Our job is clear: we are at 4% and need to be at 80% wind, water and solar by 2030 and 100% by 2050, for 1.5 C

In 2012, the 139-country all-purpose, end-use load was ∼12.1 TW. Of this, 2.4 TW (19.6%) was electricity demand. Under BAU, all-purpose end-use load may grow to 20.6 TW in 2050. Transitioning to 100% WWS by 2050 reduces the 139-country load by ∼42.5%, to 11.8 TW (Table 1), with the greatest percentage reduction in transportation. While electricity use increases with WWS, conventional fuel use decreases to zero. The increase in electric energy is much less than the decrease in energy in the gas, liquid, and solid fuels that the electricity replaces for three major reasons:

(1) The higher energy-to-work conversion efficiency of using electricity for heating, heat pumps, and electric motors, and using electrolytic hydrogen in hydrogen fuel cells for transportation, compared with using fossil fuels (Table S4);

(2) The elimination of energy needed to mine, transport, and refine coal, oil, gas, biofuels, bioenergy, and uranium;

(3) Assumed modest additional policy-driven energy-efficiency measures beyond those under BAU.

These factors decrease average demand ∼23.0%, 12.6%, and 6.9%, respectively, for a total of 42.5%. Thus, WWS not only replaces fossil-fuel electricity directly but is also an energy-efficiency measure, reducing demand.

Numbers of Electric Power Generators, Land Required, and Resources Available

Table 2 summarizes the numbers of WWS generators needed to power all 139 countries in 2050 for all energy purposes assuming the end-use loads by country in Table S6 and the percent of each country’s load met by each generator in Table S8. The numbers of generators were derived accounting for power loss during transmission, distribution, and generator maintenance; and competition among wind turbines for limited kinetic energy (array losses). The numbers also assume all power for a country is generated and used in the country in the annual average, and thus ignore cross-border transfers of energy that will occur in reality.

While utility-scale PV can operate in any country, because it can use direct and diffuse sunlight, CSP is viable only where significant direct sunlight exists. Thus, CSP penetration in several countries is limited (Section S5.2.4).

Onshore wind is available in every country but assumed to be deployed aggressively primarily in countries with good wind resources and sufficient land (Section S5.1.1). Offshore wind is assumed viable in the 108 out of 139 countries with ocean or lake coastline (Section S5.1.2). In most of these countries, the technical potential installed capacity is determined from the area of coastal water less than 60 m depth and with a capacity factor of at least 34% in the annual average.

The 2050 nameplate capacity of hydropower is assumed to be the same as in 2015. However, existing hydropower is assumed to run at slightly higher capacity factor (Section S5.4). This assumption is justified by the fact that in many places, hydropower use is currently suppressed by the availability and use of gas and coal, which will be eliminated here. If current capacity factors are limited by low rainfall, it may also be possible to make up for the deficit with additional run-of-the-river hydro, pumped hydro, or non-hydro WWS energy sources. Geothermal, tidal, and wave power are limited by each country’s technical potentials (Sections S5.3, S5.5, S5.6).

4% of the way there, more than 75% to go by 2030!

Table 2 also lists needed installed capacities of additional CSP with storage, new solar thermal collectors, and existing geothermal heat installations. These collectors are needed to provide electricity or heat that is mostly stored for peaking power (Section S7).  Table 2 indicates that 4.26% of the 2050 nameplate capacity required for a 100% all-purpose WWS system among the 139 countries was already installed as of the end of 2015. The countries closest to 100% installation are Tajikistan (76.0%), Paraguay (58.9%), Norway (35.8%), Sweden (20.7%), Costa Rica (19.1%), Switzerland (19.0%), Georgia (18.7%), Montenegro (18.4%), and Iceland (17.3%). China (5.8%) ranks 39^th and the United States (4.2%) ranks 52^nd (Figure S2).

Footprint is the physical area on the top surface of soil or water needed for each energy device. It does not include areas of underground structures. Spacing is the area between some devices, such as wind, tidal, and wave turbines, needed to minimize interference of the wake of one turbine with others downwind. The total new land footprint required for the 139 countries is ∼0.22% of the 139-country land area (Table 2), mostly for utility PV. This does not account for the decrease in footprint from eliminating the current energy infrastructure, which includes footprints for continuous mining, transporting, and refining fossil fuels and uranium and for growing, transporting, and refining biocrops. WWS has no footprint associated with mining fuels, but both WWS and BAU energy infrastructures require one-time mining for raw materials for new plus repaired equipment construction. The only spacing over land needed is between onshore wind turbines and requires ∼0.92% of the 139-country land area (Figure 1). The installed spacing area density of onshore and offshore wind turbines assumed here is less than indicated by data from dozens of wind farms worldwide (Section S5.1.1), thus spacing requirements may be less than proposed here.

