The IPCC AR4 WG3 did not adequately describe the reasons for these wide ranges of mitigation potentials and costs due to space constraints. With regard to the range of carbon prices, Table 11.3 in the IPCC AR4 focuses on carbon prices under 100 US $/tCO2 eq, Capmatinib which is within the scope of the current trend of the carbon market. For
example, the European Unit of Accounting (EUA) price of the European Union Emissions Trading Scheme (EU-ETS) and the Certified Emission Reduction (CER) price for Clean Development Mechanism (CDM) projects vary around 15–30 €/tCO2 eq and 10–20 €/tCO2 eq, respectively, and the value of penalty charges in the EU-ETS market is at 100 €/tCO2 eq. However, transitions toward a low-carbon society are not an extension of the current trends and much greater GHG reductions than the current rate are required in the mid-term on a global scale (Rogelj et al. 2011; IEA 2010). It is also worth analyzing mitigation potentials at carbon prices higher than 100 US $/tCO2 eq. Therefore, this comparison study focuses on technological mitigation potentials up to the carbon price at 200 US $/tCO2 eq, which is close
to double the price of penalty charges at 100 €/tCO2 eq in the EU-ETS market. Moreover, Tables 11.3 and 11.4 in the IPCC AR4 show mitigation potentials only on a global scale and not on a detailed regional scale. Accordingly, this comparison study focuses on results of MAC curves from 0 to 200 US $/tCO2 eq in a more detailed country or region than the IPCC AR4 WG3, and provides comprehensive analysis to show the wide range of comparison results. Comparison design XMU-MP-1 supplier on mitigation potentials and costs Characteristics of the bottom-up approach This comparison study focuses on the results of mitigation potentials and costs using energy-engineering bottom-up models for multi-regions and multi-sectors. The most characteristic aspect of the bottom-up approach
is that it deals with distinct and detailed technology information such as the costs of technologies, energy efficiency of technologies, the C646 diffusion Adenosine triphosphate rate of technologies, at regional and sectoral levels. The bottom-up analysis has two different approaches: an accounting approach that accumulates mitigation options compared to the baseline scenario, and a cost optimization approach that minimizes the total system costs. One of the advantages of the bottom-up approach is that the technological feasibility of GHG emission reductions is identified explicitly by mitigation options. However, in the bottom-up analysis it is difficult to take into account the spillover effects of the introduction of mitigation measures (Edenhofer et al. 2006), such as changes in industrial structure, service demand, technology costs and energy prices. Consequently, it is not possible to analyze its economic impacts (Akashi and Hanaoka 2012; Wagner et al. 2012; Akimoto et al. 2012).