Your search keyword '"Sognnaes, I."' showing total 14 results

1. Energy and socioeconomic system transformation through a decade of IPCC-assessed scenarios

Author

van de Ven, D. J., Mittal, S., Nikas, A., Xexakis, G., Gambhir, A., Hermwille, L., Fragkos, P., Obergassel, W., Gonzalez-Eguino, M., Filippidou, F., Sognnaes, I., Clarke, L., and Peters, G. P.

Published

2025

2. Macroeconomic impact of stranded fossil fuel assets

Author

Mercure, J.-F., Pollitt, H., Viñuales, J. E., Edwards, N. R., Holden, P. B., Chewpreecha, U., Salas, P., Sognnaes, I., Lam, A., and Knobloch, F.

Published

2018

3. A multimodel analysis of post-Glasgow climate targets and feasibility challenges

Author

van de Ven, D.-J., Mittal, S., Gambhir, A., Lamboll, R.D., Doukas, H., Giarola, S., Hawkes, A., Koasidis, K., Köberle, A.C., McJeon, H., Perdana, S., Peters, G.P., Rogelj, J., Sognnaes, I., Vielle, M., Nikas, A., van de Ven, D.-J., Mittal, S., Gambhir, A., Lamboll, R.D., Doukas, H., Giarola, S., Hawkes, A., Koasidis, K., Köberle, A.C., McJeon, H., Perdana, S., Peters, G.P., Rogelj, J., Sognnaes, I., Vielle, M., and Nikas, A.

Abstract

The COP26 Glasgow process resulted in many countries strengthening their 2030 emissions reduction targets and announcing net-zero pledges for 2050–2070 but it is not clear how this would impact future warming. Here, we use four diverse integrated assessment models (IAMs) to assess CO2 emission trajectories in the near- and long-term on the basis of national policies and pledges, combined with a non-CO2 infilling model and a simple climate model to assess the temperature implications. We also consider the feasibility of national long-term pledges towards net-zero. While near-term pledges alone lead to warming above 2 °C, the addition of long-term pledges leads to emissions trajectories compatible with a future well below 2 °C, across all four IAMs. However, while IAM heterogeneity translates to diverse decarbonization pathways towards long-term targets, all modelled pathways indicate several feasibility concerns, relating to the cost of mitigation and the rates and scales of deployed technologies and measures.

Published

2023

4. A multimodel analysis of post-Glasgow climate targets and feasibility challenges

Author

van de Ven, D.J., Mittal, S., Gambhir, A., Lamboll, R.D., Doukas, H., Giarola, S., Hawkes, A., Koasidis, K., Köberle, A.C., McJeon, H., Perdana, S., Peters, G.P., Rogelj, J., Sognnaes, I., Vielle, M., Nikas, A., van de Ven, D.J., Mittal, S., Gambhir, A., Lamboll, R.D., Doukas, H., Giarola, S., Hawkes, A., Koasidis, K., Köberle, A.C., McJeon, H., Perdana, S., Peters, G.P., Rogelj, J., Sognnaes, I., Vielle, M., and Nikas, A.

Abstract

The COP26 Glasgow process resulted in many countries strengthening their 2030 emissions reduction targets and announcing net-zero pledges for 2050–2070 but it is not clear how this would impact future warming. Here, we use four diverse integrated assessment models (IAMs) to assess CO2 emission trajectories in the near- and long-term on the basis of national policies and pledges, combined with a non-CO2 infilling model and a simple climate model to assess the temperature implications. We also consider the feasibility of national long-term pledges towards net-zero. While near-term pledges alone lead to warming above 2 °C, the addition of long-term pledges leads to emissions trajectories compatible with a future well below 2 °C, across all four IAMs. However, while IAM heterogeneity translates to diverse decarbonization pathways towards long-term targets, all modelled pathways indicate several feasibility concerns, relating to the cost of mitigation and the rates and scales of deployed technologies and measures. © 2023, The Author(s), under exclusive licence to Springer Nature Limited.