In this section, current and future full social costs (including capital, land, operating, maintenance, storage, fuel, transmission, and externality costs) of WWS electric power generators versus non-WWS conventional fuel generators are estimated. These costs include the costs of CSP storage, solar collectors for underground heat storage in rocks and boilers, and all transmission/distribution costs, including additional short-distance A/C lines and long-distance high-voltage D/C lines. We do not include here the cost of underground storage in rocks (apart from the cost of the solar collectors), the cost of pumped hydro storage, the cost of heat and cold storage in water and ice, or the cost of hydrogen fuel cells, but the section Matching Electric Power Supply with Demand provides a brief discussion that includes these costs.

The total up-front capital cost of the 2050 WWS system (for annual average power plus the peaking power and storage infrastructure listed in Table 2) for the 139 countries is ∼$124.7 trillion for the 49.9 TW of new installed capacity needed (∼$2.5 million/MW). This compares with ∼$2.7 million/MW for the BAU case. In addition, WWS has zero fuel costs, whereas BAU has non-zero fuel cost. To account for these factors plus operation/maintenance, transmission/distribution, and storage costs, the levelized cost of energy (LCOE) is needed.

The 2050 LCOEs, weighted among all electricity generators and countries in the BAU and WWS cases, are 9.78 ¢/kWh-BAU-electricity and 8.86 ¢/kWh-WWS-all-energy, respectively (Table S34), excluding at this point any costs for peaking and storage. Taking the product of the first number and the kWh-BAU in the retail electricity sector, subtracting the product of the second number and the kWh-WWS-electricity replacing BAU retail electricity, and subtracting the amortized cost of energy-efficiency improvements beyond BAU improvements in the WWS case, gives a 2050 business cost saving due to switching from BAU to WWS electricity of ∼$115/year per capita ($2013 USD). Estimating an additional 0.8 ¢/kWh-WWS-electricity for peaking and storage in the BAU retail electricity sector from Jacobson et al.⁴ gives a WWS approximate business cost of ∼9.66 ¢/kWh-WWS-electricity, still providing ∼$85/year per capita savings for WWS relative to just BAU’s retail electricity sector.

Matching Electric Power Supply with Demand

In the present study, we first calculate the baseline number of electric power generators of each type needed to power each country based on the 2050 annually averaged WWS load in the country after all sectors have been electrified but before considering grid reliability and neglecting energy imports and exports.

We then use data from a 2015 grid-integration study for the US⁴ to make a first-guess estimate of the additional electricity and heat generators needed in each country to ensure a reliable regional electric power grid (Table 2). Such estimates are then used as starting points in a separate, follow-up grid-integration study for 139 countries. Although no information from the separate 139-country grid-integration study feeds back to the present study, results from that grid-integration study are briefly described here next to provide an idea of the 139-country average energy cost to keep the grid stable with 100% WWS.

In M.Z.J., M.A.D., M.A.C., and B.V. Mathiesen, unpublished data, each of the 139 countries is allocated to one of 20 world regions. The numbers of wind and solar generators determined from the present study are input into the GATOR-GCMOM climate model⁴ in each country. The model predicts the resulting wind (onshore, offshore) and solar (PV, CSP, thermal) resources worldwide every 30 s for 5 years, accounting for extreme weather events, competition among wind turbines for kinetic energy, and the feedback of extracted solar radiation to roof and surface temperatures. The LOADMATCH grid-integration model⁴ then combines the wind and solar resource time series with estimated time series for other WWS generators; hourly load data for each country; capacities for low-cost heat storage (in underground rocks and water), cold storage (in ice and water), electricity storage (in CSP with storage, pumped hydropower, batteries, and hydropower reservoirs), and hydrogen storage; and demand-response to obtain low-cost, zero-load loss grid solutions for each of the 20 grid regions.

In that study, it was found that matching large differences between high electrical demand and low renewable supply could be realized largely by using a combination of either (1) substantial CSP storage plus batteries with zero change in existing hydropower annual energy output or peak power discharge rate, (2) modest CSP storage with no batteries and zero change in the existing hydropower annual energy output but a substantial increase in hydropower’s peak discharge rate, (3) increases in CSP-storage, batteries, and heat pumps, but no thermal energy storage and no increase in hydropower’s peak discharge rate or annual energy output, or (4) a combination of (1), (2), and (3). Thus, there were multiple solutions for matching peak demand with supply 100% of the time for 5 years without bioenergy, nuclear, power, fossil fuels with carbon capture, or natural gas.

In one set of simulations from M.Z.J., M.A.D., M.A.C., and B.V. Mathiesen, unpublished data, the resulting total costs of delivered 100% WWS energy, including generation, storage, short- and long-distance transmission, distribution, and maintenance, across all 139 countries in all 20 regions, was 10.6 (8.1–14) ¢/kWh-all-energy (USD, 2013) and 9.8 (7.9–12) ¢/kWh-WWS- electricity, the latter of which compares with the rough estimate of 9.7 ¢/kWh-WWS-electricity from the section Energy Costs here.

