380.256 PEOPLE
| People | Locations | Statistics |
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| Seuring, Stefan |
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| Nor Azizi, S. |
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| Pato, Margarida Vaz |
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| Kölker, Katrin |
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| Huber, Oliver |
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| Király, Tamás |
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| Spengler, Thomas Stefan |
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| Al-Ammar, Essam A. |
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| Dargahi, Fatemeh |
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| Mota, Rui |
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| Mazalan, Nurul Aliah Amirah |
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| Macharis, Cathy | Brussels |
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| Arunasari, Yova Tri |
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| Nunez, Alfredo | Delft |
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| Bouhorma, Mohammed |
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| Bonato, Matteo |
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| Fitriani, Ira |
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| Autor Correspondente Coelho, Sílvia. |
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| Pond, Stephen |
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| Okwara, Ukoha Kalu |
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| Toufigh, Vahid |
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| Campisi, Tiziana | Enna |
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| Ermolieva, Tatiana |
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| Sánchez-Cambronero, Santos |
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| Agzamov, Akhror |
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Dietmüller, Simone
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (25/25 displayed)
- 2024Decision-making strategies implemented in SolFinder 1.0 to identify eco-efficient aircraft trajectories: application study in AirTraf 3.0
- 2024Update of Climate Change Functions and comparison with algorithmic Climate Change Functions
- 2023Updated algorithmic climate change functions (aCCF) V1.0A: Evaluation with the climate-response model AirClim V2.0citations
- 2023Decision-making strategies implemented in SolFinder 1.0 to identify eco-efficient aircraft trajectories: application study in AirTraf 3.0citations
- 2023Supplementary material to "Decision-making strategies implemented in SolFinder 1.0 to identify eco-efficient aircraft trajectories: application study in AirTraf 3.0"
- 2023Predicting the climate impact of aviation for en-route emissions: the algorithmic climate change function submodel ACCF 1.0 of EMAC 2.53citations
- 2023Robust 4D Climate Optimal Flight Planning in Structured Airspace using Parallelized Simulation on GPUs: ROOST V1.0citations
- 2023Robust 4D climate-optimal flight planning in structured airspace using parallelized simulation on GPUs: ROOST V1.0citations
- 2023A Python library for computing individual and merged non-CO2 algorithmic climate change functionscitations
- 2022FlyATM4E - Mitigating aviation climate impact by climate-optimized aircraft trajectories
- 2022A Comprehensive Survey on Climate Optimal Aircraft Trajectory Planningcitations
- 2022Decrease of anthropogenic emission from aviation and detection of natural hazards with potential application in geosciences using satellite sensors, ground-based networks and model forecasts in the context of the SACS/ALARM early warning system
- 2022MITIGATION OF AVIATION’S CLIMATE IMPACT THROUGH ROBUST CLIMATE OPTIMIZED TRAJECTORIES IN INTRA-EUROPEAN AIRSPACE
- 2022Quantifying the spatial and temporal non-CO2 effect of aviation by using algorithmic climate change functions
- 2022Predicting the climate impact of aviation for en-route emissions: The algorithmic climate change function submodel ACCF 1.0 of EMAC 2.53citations
- 2022Robust climate-optimized flight planning of intra-European flights considering meteorological uncertainties
- 2022Supplementary material to "Predicting the climate impact of aviation for en-route emissions: The algorithmic climate change function submodel ACCF 1.0 of EMAC 2.53"
- 2022MITIGATION OF AVIATIONS CLIMATE IMPACT THROUGH ROBUST CLIMATE OPTIMIZED TRAJECTORIES IN INTRA-EUROPEAN AIRSPACE
- 2021Mitigation of Non-CO2 Aviation’s Climate Impact by Changing Cruise Altitudescitations
- 2021Mitigation of Non-CO2 Aviation's Climate Impact by Changing Cruise Altitudescitations
- 2021Seasonal Variability of Aircraft Trajectories reducing NOx-climate Impacts under a Multitude of Weather Patterns
- 2016Proceedings of the 4th International Conference on Transport, Atmosphere and Climate
- 2014Aircraft routing with minimal climate impact: the REACT4C climate cost function modelling approach (V1.0)citations
- 2013Global sensitivity of aviation NOx effects to the HNO3-forming channel of the HO2+NO reactioncitations
- 2012Global sensitivity of aviation NOx effects to the HO2 + NO → HNO3 reaction
Places of action
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