 The trend in primary energy consumption is declining in all scenarios. In 2050, the SEK reference scenario operates with a 16% drop in primary energy consumption compared with 2020, down to 1,506 PJ; the low-emission scenarios project a drop of 24% in N35 and N45 and 34% in N-opt. Compared with SEK, the low-emission scenarios envisage a significant decline in the consumption of lignite, hard coal and liquefied fossil fuels; on the other hand, they project an upswing in the consumption of biomass, biogas and other renewable sources of energy, and a slight rise in the consumption of natural gas. In the N-opt scenario, the production gap left by the decommissioned Dukovany nuclear power plant is filled mainly with renewables and natural gas.
 The total average yearly annualized not-discounted (real) costs of whole energy system are projected to grow mainly driven by capital expenditure. In the SEK scenario, the total costs are envisaged to grow by 80%, from EUR 30 billion in 2020, to EUR 53 billion in 2050. The differences in the costs between individual scenarios are not significant until 2030. In 2035-2045, the cost differences in the scenarios are influenced mainly by the decision to build new nuclear capacity. In 2050, the total costs of the low-emission scenarios N35 and N45 are EUR 2.7 billion higher compared with the SEK scenario (counting in the cost of renewal of the vehicle fleet to electric vehicles). The N-opt scenario results in generally lower costs compared with N35 and N45. N-opt, compared with SEK, predicts total costs which are EUR 2.2 billion higher in 2050.
 Discounted at the rate of 7.5% per annum, the present value of the total costs for the whole period 2020-2050 are EUR 508 billion in SEK. The total discounted costs in the low- emission scenarios N35, N45 and N-opt are EUR 2.6, EUR 0.7 and EUR 0.6 billion higher, respectively, than SEK, which is only a marginal difference of 0.1-0.5% compared to the costs of the reference case.
 Reducing CO2 emissions leads also to a reduction of other pollutants, which has a positive impact on the quality of air. The presented paper evaluates these ancillary effects of climate change mitigation policies. We focus mainly on the effects of SO2, NOx and particulate matter emissions which are the product of energy conversion. The application of ExternE methodology, specifically the impact pathway analysis, allows us to quantify the negative effects of air pollution on human health and on the environment, which emerge in the different policy scenarios we consider in our paper. The external costs are significant: EUR 31 billion for the whole period 2020-2050, which corresponds to approximately 17% of the GDP in 2015. The costs progressively decline over time, also in the reference scenario which describes the policy measures adopted in the State Energy Policy (MPO 2015b). In the SEK scenario, external costs attributable to air pollution go down from EUR 1,082 million in 2020 to EUR 659 million in 2050. All low-emission scenarios (operating with a reduction of 80% GHG) will help mitigate negative impacts on human health and on the environment, despite the fact that the scenarios envisage a higher volume of electricity generation, to satisfy the higher demand driven by e-mobility. The technology mix used to generate electricity will be a major factor influencing the degree of negative externalities. External costs of the scenario which does not operate with any development of the nuclear capacity (N-opt) are EUR 357 million lower for the whole period 2020-2050 compared with SEK, while the scenarios which calculate with new nuclear generation capacity (N35 and N45) have even lower external costs – by EUR 1,449 million compared with SEK. This comparison does not account for the benefits of reducing external costs in transport by replacing fossil fuels with electricity for powering vehicles, and the external costs of the nuclear energy, which fall sharply, in particular in the N-opt scenario.
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