Introduction

Background

Under the Paris Agreement, Japan pledged to reduce its greenhouse gas (GHG) emissions by 26% by 2030 from the 2013 levels and cut emissions by 80% by 2050 (Government of Japan 2019). As of 2018, the GHG emissions stood at 1240 Mt-CO2e, and around 50% were direct emissions from the demand-side (Industry 25%, Residential 5%, Commercial 5%, and Transportation 18%) (Ministry of the Environment 2020).

The power sector is going through a major reform in Japan, and a rapid deployment of renewable energy has been contributing to supply-side decarbonization. In parallel with supply-side actions, it is also crucial to promote demand-side decarbonization (Luderer et al. 2018; Duscha et al. 2019). Sugiyama et al. (2019) shows that the demand-side, especially the industry sector, has the difficulty of achieving emissions reductions in Japan's energy system.

Energy efficiency improvements are the first and useful contributions in reducing emissions (Fujimori et al. 2014; Sugiyama et al. 2014; Wakiyama and Kuramochi 2017), but switching the demand-side to clean energy carriers (electricity, hydrogen, and bioenergy) is equally important (Deep Decarbonization Pathways Project 2015; Ozawa et al. 2018; Matsuo et al. 2018; Gambhir et al. 2019; Wachsmuth and Duscha 2019). In fact, the Government of Japan has introduced electrification as one of the key policy areas along with increasing use of bioenergy and hydrogen (Government of Japan 2019).

Notably, among clean energy carriers, numerous studies show that a transition to electricity by the demand-side plays a pivotal role in large-scale CO2 reduction of all demand sectors on a global, national and urban scale (Sugiyama 2012; Williams et al. 2012; Wei et al. 2013, Intergovernmental Panel on Climate Change (IPCC) 2014; Quiggin and Buswell 2016; Raghavan et al. 2017; IPCC 2018; Fortes et al. 2019; Hill et al. 2019; Luh et al. 2020; Zhang and Fujimori 2020).

Electrification has been incorporated in Japan’s long-term energy plans. The long-term low-carbon vision (Ministry of the Environment 2016), an input from the Ministry of the Environment to the policy debate on the long-term strategy, listed electrification, including a switch from combustion-engine vehicles to electric vehicles and diffusion of heat pumps for space and water heating, as one of the three pillars to achieve low-carbon society in Japan. The 2019 long-term strategy submitted by Japan to the United Nations Framework Convention on Climate Change also emphasizes the need to increase electrification rates for 2050.

In contrast to the policy directions, there are only a few concrete policies on electrification and most of them have been subsidies or RD&D projects (Government of Japan 2019). One can contrast this with more drastic measures such as a ban on ICE cars in the United Kingdom (Government of UK 2017) and a proposal of a ban on the use of natural gas in the buildings (Deason and Borgeson 2019) in the west coast of the United States of America.

Research questions and aims

As mentioned above, while Japan’s Nationally Determined Contribution (NDC) proposes an increasing share of electricity in 2030, Japan’s mid-century strategy lacks a concrete level of electrification. The low-carbon vision from the Ministry of Environment and Japan’s long-term strategy also do not reveal quantitative electrification pathways through 2050. Therefore; this study examines 2050 low-carbon scenarios more concretely, with a focus on electrification pathways.

There are two dimensions that deserve detailed examination.

First, how high and fast should the share of electricity increase in the midst of competition from other clean energy carriers? Where and how much electrification contributes to mitigation needs to be assessed, as electricity is not the only clean energy carrier, and the role of electricity would be different by sectors. Oshiro et al. (2017) shows that for Japan to achieve an 80% emissions reduction in 2050, it is necessary to accelerate the pace of electrification and reach the electrification rate of 45% in 2050. However, the long-term energy demand and supply outlook by the Ministry of Economy, Trade and Industry (hereinafter called METI outlook), which is consistent with Japan’s NDC, shows the share of electricity in final energy (electrification rate) in 2030 to be 29%, a mere 3% increase from 2013.

Second, would decarbonization increase the total demand for electricity? Increasing the electrification rate and decreasing the fossil fuel consumption is an effective way to reducing demand-side emissions. However, increasing the electrification rate does not automatically increase its absolute demand. Sugiyama (2012) reviewed global decarbonization pathways and found the electrification rate to increase with more stringent emissions targets, but the absolute demand of electricity did not always increase.

