Towards a new surrogate model for predicting short-term NOx-O3 effects from aviation using Gaussian processes

While efforts have been made to curb CO2 emissions from aviation, the more uncertain non-CO2 effects that contribute about two-thirds to the warming in terms of radiative forcing (RF), still require attention. The most important non-CO2 effects include persistent line-shaped contrails, contrail-indu...

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Main Authors: Rao, P.V. (author), Dwight, R.P. (author), Singh, D. (author), Maruhashi, J. (author), Dedoussi, I.C. (author), Grewe, V. (author), Frömming, Christine (author)
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Language:English
Published: 2023
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Online Access:http://resolver.tudelft.nl/uuid:63fd55cb-8d37-43ee-8230-7ccad3509291
https://doi.org/10.5194/egusphere-egu23-4337
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spelling fttudelft:oai:tudelft.nl:uuid:63fd55cb-8d37-43ee-8230-7ccad3509291 2024-02-11T10:06:41+01:00 Towards a new surrogate model for predicting short-term NOx-O3 effects from aviation using Gaussian processes Rao, P.V. (author) Dwight, R.P. (author) Singh, D. (author) Maruhashi, J. (author) Dedoussi, I.C. (author) Grewe, V. (author) Frömming, Christine (author) 2023 http://resolver.tudelft.nl/uuid:63fd55cb-8d37-43ee-8230-7ccad3509291 https://doi.org/10.5194/egusphere-egu23-4337 en eng EGU General Assembly 2023 EGU General Assembly 2023--2c813a69-dde7-44c6-9249-7ff9be3b8ec7 http://resolver.tudelft.nl/uuid:63fd55cb-8d37-43ee-8230-7ccad3509291 https://doi.org/10.5194/egusphere-egu23-4337 © 2023 P.V. Rao, R.P. Dwight, D. Singh, J. Maruhashi, I.C. Dedoussi, V. Grewe, Christine Frömming conference paper 2023 fttudelft https://doi.org/10.5194/egusphere-egu23-4337 2024-01-24T23:34:30Z While efforts have been made to curb CO2 emissions from aviation, the more uncertain non-CO2 effects that contribute about two-thirds to the warming in terms of radiative forcing (RF), still require attention. The most important non-CO2 effects include persistent line-shaped contrails, contrail-induced cirrus clouds and nitrogen oxide (NOx) emissions that alter the ozone (O3) and methane (CH4) concentrations, both of which are greenhouse gases, and the emission of water vapour (H2O). The climate impact of these non-CO2 effects depends on emission location and prevailing weather situation; thus, it can potentially be reduced by advantageous re-routing of flights using Climate Change Functions (CCFs), which are a measure for the climate effect of a locally confined aviation emission. CCFs are calculated using a modelling chain starting from the instantaneous RF (iRF) measured at the tropopause that results from aviation emissions. However, the iRF is a product of computationally intensive chemistry-climate model (EMAC) simulations and is currently restricted to a limited number of days and only to the North Atlantic Flight Corridor. This makes it impossible to run EMAC on an operational basis for global flight planning. A step in this direction lead to a surrogate model called algorithmic Climate Change Functions (aCCFs), derived by regressing CCFs (training data) against 2 or 3 local atmospheric variables at the time of emission (features) with simple regression techniques and are applicable only in parts of the Northern hemisphere. It was found that in the specific case of O3 aCCFs, which provide a reasonable first estimate for the short-term impact of aviation NOx on O3 warming using temperature and geopotential as features, can be vastly improved [1]. There is aleatoric uncertainty in the full-order model (EMAC), stemming from unknown sources (missing features) and randomness in the known features, which can introduce heteroscedasticity in the data. Deterministic surrogates (e.g. aCCFs) only predict point ... Conference Object North Atlantic Delft University of Technology: Institutional Repository
institution Open Polar
collection Delft University of Technology: Institutional Repository
op_collection_id fttudelft