Published

2023

5. A multi-model analysis of long-term emissions and warming implications of current mitigation efforts

Author

Sognnaes, I., Gambhir, A., van de Ven, D.-J., Nikas, A., Anger-Kraavi, A., Bui, H., Campagnolo, L., Delpiazzo, E., Doukas, H., Giarola, S., Grant, N., Hawkes, A., Köberle, A.C., Kolpakov, A., Mittal, S., Moreno, J., Perdana, S., Rogelj, J., Vielle, M., Peters, G.P., Sognnaes, I., Gambhir, A., van de Ven, D.-J., Nikas, A., Anger-Kraavi, A., Bui, H., Campagnolo, L., Delpiazzo, E., Doukas, H., Giarola, S., Grant, N., Hawkes, A., Köberle, A.C., Kolpakov, A., Mittal, S., Moreno, J., Perdana, S., Rogelj, J., Vielle, M., and Peters, G.P.

Abstract

Most of the integrated assessment modelling literature focuses on cost-effective pathways towards given temperature goals. Conversely, using seven diverse integrated assessment models, we project global energy CO2 emissions trajectories on the basis of near-term mitigation efforts and two assumptions on how these efforts continue post-2030. Despite finding a wide range of emissions by 2050, nearly all the scenarios have median warming of less than 3 °C in 2100. However, the most optimistic scenario is still insufficient to limit global warming to 2 °C. We furthermore highlight key modelling choices inherent to projecting where emissions are headed. First, emissions are more sensitive to the choice of integrated assessment model than to the assumed mitigation effort, highlighting the importance of heterogeneous model intercomparisons. Differences across models reflect diversity in baseline assumptions and impacts of near-term mitigation efforts. Second, the common practice of using economy-wide carbon prices to represent policy exaggerates carbon capture and storage use compared with explicitly modelling policies.

Published

2021

6. Perspective of comprehensive and comprehensible multi-model energy and climate science in Europe

Author

Nikas, A., Gambhir, A., Trutnevyte, E., Koasidis, K., Lund, H., Thellufsen, J.Z., Mayer, D., Zachmann, G., Miguel, L.J., Ferreras-Alonso, N., Sognnaes, I., Peters, G.P., Colombo, E., Howells, M., Hawkes, A., van den Broek, M., Van de Ven, D.J., Gonzalez-Eguino, M., Flamos, A., Doukas, H., Nikas, A., Gambhir, A., Trutnevyte, E., Koasidis, K., Lund, H., Thellufsen, J.Z., Mayer, D., Zachmann, G., Miguel, L.J., Ferreras-Alonso, N., Sognnaes, I., Peters, G.P., Colombo, E., Howells, M., Hawkes, A., van den Broek, M., Van de Ven, D.J., Gonzalez-Eguino, M., Flamos, A., and Doukas, H.

Abstract

Europe’s capacity to explore the envisaged pathways that achieve its near- and long-term energy and climate objectives needs to be significantly enhanced. In this perspective, we discuss how this capacity is supported by energy and climate-economy models, and how international modelling teams are organised within structured communication channels and consortia as well as coordinate multi-model analyses to provide robust scientific evidence. Noting the lack of such a dedicated channel for the highly active yet currently fragmented European modelling landscape, we highlight the importance of transparency of modelling capabilities and processes, harmonisation of modelling parameters, disclosure of input and output datasets, interlinkages among models of different geographic granularity, and employment of models that transcend the highly harmonised core of tools used in model inter-comparisons. Finally, drawing from the COVID-19 pandemic, we discuss the need to expand the modelling comfort zone, by exploring extreme scenarios, disruptive innovations, and questions that transcend the energy and climate goals across the sustainability spectrum. A comprehensive and comprehensible multi-model framework offers a real example of “collective” science diplomacy, as an instrument to further support the ambitious goals of the EU Green Deal, in compliance with the EU claim to responsible research.