These two aspects are both dependent on a number of scenario assumptions as well as models. This study employs the multi-model analytic framework of Energy Modeling Forum (EMF) 35 Japan Model Intercomparison Project (JMIP) and characterizes future electrification pathways for Japan to achieve the long-term emissions reduction goals. In particular, the present paper takes advantage of a framework that includes various power supply technologies scenarios.

Oshiro et al. (2019) is a notable study in a multi-model framework which focused on a Japan’s in-depth decarbonization scenario. Although the study shows the share of clean energy carriers grows in final energy use, electrification pace, supply-side technology uncertainty, nor the total demand for electricity are analyzed. The present study attempts to fill the gap by finding a common pattern among results of multiple models of different types to draw a general conclusion related to the role of electricity in decarbonizing the demand sector of Japan.

Methods

Model description

This study employs scenarios from five energy-economic and integrated assessment models: AIM/Enduse-Japan (Oshiro and Masui 2015; Fujimori et al. 2019; Kainuma et al. 2003), AIM/Hub-Japan (Fujimori et al. 2017a, b, c; Silva et al. 2019), DNE21 (Hosoya and Fujii 2011; Fujii and Komiyama 2015), IEEJ_Japan 2017 (Matsuo et al. 2013, 2020), and TIMES-Japan (Kato and Kurosawa 2019; Kurosawa and Hagiwara 2012; Loulou et al. 2005; Sato 2005). Hereafter, each model is called AIM/Enduse, AIM/Hub, DNE21, IEEJ, and TIMES-Japan. AIM/Enduse and AIM/Hub are recursive dynamic models. The former is a typical energy system model that minimizes total energy system cost considering numerous detailed technological representation in both energy supply and demand sectors, and the latter is a general equilibrium model with relatively aggregated technological resolution but can consider the macroeconomic responses considering the sectoral input–output changes in detail. DNE21, IEEJ and TIMES-Japan are perfect foresight models. Only AIM/Hub is a general equilibrium model, and others are partial equilibrium models.

Since energy demand representation is much more heterogeneous across models than supply-side structures, it is favorable to have an overview of the decomposition of sectors and the inclusion of different final energy carriers. The reason for different model behaviors could be attributable to which final energy carrier is explicitly represented.

Table 1 clarifies final energy carriers by sectors reported by the participating models. Electricity is included in all models while hydrogen is represented in AIM/Enduse, IEEJ, and TIMES-Japan. Some models do not report biomass-related carrier (solids biomass, biofuels, and biogas) separately. These carriers are reported in an aggregated manner and included in the corresponded carriers (solids, liquids, and gases). Note that DNE21 does not explicitly represent energy services by sectors; instead, their demands are represented as fuel demands. Also, AIM/Hub does not represent energy services, yet fuel demands are represented for each sector. Detailed end-use technologies by models are shown in ESM (Table ESM1 to 4). The more detailed model descriptions are provided in Sugiyama et al. (2021).

Table 1 Final energy carriers reported by each model

Scenarios

We briefly describe the salient aspects of the scenarios that are analyzed in this paper (see Sugiyama et al. 2021 for fuller descriptions).

The central scenario is a mitigation scenario that is consistent with the NDC and mid-century strategyFootnote 1 (26by30 + 80by50_Def). The “Baseline” scenario is a scenario with no climate policy.

We also consider an extensive list of sensitivity runs on variable renewables (VREs) and nuclear generation. It is now well established that the power sector needs to go through almost a complete decarbonization in the long run (IPCC 2014, 2018). Cheap clean electricity makes electrification economically competitive, and can further promote demand-side electrification (Zhang et al. 2012). However, the availability of affordable clean electricity depends on multiple technological parameters. It is therefore useful to examine the impact of supply-side sensitivities on demand-side electrification.

The JMIP study also explores a scenario regarding the availability of Carbon Capture and Storage (CCS) in addition to VREs and nuclear power generation technology. Since CCS can be deployed both in the power generation sector and the industry sector, it can be a crucial technology to decrease demand-side emissions.

This paper considers the following scenarios:

  • 26by30 + 80by50_LoVREcost: halving the costs of VREs;

  • 26by30 + 80by50_HiVREcost: doubling the costs of VREs;

  • 26by30 + 80by50_LoVREpot: Resource potential for wind and solar halved for 2020 and onwards;

  • 26by30 + 80by50_HiVREpot: Resource potential for wind and solar doubled for 2020 and onwards; and

  • 26by30 + 80by50_NoNuc: nuclear power is completely unavailable.

