Romeo. Journal of CO2 Utilization, Volume 46, 1 April 2021, Pages 101456.
[2] CO2 recycling in the Iron and Steel Industry via Power-to-Gas and Oxy-Fuel Combustion. J Perpiñán, M Bailera, LM Romeo, B Peña, V Eveloy. Energies, Volume 14, 29 October 2021, Pages 7090.
[3] Revisiting the Rist diagram for predicting operating conditions in blast furnaces with multiple injections. M Bailera, T Nakagaki, R Kataoka. Open Research Europe, Volume 1:141, 29 November 2021.
[4] Synthetic natural gas production in a 1 kW reactor using Ni–Ce/Al2O3 and Ru–Ce/Al2O3: Kinetics, catalyst degradation and process design. M Bailera, P Lisbona, B Peña, A Alarcón, J Guilera, J Perpiñán, LM Romeo. Energy, Volume 256, 1 October 2022, Pages 124720.
[1] The global warming paradox of the colder winters
[2] Decarbonization of the industry: why electrification is not enough
[3] What is Power to Gas?
[4] How does it look a methanation plant? (laboratory at Unizar)
[5] Why the reutilization of CO2 must be smart?
[6] How does it work a Blast Furnace?
[7] Power to X routes for the decarbonization of ironmaking
[8] How does it look a blast furnace simulation? (Aspen Plus software)
This project has received funding from the European Union’s Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No 887077.
Project info
1 April 2021 – 30 June 2023
Total budget: 188,442.24 €
Spain
• University of Zaragoza Japan
• Waseda University (Nakagaki Lab) Austria
• K1-MET GmbH
General coordinator
M. Bailera (mbailera@unizar.es)
University of Zaragoza
Further information: cordis.europa.eu
[1] A review on CO2 mitigation in the Iron and Steel industry through Power to X processes. M Bailera, P Lisbona, B Peña, LM Romeo. Journal of CO2 Utilization, Volume 46, 1 April 2021, Pages 101456.
[2] CO2 recycling in the Iron and Steel Industry via Power-to-Gas and Oxy-Fuel Combustion. J Perpiñán, M Bailera, LM Romeo, B Peña, V Eveloy. Energies, Volume 14, 29 October 2021, Pages 7090.
[3] Revisiting the Rist diagram for predicting operating conditions in blast furnaces with multiple injections. M Bailera, T Nakagaki, R Kataoka. Open Research Europe, Volume 1:141, 29 November 2021.
[4] Synthetic natural gas production in a 1 kW reactor using Ni–Ce/Al2O3 and Ru–Ce/Al2O3: Kinetics, catalyst degradation and process design. M Bailera, P Lisbona, B Peña, A Alarcón, J Guilera, J Perpiñán, LM Romeo. Energy, Volume 256, 1 October 2022, Pages 124720.
[1] The global warming paradox of the colder winters
[2] Decarbonization of the industry: why electrification is not enough
[3] What is Power to Gas?
[4] How does it look a methanation plant? (laboratory at Unizar)
[5] Why the reutilization of CO2 must be smart?
[6] How does it work a Blast Furnace?
[7] Power to X routes for the decarbonization of ironmaking
[8] How does it look a blast furnace simulation? (Aspen Plus software)
This project has received funding from the European Union’s Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No 887077.