Published

2021

7. Challenges in the harmonisation of global integrated assessment models: A comprehensive methodology to reduce model response heterogeneity

Author

Giarola, S., Mittal, S., Vielle, M., Perdana, S., Campagnolo, L., Delpiazzo, E., Bui, H., Kraavi, A.A., Kolpakov, A., Sognnaes, I., Peters, G., Hawkes, A., Köberle, A.C., Grant, N., Gambhir, A., Nikas, A., Doukas, H., Moreno, J., van de Ven, D.-J., Giarola, S., Mittal, S., Vielle, M., Perdana, S., Campagnolo, L., Delpiazzo, E., Bui, H., Kraavi, A.A., Kolpakov, A., Sognnaes, I., Peters, G., Hawkes, A., Köberle, A.C., Grant, N., Gambhir, A., Nikas, A., Doukas, H., Moreno, J., and van de Ven, D.-J.

Abstract

Harmonisation sets the ground to a solid inter-comparison of integrated assessment models. A clear and transparent harmonisation process promotes a consistent interpretation of the modelling outcomes divergences and, reducing the model variance, is instrumental to the use of integrated assessment models to support policy decision-making. Despite its crucial role for climate economic policies, the definition of a comprehensive harmonisation methodology for integrated assessment modelling remains an open challenge for the scientific community. This paper proposes a framework for a harmonisation methodology with the definition of indispensable steps and recommendations to overcome stumbling blocks in order to reduce the variance of the outcomes which depends on controllable modelling assumptions. The harmonisation approach of the PARIS REINFORCE project is presented here to layout such a framework. A decomposition analysis of the harmonisation process is shown through 6 integrated assessment models (GCAM, ICES-XPS, MUSE, E3ME, GEMINI-E3, and TIAM). Results prove the potentials of the proposed framework to reduce the model variance and present a powerful diagnostic tool to feedback on the quality of the harmonisation itself. © 2021

Published

2021

8. Where is the EU headed given its current climate policy? A stakeholder-driven model inter-comparison

Author

Nikas, A., Elia, A., Boitier, B., Koasidis, K., Doukas, H., Cassetti, G., Anger-Kraavi, A., Campagnolo, L., Bui, H., De Miglio, R., Delpiazzo, E., Fougeyrollas, A., Gambhir, A., Gargiulo, M., Giarola, S., Grant, N., Hawkes, A., Herbst, A., Köberle, A. C., Kolpakov, A., Le Mouël, P., McWilliams, B., Mittal, S., Neuner, F., Moreno, J., Perdana, S., Plötz, P., Peters, G. P., Rogelj, J., Sognnæs, I., Van de Ven, D. J., Vielle, M., Zachmann, G., Zagamé, P., Chiodi, A., Nikas, A., Elia, A., Boitier, B., Koasidis, K., Doukas, H., Cassetti, G., Anger-Kraavi, A., Campagnolo, L., Bui, H., De Miglio, R., Delpiazzo, E., Fougeyrollas, A., Gambhir, A., Gargiulo, M., Giarola, S., Grant, N., Hawkes, A., Herbst, A., Köberle, A. C., Kolpakov, A., Le Mouël, P., McWilliams, B., Mittal, S., Neuner, F., Moreno, J., Perdana, S., Plötz, P., Peters, G. P., Rogelj, J., Sognnæs, I., Van de Ven, D. J., Vielle, M., Zachmann, G., Zagamé, P., and Chiodi, A.

Abstract

Recent calls to do climate policy research with, rather than for, stakeholders have been answered in non-modelling science. Notwithstanding progress in modelling literature, however, very little of the scenario space traces back to what stakeholders are ultimately concerned about. With a suite of eleven integrated assessment, energy system and sectoral models, we carry out a model inter-comparison for the EU, the scenario logic and research questions of which have been formulated based on stakeholders' concerns. The output of this process is a scenario framework exploring where the region is headed rather than how to achieve its goals, extrapolating its current policy efforts into the future. We find that Europe is currently on track to overperforming its pre-2020 40% target yet far from its newest ambition of 55% emissions cuts by 2030, as well as looking at a 1.0 2.35 GtCO2 emissions range in 2050. Aside from the importance of transport electrification, deployment levels of carbon capture and storage are found intertwined with deeper emissions cuts and with hydrogen diffusion, with most hydrogen produced post-2040 being blue. Finally, the multi-model exercise has highlighted benefits from deeper decarbonisation in terms of energy security and jobs, and moderate to high renewables-dominated investment needs. © 2021 The Authors