  • 26by30 + 80by50_NoCCS: CCS is completely unavailable.

In the 26by30 + 80by50_LoVREcost, VRE’s capital cost was halved compared to 26by30 + 80by50_Def, but the models did not harmonize the timing of the cost change. Hereafter, the scenario prefix “26by30 + 80by50_” is dropped for sensitivity scenarios in this paper for brevity in reporting.

We also examine different levels of emissions constraints. More stringent emissions constraint should accelerate demand-side decarbonization, resulting in higher clean energy carrier shares or electrification rates (Fortes et al. 2019). Targeting 2050, we consider 70%, 80%, 90%, and 100% emission reduction levels to understand the impacts of climate policies. In addition to 26by30 + 80by50_Def, we explore following scenarios:

  • 26by30 + 70by50_Def;

  • 26by30 + 90by50_Def; and

  • 26by30 + 100by50_Def.

In the JMIP study, not all participating models have 90% and 100% CO2 emissions reduction scenarios in 2050. In AIM/Enduse, 26by30 + 100by50_Def is infeasible, and in IEEJ and TIMES-Japan, 26by30 + 90by50_Def and 26by30 + 100by50_Def are infeasible. Therefore; pathways to achieve net carbon neutrality, a new pledge presented by Prime Minister Suga in October 2020 (Prime Minister’s Office of Japan 2020), could not be elaborated in this paper. This is a future research issue.

Results

Overall CO2 emissions and final energy use in 2050

The CO2 emissions in 2050 for the 26by30 + 80by50_Def scenario are around 280Mt-CO2 (237–336Mt-CO2). The supply side sees a sharp reduction to which the emissions are less than 100Mt-CO2 in all models. However, the demand sector still emits approximately 200Mt-CO2 (199–252Mt-CO2) (see Figure ESM 1.) showing that the demand-side reduction is crucial in achieving emissions reduction targets. The total amount of CO2 captured and stored is around 160Mt-CO2 (23–350Mt-CO2), of which around 40 Mt-CO2 (0–109Mt-CO2) is captured in the demand sector (the industry sector, including industrial processes).

Next, we present final energy (reported in lower heating value) by fuel types in 2010Footnote 2 and 2050 for the 26by30 + 80by50_Def scenario (Fig. 1). One common trend among the models is a drastic decrease in liquids, mostly oil products, by 4.1EJ to 5.5EJ compared to 2010 (the reduction rate ranges from 44 to 78%). A similar trend of decreasing consumption is observed in solids, which sees a decrease by about 1EJ in all models. Other energy carriers, electricity, hydrogen and gases, see different patterns depending on models.

Fig. 1
figure 1

Final energy use in 2010 and 2050 by fuels in 26by30 + 80by50_Def: a Final energy use in 2010 and 2050, b Difference in final energy use 2010 and 2050, c Fuel share in final energy use in 2010 and 2050, and d Difference of fuel share in final energy use 2010 and 2050

All models show a substantial decrease in the final energy use from 2010 to 2050. The net final energy use decreases by 5EJ in AIM/Enduse and by 7EJ in IEEJ. Despite similar reduction in liquids and solids, the net final energy use only decreases around 4EJ in AIM/Hub, DNE21, and TIMES-Japan due to the increasing use of electricity, gas and hydrogen.

In AIM/Enduse, most fuels are reduced with only a slight increase in hydrogen and “other all (heat, solar, and other sources)”. In IEEJ, only a slight increase in hydrogen is seen and significant energy savings in all other fuels. In AIM/Hub, DNE21, and TIMES-Japan electricity, gas and hydrogen increase while fossil fuel consumption reduces. In AIM/Hub, a significant increase in electricity consumption is observed. In DNE21, electricity and gases increase. In TIMES-Japan, electricity, gases, and hydrogen significantly increase.