language English
description While efforts have been made to curb CO2 emissions from aviation, the more uncertain non-CO2 effects that contribute about two-thirds to the warming in terms of radiative forcing (RF), still require attention. The most important non-CO2 effects include persistent line-shaped contrails, contrail-induced cirrus clouds and nitrogen oxide (NOx) emissions that alter the ozone (O3) and methane (CH4) concentrations, both of which are greenhouse gases, and the emission of water vapour (H2O). The climate impact of these non-CO2 effects depends on emission location and prevailing weather situation; thus, it can potentially be reduced by advantageous re-routing of flights using Climate Change Functions (CCFs), which are a measure for the climate effect of a locally confined aviation emission. CCFs are calculated using a modelling chain starting from the instantaneous RF (iRF) measured at the tropopause that results from aviation emissions. However, the iRF is a product of computationally intensive chemistry-climate model (EMAC) simulations and is currently restricted to a limited number of days and only to the North Atlantic Flight Corridor. This makes it impossible to run EMAC on an operational basis for global flight planning. A step in this direction lead to a surrogate model called algorithmic Climate Change Functions (aCCFs), derived by regressing CCFs (training data) against 2 or 3 local atmospheric variables at the time of emission (features) with simple regression techniques and are applicable only in parts of the Northern hemisphere. It was found that in the specific case of O3 aCCFs, which provide a reasonable first estimate for the short-term impact of aviation NOx on O3 warming using temperature and geopotential as features, can be vastly improved [1]. There is aleatoric uncertainty in the full-order model (EMAC), stemming from unknown sources (missing features) and randomness in the known features, which can introduce heteroscedasticity in the data. Deterministic surrogates (e.g. aCCFs) only predict point ...
format Conference Object
author Rao, P.V. (author)
Dwight, R.P. (author)
Singh, D. (author)
Maruhashi, J. (author)
Dedoussi, I.C. (author)
Grewe, V. (author)
Frömming, Christine (author)
spellingShingle Rao, P.V. (author)
Dwight, R.P. (author)
Singh, D. (author)
Maruhashi, J. (author)
Dedoussi, I.C. (author)
Grewe, V. (author)
Frömming, Christine (author)
Towards a new surrogate model for predicting short-term NOx-O3 effects from aviation using Gaussian processes
author_facet Rao, P.V. (author)
Dwight, R.P. (author)
Singh, D. (author)
Maruhashi, J. (author)
Dedoussi, I.C. (author)
Grewe, V. (author)
Frömming, Christine (author)
author_sort Rao, P.V. (author)
title Towards a new surrogate model for predicting short-term NOx-O3 effects from aviation using Gaussian processes
title_short Towards a new surrogate model for predicting short-term NOx-O3 effects from aviation using Gaussian processes
title_full Towards a new surrogate model for predicting short-term NOx-O3 effects from aviation using Gaussian processes
title_fullStr Towards a new surrogate model for predicting short-term NOx-O3 effects from aviation using Gaussian processes
title_full_unstemmed Towards a new surrogate model for predicting short-term NOx-O3 effects from aviation using Gaussian processes
title_sort towards a new surrogate model for predicting short-term nox-o3 effects from aviation using gaussian processes
publishDate 2023
url http://resolver.tudelft.nl/uuid:63fd55cb-8d37-43ee-8230-7ccad3509291
https://doi.org/10.5194/egusphere-egu23-4337
genre North Atlantic
genre_facet North Atlantic
op_relation EGU General Assembly 2023
EGU General Assembly 2023--2c813a69-dde7-44c6-9249-7ff9be3b8ec7
http://resolver.tudelft.nl/uuid:63fd55cb-8d37-43ee-8230-7ccad3509291
https://doi.org/10.5194/egusphere-egu23-4337
op_rights © 2023 P.V. Rao, R.P. Dwight, D. Singh, J. Maruhashi, I.C. Dedoussi, V. Grewe, Christine Frömming
op_doi https://doi.org/10.5194/egusphere-egu23-4337
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