integrated assessment models
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Energy ◽  
2021 ◽  
pp. 122434
Author(s):  
Katerina Kermeli ◽  
Oreane Y. Edelenbosch ◽  
Wina Crijns-Graus ◽  
Bas J. van Ruijven ◽  
Detlef P. van Vuuren ◽  
...  

2021 ◽  
Vol 80 ◽  
pp. 102220
Author(s):  
Lukas Braunreiter ◽  
Lisette van Beek ◽  
Maarten Hajer ◽  
Detlef van Vuuren

2021 ◽  
Author(s):  
Valeria Jana Schwanitz

Integrated Assessment Models of Global Climate Change are an established tool to explore possible pathways of climate change mitigation and adaptation. The models are a quantitative backbone for IPCC reports. But can the models be trusted? This manuscript discusses how the models can be scrutinized and where limits to model validation exist.


2021 ◽  
Author(s):  
Thais Diniz Oliveira ◽  
Thierry Brunelle ◽  
Bertrand Guenet ◽  
Philippe Ciais ◽  
Florian Leblanc ◽  
...  

2021 ◽  
Vol 166 (1-2) ◽  
Author(s):  
Charlie Wilson ◽  
Céline Guivarch ◽  
Elmar Kriegler ◽  
Bas van Ruijven ◽  
Detlef P. van Vuuren ◽  
...  

AbstractProcess-based integrated assessment models (IAMs) project long-term transformation pathways in energy and land-use systems under what-if assumptions. IAM evaluation is necessary to improve the models’ usefulness as scientific tools applicable in the complex and contested domain of climate change mitigation. We contribute the first comprehensive synthesis of process-based IAM evaluation research, drawing on a wide range of examples across six different evaluation methods including historical simulations, stylised facts, and model diagnostics. For each evaluation method, we identify progress and milestones to date, and draw out lessons learnt as well as challenges remaining. We find that each evaluation method has distinctive strengths, as well as constraints on its application. We use these insights to propose a systematic evaluation framework combining multiple methods to establish the appropriateness, interpretability, credibility, and relevance of process-based IAMs as useful scientific tools for informing climate policy. We also set out a programme of evaluation research to be mainstreamed both within and outside the IAM community.


Author(s):  
Sara Giarola ◽  
Shivika Mittal ◽  
Marc Vielle ◽  
Sigit Perdana ◽  
Lorenza Campagnolo ◽  
...  

2021 ◽  
Author(s):  
Sibel Eker ◽  
Lori Siegel ◽  
Charles Jones ◽  
John Sterman ◽  
Florian Kapmeier ◽  
...  

<p>Simple climate models enable not only rapid simulation of a large number of climate scenarios, especially in connection with the integrated assessment models of economy and environment, but also provide chances for outreach and education. En-ROADS, (Energy Rapid Overview and Decision Support)[1], is a publicly available, online policy simulation model designed to complement integrated assessment models for rapid simulation of climate solutions. En-ROADS is a globally aggregated energy-economy-climate model based on a simple climate model, and supports outreach and education about the causes and effects of climate change.  It has an intuitive user interface and runs essentially instantly on ordinary laptops and tablets, providing policymakers, other leaders, educators, and the public with the ability to learn for themselves about the likely consequences of energy and climate policies and uncertainties.</p><p> </p><p>En-ROADS is a behavioral system dynamics model consisting of a system of nonlinear ordinary differential equations solved numerically from 1990-2100, with a time step of one-eighth year. En-ROADS extends the C-ROADS model, which has been used extensively by officials and policymakers around the world to inform positions of parties to the UNFCCC[2][3]. In En-ROADS’ climate module, the resulting emissions from the energy system, from forestry and land use, and carbon removal technologies, determine the atmospheric concentrations of each GHG, radiative forcing, and climate impacts including global surface temperature anomaly, heat and carbon transfer between the surface and deep ocean, sea level rise, and ocean acidification. It is calibrated to fit historical data of temperature change and carbon cycle elements, as well as the projections within the RCP-SSP framework. Both En-ROADS and C-ROADS are further developed to account for the details of the terrestrial carbon cycle.</p><p> </p><p> </p><p> </p><p> </p><div><br><div> <p>[1] https://en-roads.climateinteractive.org/scenario.html.</p> </div> <div> <p>[2] Sterman J, Fiddaman T, Franck TR, Jones A, McCauley S, Rice P, et al. Climate interactive: the C-ROADS climate policy model. System Dynamics Review 2013 <strong>28</strong> (3): 295–305</p> </div> <div> <p>[3] Sterman JD, Fiddaman T, Franck T, Jones A, McCauley S, Rice P, et al. Management flight simulators to support climate negotiations. Environmental Modelling & Software 2013, <strong>44:</strong> 122-135.</p> </div> </div>


2021 ◽  
Vol 16 (2) ◽  
pp. 411-427 ◽  
Author(s):  
Yiyi Ju ◽  
Masahiro Sugiyama ◽  
Etsushi Kato ◽  
Yuhji Matsuo ◽  
Ken Oshiro ◽  
...  

AbstractEnergy-intensive industries are difficult to decarbonize. They present a major challenge to the emerging countries that are currently in the midst of rapid industrialization and urbanization. This is also applicable to Japan, a developed economy, which retains a large presence in heavy industries compared to other developed economies. In this paper, the results obtained from four energy-economic and integrated assessment models were utilized to explore climate mitigation scenarios of Japan’s industries by 2050. The results reveal that: (i) Japan’s share of emissions from industries may increase by 2050, highlighting the difficulties in achieving industrial decarbonization under the prevailing industrial policies; (ii) the emission reduction in steelmaking will play a key role, which can be achieved by the implementation of carbon capture and expansion of hydrogen technologies after 2040; (iii) even under mitigation scenarios, electrification and the use of biomass use in Japan’s industries will continue to be limited in 2050, suggesting a low possibility of large-scale fuel switching or end-use decarbonization. After stocktaking of the current industry-sector modeling in integrated assessment models, we found that such limited uptake of cleaner fuels in the results may be related to the limited interests of both participating models and industry stakeholders in Japan, specifically the interests on the technologies that are still at the early stage of development but with high reduction potential. It is crucial to upgrade research and development activities to enable future industry-sector mitigation as well as to improve modeling capabilities of energy end-use technologies in integrated assessment models.


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