Published

2021

9. The Impact of U.S. Re-engagement in Climate on the Paris Targets

Author

van de Ven, D.J., Westphal, M., González-Eguino, M., Gambhir, A., Peters, G., Sognnaes, I., McJeon, H., Hultman, N., Kennedy, K., Cyrs, T., Clarke, L., van de Ven, D.J., Westphal, M., González-Eguino, M., Gambhir, A., Peters, G., Sognnaes, I., McJeon, H., Hultman, N., Kennedy, K., Cyrs, T., and Clarke, L.

Abstract

The Paris Agreement seeks to combine international efforts to keep global temperature increase to well-below 2°C. Whilst current ambitions in many signatories are insufficient to achieve this goal, optimism prevailed in the second half of 2020. Not only did several major emitters announce net-zero mitigation targets around mid-century, but the new Biden Administration immediately announced the U.S.’s re-entry into Paris and a net-zero goal for 2050. U.S. federal re-engagement in climate action could have a considerable impact on its national greenhouse gas emissions pathway, by significantly augmenting existing state-level actions. Combined with U.S. re-entry in the Paris Agreement, this could also serve as a stimulus to enhance ambitions in other countries. A critical question then becomes what such U.S. re-engagement, through both national and international channels, would have on the global picture. This commentary explores precisely this question, by using an integrated assessment model to assess U.S. national emissions, global emissions, and end-of-century temperatures in five scenarios combining different climate ambition levels in both the U.S. and the rest of the world. Our analyses finds that ambitious climate leadership by the Biden Administration on top of enhanced climate commitments by other the major economies could potentially be the trigger for the world to fulfill the temperature goal of the Paris Agreement. © 2021. The Authors. Earth's Future published by Wiley Periodicals LLC on behalf of American Geophysical Union.

Published

2021

10. Perspective of comprehensive and comprehensible multi-model energy and climate science in Europe

Author

Nikas, A., primary, Gambhir, A., additional, Trutnevyte, E., additional, Koasidis, K., additional, Lund, H., additional, Thellufsen, J.Z., additional, Mayer, D., additional, Zachmann, G., additional, Miguel, L.J., additional, Ferreras-Alonso, N., additional, Sognnaes, I., additional, Peters, G.P., additional, Colombo, E., additional, Howells, M., additional, Hawkes, A., additional, van den Broek, M., additional, Van de Ven, D.J., additional, Gonzalez-Eguino, M., additional, Flamos, A., additional, and Doukas, H., additional

Published

2021

11. Systems Innovation, Inertia and Pliability: A mathematical exploration with implications for climate change abatement

Author

Grubb, M., Mercure, J., Salas, P., Lange, R., and Sognnaes, I.

Subjects

endogenous technological change, inertia, Innovation, energy systems, learning by doing, path dependence, climate change abatement

Abstract

This paper develops a stylised mathematical interpretation of innovation and inertia in economic systems, characteristics which feature in economics literature traceable back at least to Schumpeter and other economic theorists of innovation, as well as economic historians. Such characteristics are particularly important in energy systems and their potential response to climate change, where it is important to distinguish operational/fuel substitution from investment because the latter necessarily embodies both inertia and innovation, in systems as well as technologies. We argue that integrated assessments of climate abatement need to focus on investment, including the associated characteristics of both learning and inertia, and derive in detail the mathematical basis for incorporating these factors through marginal investment cost curves. From this we also introduce the concept of �pliability� as an expression of the ratio between costs which are significant but transitional (including learning investments, infrastructure and overcoming inertia), as compared to the enduring costs implied by purely exogenous technology assumptions. We then incorporate these features in a global model of optimal climate mitigation and show that they can generate a very different profile and pattern of results from traditional �integrated assessment� models, pinpointing the key sensitivities. We conclude that alongside all the attention devoted to evaluating climate change impacts and technology scenarios, far more effort should be devoted to understanding the structural characteristics of how the global energy system may respond to climate change mitigation.