The electricity demand stays at a relatively the same level compared to the current consumption, 3.0–4.5EJ (840–1260TWh), with one exception of AIM/Hub which sees a sharp increase to 7.0EJ (1950TWh) in 2050.Footnote 3 In terms of the absolute electricity demand, both results of increasing and decreasing were seen among models, which is consistent with the findings of Sugiyama (2012). Despite the level of consumption staying relatively flat in 2050, the electrification rate increases in all models (AIM/Enduse: 37%; AIM/Hub: 66%; DNE21: 39%; IEEJ: 44%; TIMES: 43%) compared to around 26% in 2010 as the total final energy use decreases. The electrification rates increase at a pace of 0.03–0.45%/year from 2010 to 2030, but increase at a faster pace of 0.46–1.58%/year from 2030 to 2050.

With regards to other clean energy carriers, a notable increase in hydrogen is seen in IEEJ and TIMES-Japan models, providing around 10% of final energy in 2050 (AIM/Hub and DNE21 have no hydrogen option).

CO2 emissions and final energy use by sectors in 2050

The overall direct CO2 emissions reduction rate of the demand-side from 2010 to 2050 is approximately 70%, but the reduction rates by sectors vary across models as shown in Fig. 2. The CO2 emissions reduction rates are 50–84% in the industry sector including industrial processes, 36–82% in the residential sector, 34–100% in the commercial sector, and 54–93% in the transportation sector.

Fig. 2
figure 2

CO2 emissions and CO2 reduction rate by demand-side sectors in 26by30 + 80by50_Def: a CO2 emissions in 2010 and 2050, and b CO2 reduction rate in 2050 from 2010. Note: DNE21 does not report CO2 emissions by sectors

The CO2 emissions in the transportation sector are the smallest in AIM/Enduse while they are the largest in AIM/Hub. Both in IEEJ and TIMES-Japan, the largest emitting sector is the industry sector and the smallest is the commercial sector. However, in IEEJ, the CO2 emissions of the residential sector is about half of the transportation sector, but in TIMES-Japan, the residential sector and the transportation sector have almost the same CO2 emissions.

The variation among models is caused by the differences in final energy use changes in each sector from 2010 to 2050. Figure 3. shows the differences among models in the final energy use by fuels in industry, residential, commercial, and transportation sectors in 2010 and 2050. The industry sector continues to be the most consuming sector in all models despite the largest decrease in the final energy use among all sectors in most models. The transport sector goes through a rapid transition with a rapid decline in use of liquids (mostly oil products).

Fig. 3
figure 3

Final energy use by fuel type by sector in 2010 and 2050 in 26by30 + 80by50_Def: a Final energy use in industry sector in 2010 and 2050, b Difference in final energy use 2010 and 2050 in industry sector, c Final energy use in residential sector in 2010 and 2050, d Difference in final energy use 2010 and 2050 in residential sector, e Final energy use in commercial sector in 2010 and 2050, f Difference in final energy use 2010 and 2050 in commercial sector, g Final energy use in transportation sector in 2010 and 2050, and h Difference in final energy use 2010 and 2050 in transportation sector

The final energy use in the industry sector in 2050 ranges between 3.3 and 5.7EJ, and the electricity consumption ranges between 0.8 and 2.5EJ. The share of final energy use by the industry sector in 2050 is 32–60%, close to half in three models. The industry sector transforms its energy composition largely dependent on liquids and solids (around 60% in all models) in 2010 to delivering half of its energy from electricity, gases and hydrogen in 2050. Although the largest reduction is seen in liquids, the consumption of liquids still stays high around 1.2EJ in all models. Solids are also reduced in all models, but most models still use around 0.6EJ in 2050.

The final energy use in the residential sector ranges between 1.2 and 2.4EJ of which gases and electricity make up most of the demand. The reduction in liquids demand is a major movement in the residential sector as the liquids demand decreases to less than 0.1EJ in three models, implying that oil water heater and stoves are virtually phased out in the residential sector (Oshiro and Fujimori 2020). Most models see a decrease in the final energy demand, but AIM/Hub sees an increase as the increase in electricity demand surpasses the decrease in liquids demand.

The final energy use in the commercial sector in 2050 is 1.3–2.4EJ, of which electricity is the major energy carrier. The use of liquids and gases are greatly reduced and almost no longer consumed (0–0.02EJ for liquids, 0–0.2EJ for gases) except for AIM/Enduse which has a relatively large CO2 emissions in the commercial sector. This implies that nearly all oil and gas appliances (mainly cooking, water heater, and space heating) needs to be phased out in this sector to reach emissions reduction targets.

The transportation sector sees a rapid transformation from heavily liquids dependent energy composition to a more mixed composition. Other than AIM/Hub, which does not model hydrogen, models see an increase in both electricity and hydrogen. The electricity consumption increases to 0.3–0.6EJ, whereas the hydrogen consumption increases to 0.1–0.6EJ. Since most of the energy use in the transportation sector was oil products in 2010, liquids consumption decreases by 1.3–2.5EJ. The replacing technologies (electric vehicles and hydrogen vehicles) typically have higher efficiency, so the final energy use in the sector reduces to 1.0–2.4EJ. The share of transportation sector in overall final energy, which was around 25% in 2010, decreases to around 15% in most models.

Figure 4 shows fuel share of final energy use by sectors in 2010 and 2050. Two trends observed in all sectors from 2010 to 2050 are the decrease in the share of liquids and the increase in electrification rates (with the exception of the residential sector’s electricity share in the AIM/Enduse). The electrification rates increase mainly due to decreasing consumption of other fuels in the industry and residential sectors. In the commercial and transport sectors, the increasing electrification rates is attributed also to the increasing consumption of electricity along with decreasing consumption of other fuels (see also Fig. 3).

Fig. 4
figure 4

Share of fuels in final energy by sectors in 2010 and 2050 in 26by30 + 80by50_Def: a Industry sector, b Residential sector, c Commercial sector, and d Transportation sector

In the industry sector, the electrification rate stays the lowest among sectors at around 20%, an increase of only a few percentage points from 2010. One exception is the AIM/Hub (the only participating GE model), in which rapid electrification takes place up to 73% in 2050.In the residential sector, the electrification rate is the highest among all fuels in all models (46–75%), showing the importance in electrifying the residential end-use technologies. On the other hand, the share of liquids (mostly oil products) decrease significantly suggesting a need to initiating a phase out of oil water heater and stoves. The commercial sector, which has the highest electrification rate across sectors in all models (62–95%), sees the use of liquids disappear in three models implying limited use of oil and gas appliances (mainly for cooking, hot water, and space heating) in a decarbonized society. The transport sector sees a great increase in the share of electricity. In 2010 the share is very low at around 2%, but it increases to 20–40% in models.

As a complement, the share of hydrogen, a clean energy carrier competing with electricity, is described by sector. In the industry sector, hydrogen is introduced in 2050 with a share of 9% and 7% in IEEJ and TIMES-Japan respectively, while the electrification rates reach 23% and 29%. Likewise, in the transport sector, both electricity and hydrogen are introduced in 2050. In AIM/Enduse, electricity is 20% while hydrogen is 7% and in IEEJ, electricity is 24%, hydrogen is 19%. In TIMES-Japan, the share of hydrogen is higher than electricity, with electricity at 40% while hydrogen at 44%.

Carbon intensity (the emission amount per unit final energy use) is reduced across all models in 2050. Looking at the CO2 emissions (Fig. 2) and the final energy use (Fig. 3) in each sector from 2010 to 2050, the demand sector’s carbon intensities in 2010 is 48–56 g-CO2/MJ, but they are reduced to 22–29 g-CO2/MJ in 2050 (Fig. 5). The lowest carbon intensity is seen in the commercial sector (0–22 g-CO2/MJ), followed by the residential sector (11–28 g-CO2/MJ). The model average of carbon intensity in the industry sector including industrial processes (28 g-CO2/MJ) and the transportation sector (30 g-CO2/MJ) remain to be high-emitting sectors.

Fig. 5
figure 5

Carbon intensity in 2010 and 2050 and relationship to electrification rate by sector in 2050 in 26by30 + 80by50_Def: a Carbon intensity by sector in 2010 and 2050, and b The relationship between electrification rate and carbon intensity by sector in 2050. Note: Carbon intensity calculates by only direct emissions without CCS in industry sector

The carbon intensity strongly depends on the ratio of fuel types in the final energy use. The value of carbon intensity increases as the share of fossil fuels increases, and the carbon intensity decreases as the share of clean energy carriers, such as electricity and hydrogen, increase. Therefore, sectors with high electrification rates have low-carbon intensities as shown in Fig. 5 and contribute greatly in reducing the demand-side emissions.

Sensitivity analysis

VREs and nuclear generation sensitivity

In order to analyze the effects of available VREs and nuclear generation, scenarios with high and low VRE costs, high and low VRE resource potential, and no nuclear (LoVREcost, HiVREcost, HiVREpot, LoVREpot, and NoNuc) are compared. Figure 6 shows the share of energy carriers in each scenario by models. Although electrification rates are different in each model, all models maintain electrification rates close to the level of 26by30 + 80by50_Def scenario as the change ranges between  − 4.3 and  + 6.5%pt (see also Figure ESM3).