Published

2018

12. Mean square flux noise in SQUIDs and qubits: numerical calculations

Author

Anton, S M, primary, Sognnaes, I A B, additional, Birenbaum, J S, additional, O’Kelley, S R, additional, Fourie, C J, additional, and Clarke, John, additional

Published

2013

13. Where is the EU headed given its current climate policy? A stakeholder-driven model inter-comparison.

Author

Nikas A, Elia A, Boitier B, Koasidis K, Doukas H, Cassetti G, Anger-Kraavi A, Bui H, Campagnolo L, De Miglio R, Delpiazzo E, Fougeyrollas A, Gambhir A, Gargiulo M, Giarola S, Grant N, Hawkes A, Herbst A, Köberle AC, Kolpakov A, Le Mouël P, McWilliams B, Mittal S, Moreno J, Neuner F, Perdana S, Peters GP, Plötz P, Rogelj J, Sognnæs I, Van de Ven DJ, Vielle M, Zachmann G, Zagamé P, and Chiodi A

Subjects

Carbon, Carbon Dioxide, Climate, Climate Change, Policy

Abstract

Recent calls to do climate policy research with, rather than for, stakeholders have been answered in non-modelling science. Notwithstanding progress in modelling literature, however, very little of the scenario space traces back to what stakeholders are ultimately concerned about. With a suite of eleven integrated assessment, energy system and sectoral models, we carry out a model inter-comparison for the EU, the scenario logic and research questions of which have been formulated based on stakeholders' concerns. The output of this process is a scenario framework exploring where the region is headed rather than how to achieve its goals, extrapolating its current policy efforts into the future. We find that Europe is currently on track to overperforming its pre-2020 40% target yet far from its newest ambition of 55% emissions cuts by 2030, as well as looking at a 1.0-2.35 GtCO 2 emissions range in 2050. Aside from the importance of transport electrification, deployment levels of carbon capture and storage are found intertwined with deeper emissions cuts and with hydrogen diffusion, with most hydrogen produced post-2040 being blue. Finally, the multi-model exercise has highlighted benefits from deeper decarbonisation in terms of energy security and jobs, and moderate to high renewables-dominated investment needs., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2021 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2021

14. Challenges in the harmonisation of global integrated assessment models: A comprehensive methodology to reduce model response heterogeneity.

Author

Giarola S, Mittal S, Vielle M, Perdana S, Campagnolo L, Delpiazzo E, Bui H, Kraavi AA, Kolpakov A, Sognnaes I, Peters G, Hawkes A, Köberle AC, Grant N, Gambhir A, Nikas A, Doukas H, Moreno J, and van de Ven DJ

Abstract

Harmonisation sets the ground to a solid inter-comparison of integrated assessment models. A clear and transparent harmonisation process promotes a consistent interpretation of the modelling outcomes divergences and, reducing the model variance, is instrumental to the use of integrated assessment models to support policy decision-making. Despite its crucial role for climate economic policies, the definition of a comprehensive harmonisation methodology for integrated assessment modelling remains an open challenge for the scientific community. This paper proposes a framework for a harmonisation methodology with the definition of indispensable steps and recommendations to overcome stumbling blocks in order to reduce the variance of the outcomes which depends on controllable modelling assumptions. The harmonisation approach of the PARIS REINFORCE project is presented here to layout such a framework. A decomposition analysis of the harmonisation process is shown through 6 integrated assessment models (GCAM, ICES-XPS, MUSE, E3ME, GEMINI-E3, and TIAM). Results prove the potentials of the proposed framework to reduce the model variance and present a powerful diagnostic tool to feedback on the quality of the harmonisation itself., Competing Interests: Declaration of competing interest We have no conflicts of interest to disclose., (Copyright © 2021 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2021