Fig. 6
figure 6

Final energy mix in 2050 in VREs and nuclear generation sensitivity scenarios

A notable change in the share of final energy is seen in the following scenarios. AIM/Enduse shows a higher electrification rate (+ 1.2%pt) in the HiVREcost scenario than the 26by30 + 80by50_Def scenario because the electricity consumption is slightly higher (+ 0.01EJ) while the final energy use decreases by 0.24EJ. In AIM/Hub, the electrification rate decreases from the 26by30 + 80by50_Def scenario in the HiVREcost (− 4.3%pt) and the NoNuc (− 2.2%pt) scenarios by increasing liquids consumption, while the electrification rate increases from the 26by30 + 80by50_Def scenario in the LoVREcost (+ 4.5%pt) and the HiVREpot (2.1%pt) scenarios by decreasing liquids consumption. In DNE21, only the NoNuc scenario shows a slight decrease in the electrification rate (− 0.2%pt) from 26by30 + 80by50_Def because DNE21 has a high share of nuclear power generation due to no quantity constraint (see Shiraki et al. 2021) in 26by30 + 80by50_Def. IEEJ and TIMES-Japan models show a competitive nature between VRE and hydrogen. Hydrogen consumption decreases when more VREs electricity becomes accessible (LoVREcost and HiVREpot), while hydrogen consumption increases when electricity from VREs and nuclear becomes limited (HiVREcost, LoVREpot and NoNuc).

The electrification rate correlates positively with the availability of VREs and nuclear power sources, but the cases considered in this modeling exercise were not enough to change the electrification rates drastically. When availability of nuclear is restricted, VRE replaced the generation and vice versa. In summary, the cost and availability of VREs and nuclear generation does not change the need for electrifying the demand sector to achieve the 80% reduction in 2050.

CCS sensitivity

Figure 7 shows the share of final energy carriers and CO2 emissions in the NoCCS scenario by models. Models maintain electrification rates close to the level of 26by30 + 80by50_Def scenario as the change ranges only between  − 0.2 and  + 1.8%pt. One exception is AIM/Enduse, which sees a notable increase of 8.8%pt as over 100Mt of CCS is deployed on the demand side (around 110Mt-CO2 in the industry sector including industrial processes) in 26by30 + 80by50_Def. When CCS is not available, AIM/Enduse decreases gas consumption and increases electricity demand to reduce CO2 emissions in the residential and commercial sectors to compensate for the increasing emissions in the industry sector.

Fig. 7
figure 7

Final energy use and CO2 emissions in 2050 in CCS sensitivity scenario: a Final energy use and b CO2 emissions (26by30 + 80by50_Def and 26by30 + 80by50_NoCCS). Note: DNE21 does not report CO2 emissions by sectors. DNE21 are not classified

Emissions policy sensitivity

Figure 8 shows the changes in the share of final energy carriers when the emission reduction target for 2050 is 70%, 80%, 90%, and 100% (26by30 + 70by50_Def, 26by30 + 80by50_Def, 26by30 + 90by50_Def, and 26by30 + 100by50_Def). Some models were not able to provide results as the emissions policy became extremely stringent. (26by30 + 90by50_Def: IEEJ, TIMES-Japan; 26by30 + 100by50_Def: AIM/Enduse, IEEJ and TIMES-Japan).

Fig. 8
figure 8

Final energy use by fuel type in 2050 in emissions policy scenarios

When a stricter emissions reduction policy is applied, the electrification rates increase in all models (Fig. 9), showing the importance of electricity as a clean energy carrier in the demand sector. Electricity typically replaces gases and liquids, but in some models (DNE21, IEEJ) the gases consumption increases with tighter emissions targets. An increase in hydrogen consumption with tighter emissions targets is also observed in AIM/Enduse, IEEJ and TIMES-Japan, all the models with a hydrogen option.

Fig. 9
figure 9

Electrification rate and emissions reduction targets in 2050

In AIM/Enduse, electricity consumption increases from 3.1 to 3.7EJ (860–1030TWh) as the emissions target gets tighter from 70 to 90%. The biggest reduction seen is in gases as the consumption decreases from 2.0 to 0.9EJ followed by liquids from 2.3 to 1.9EJ.

AIM/Hub’s electricity consumption increases from 6.5 to 7.8EJ (1800–2160TWh) as the emissions target gets tighter from 70 to 100%. The increase in the electricity consumption replaces gases and liquids as the gases decrease from 0.8 to 0.1EJ, and liquids decrease from 4.4 to 1.0EJ.

In DNE21, the electricity consumption stays the same from 70 to 90% reduction targets at 4.5EJ (1260TWh) but increases to 4.7EJ (1300TWh) in 100% reduction target. The consumption of liquid decreases from 6.6 to 2.3EJ as the emission target gets tighter from 70 to 100% as in all models, but the consumption of gases increases from 1.8 to2.7EJ.

In IEEJ, the electricity consumption increases from 2.9 to 3.0EJ (820–830TWh) as the emissions target gets tighter from 70 to 80%. The coal and liquids demand decrease as in other models, but the biggest increase is seen in hydrogen which increases from close to zero to 0.5EJ.

In TIMES-Japan, the electricity consumption increases from 3.9 to 4.1EJ (1090–1130Wh) as the emissions target gets tighter from 70 to 80%. Like IEEJ, the TIMES-Japan sees a decrease in liquids and gases while hydrogen increases the most from 0.3 to 1.2EJ.

Discussion

Electrification pace and METI outlook

The METI outlook assumes the final energy use in 2030 to be reduced by 14% (14.4–12.4EJ) while the electricity consumption to be reduced by only 5% (3.7–3.5EJ) compared to 2010. Since the final energy reduction rate is higher, the METI outlook recommends electrification rate to be increased from 26 to 29% or the electrification rate to increase at the pace of 0.15%/year.

The electricity rate in Japan has increased from 13% in 1970 to 28% in 2018. Looking at a 20-years span, the annual percent change in electrification has been 0.37%/year from 1970 to 1990, and 0.30%/year from 1990 to 2010. Since 2011 the pace of electrification has slowed down to 0.18%/year from 2010 to 2018.

In the 26by30 + 80by50_Def scenario, the electrification rates increase at a pace of 0.03–0.45%/year from 2010 to 2030, showing that the historical rates and the rate assumed by METI outlook could be enough to reach the 2030 target (Fig. 10). However, as mentioned in the results section, the electrification pace must be accelerated from 2030 to 2050 and need to reach the range of 0.46–1.58%/year. This pace is 1.5–5.3 times higher than the historical average of 0.30%/year (199–2010), a period of relatively electrification leading up to the 2011 Tohoku earthquake and tsunami. Taking into consideration that the pace of electrification in the baseline scenario, a scenario without a climate policy, is 0.14–0.49%/year from 2030 to 2050 in the 26by30 + 80by50_Def in 2050, increasing electrification rates to achieve 80% reduction in 2050 will require additional policy measures. Multiple studies (Seto et al. 2016; Unruh 2000) have pointed out that a lock-in mechanism could delay the diffusion of technologies. Policies and measures to alleviating the lock-in mechanism which can delay electrification need be considered to increase the pace of electrification suggested by the models to achieve the emissions reduction target. Policymakers could refer to some advanced electrification measures recently taken to decarbonize buildings by several US states. The measures include obligation or recommendation to electrify new buildings, installation assistance for electrical equipment, the requirement for electrification ready, and providing consumers with information on benefits such as comfort and controllability of electrical equipment (Nishio and Nakano 2020).

Fig. 10
figure 10

Electrification rate from 1980 to 2050 in Historical, Baseline and 26by30 + 80by50_Def: a Electrification rate from 1980 to 2050, b Electrification rate in 2030 and 2050, and c Average of annual change in electrification rate from 2010 to 2030 and 2030 to 2050

Looking further into the sectoral electrification rates, there is no consensus among the models on the pace of electrification. Only in the transportation sector alone, which currently has a very low electrification rate, all models show that the electrification pace needs to be increased. While there are variations in the electrification rates and electricity demand by sectors among models, a common trend in end-use technology was observed in the residential, commercial and transportation sectors. The use of oil water heater and stoves decreases in the residential sector and gas appliances decreases in the commercial sector. In the transportation sector, fossil fuel vehicles decreased significantly, while they were replaced by electric and fuel cell vehicles. There is a big difference among models in terms of the timing and pace of electrification by sectors, but there is a clear conclusion that the overall electrification rate of the demand sector needs to be increased. A detailed analysis of the differences between the models of electrification pace by sector is a topic for the future. Since Ju et al. (2021) reports results of energy use in the industry sector in details from the same Model Intercomparison project.

It is also important to note that reducing emission intensity of electricity is a prerequisite for mitigation through electrification (Zhang and Fujimori 2020). In the 26by30 + 80by50_Def scenario, the model results show the emission intensity of electricity sharply decreases from 2040 to 2050, but a lock-in mechanism also applies to the supply sector. Along with accelerating the pace of electrification, the emission intensity of electricity should be reduced accordingly from an early stage.

Electricity and hydrogen

The two clean energy carriers introduced with a notable share in 2050 in this modeling comparison exercise are electricity and hydrogen. In two models in which hydrogen is not modeled, AIM/Hub and DNE21, electricity is chosen as the clean energy carrier. In other three models (AIM/Enduse, IEEJ and TIMES-Japan), hydrogen is introduced along with electricity to decarbonize the demand sectors. Hydrogen is mainly introduced in the industry and transportation sectors, as hydrogen is a good option for hard to electrify demands such as high temperature industrial heat demands, heavy trucks and ships. The residential and commercial sectors also have limited end-use technologies options available for hydrogen.

If we turn to the supply side, typically hydrogen is produced by electrolysis of water using carbon free electricity (International Energy Agency 2019), so the domestic hydrogen production is directly related to an increase in the supply-side electricity generation, not electricity demand in the demand sectors (see Figure ESM 4). In TIMES-Japan, the electricity generation jumps to nearly 2000TWh in the HiVREpot scenario compared to 1350TWh in the 26by30 + 80by50_Def scenario (Note that electricity consumption in Fig. 6 does not include the electricity consumption for hydrogen production, which is categorized as secondary energy use), as hydrogen is produced domestically using more readily available wind and solar. Such an increase in the amount of power generated for hydrogen production is regarded as indirect electrification. For example, net zero emissions scenario of the UK Committee on Climate Change (2019) and Capros et al. (2019) explicitly takes into account that the amount of electricity required for electrolysis of water will occur at a level comparable to the electricity demand of the traditional demand sector. It is also possible to import hydrogen; in which case the domestic electricity generation is not affected. Such a case is IEEJ, in which all of hydrogen consumed in the model is imported.

Although METI outlook only explicitly considers electricity for the demand sector in 2030, hydrogen along with electricity could play a vital role in the future energy mix. By 2050, innovation could open the possibility of affordable domestic hydrogen production options. Therefore, the amount of electricity generation possibly required to produce hydrogen should be carefully considered in the discussion for the energy mix of 2050, for example, in the revision of the basic energy plan.

We did not discuss the role of biomass, which is one of the low-carbon carriers, in this study. Since biomass could play an important role in extreme reduction scenarios, such as zero emissions in 2050, it is necessary to consider the role of biomass together with hydrogen in the future analysis of electrification.

Conclusion

In this study, we analyzed the change in energy use structure of the demand sector in scenarios achieving 80% reduction in 2050, Japan’s long-term reduction target, focusing on the role of electricity.

In order to achieve the long-term reduction target, it is necessary to significantly reduce CO2 emissions not only in the supply side but also in the demand side. The model results of the scenario that is consistent with the NDC and mid-century strategy show approximately 70% reductions in the demand-side emissions in this modeling comparison. The reduction is contributed to a significant reduction in the final energy use, especially fossil fuels, while maintaining or increasing consumption of low emission intensity electricity. The electrification rate increases mainly due to switching from fossil fuel end-use technologies (i.e. oil water heater, oil stove and combustion-engine vehicles) to electricity end-use technologies (i.e. heat pump water heater and electric vehicles).

The pace at which electrification rate must be increased is a challenge. Electrification has been advancing as a trend, but neither the past electrification pace nor the outlook of the Ministry of Economy, Trade and Industry is enough to reach the suggested electrification rate of 37–66% suggested by the models in 2050. Therefore, a more focus should be given on demand side electrification in the long-term strategy, and more concrete measures, such as banning the sale of combustion-engine vehicles by UK or requiring building electrification as in Berkeley, to accelerate dissemination of electricity end-use technologies across all sectors need to be established.