Air-Pollution Cost Reductions Due to WWS

The costs avoided due to reducing air-pollution mortality in each country are quantified as follows. Global 3D modeled concentrations of PM_2.5 and O₃ in each of 139 countries are combined with the relative risk of mortality as a function of concentration and population in a health-effects equation.²⁷ Results are then projected to 2050 accounting for increasing population, increasing emission sources, and increasing emission controls (Section S8.1).

Resulting contemporary worldwide outdoor plus indoor premature mortalities over the 139 countries are ∼4.28 (1.2–7.6) million/year for PM_2.5, ∼0.28 (0.14–0.42) million/year for O₃, and ∼4.56 (1.33–7.98) million/year for both.

Premature mortalities over the whole world are ∼4.97 (1.45–8.65) million/year for both pollutants (Figure S12), which compares with 4–7 million/year (outdoor plus indoor) worldwide from other studies. ^{1, 2, 28, 29, 30} Premature mortalities derived for 2050 here are ∼3.5 (0.84–7.4) million/year for the 139 countries (Table S36).

The air-pollution damage cost due to fossil-fuel and biofuel combustion and evaporative emissions in a country is the sum of mortality, morbidity, and non-health costs such as lost visibility and agricultural output. Mortality cost equals mortalities multiplied by the value of statistical life. Morbidity plus non-health costs are estimated as in Section S8.1. The resulting 139-country 2050 air-pollution cost due to 100% WWS is ∼$23 ($4.1-$69) trillion/year, or ∼12.7 (2.3–38) ¢/kWh-BAU-all-energy, which is ∼7.6% (1.4%–23%) of the 2050 global annual GDP on a purchasing power parity basis and $2,600/year per person (in 2013 USD). Our air-pollution mean cost, which applies across all BAU sectors, is well within the 1.4–17 ¢/kWh-BAU-electricity range of another study for the retail electricity sector.²⁸

The build-out of the WWS generation and transmission infrastructure produces jobs during construction and operation. All job numbers provided here are permanent, full-time (2,080 hr/year) jobs. Permanent direct, indirect, and induced construction jobs are calculated assuming that 1/L of total installed capacity is built or replaced every year, where L is the average facility life (Section S9.1.2). Upon replacement of each facility, new construction jobs are needed. As such, construction jobs continue permanently. Job estimates do not include job changes in industries outside of electric power generation (e.g., the manufacture of electric vehicles, fuel cells, or electricity storage), as it is uncertain where those jobs will be located and the extent to which they will be offset by losses in BAU-equivalent industries.

Results indicate that 100% conversion to WWS across 139 countries can create ∼25.4 million new ongoing full-time construction-related jobs and ∼26.6 million new full-time, ongoing operation- and maintenance-related jobs, totaling 52.0 million new ongoing jobs for WWS generators and transmission (Table S42).

Tables S42 and S45 summarize the resulting 139-country job losses in the oil, gas, coal, nuclear, and bioenergy industries. Because WWS plants replace BAU fossil, nuclear, bioenergy, and BAU-WWS plants, jobs lost from not constructing BAU plants are also included. Jobs lost from the construction of petroleum refineries and oil and gas pipelines are also counted. Shifting to WWS is estimated to result in ∼27.7 million jobs lost in the current fossil-fuel, biofuel, and nuclear industries, representing ∼0.97% of the 2.86 billion 139-country workforce.

In summary, WWS may create a net of ∼24.3 million permanent, full-time jobs across the 139 countries. Whereas the number of operation jobs declines slightly, the number of permanent, continuous construction jobs far more than makes up for the loss (Table S42). Individually, countries that currently extract significant fossil fuels (e.g., Algeria, Angola, Iraq, Kuwait, Libya, Nigeria, Qatar, and Saudi Arabia) may experience net job loss in the energy production sector. These losses can be offset by the manufacture, service, and export of technologies associated with WWS energy (e.g., liquid hydrogen production and storage, electric vehicles, electric heating and cooling, etc.). Those offsetting jobs are not included in the job numbers here. Collectively, the direct and indirect earnings from producing WWS electricity/transmission across 139 countries amount to ∼$1.86 trillion/year during construction and ∼$2.06 trillion/year during operation. The annual fossil-fuel earnings loss is ∼$2.06 trillion/year, yielding a net ∼$1.86 trillion/year gain (Table S42).

Timeline

Figure 2 is a proposed WWS transformation timeline for the 139 countries. It assumes 80% conversion to WWS by 2030 and 100% by 2050. The rate of transformation is based on what is necessary to eliminate air-pollution mortality as soon as possible, what is needed to avoid 1.5°C net global warming, and what we estimate is technically and economically feasible.

Friedlingstein et al.³² estimate that, for the globally averaged temperature change since 1870 to increase by less than 2°C with a 67% or 50% probability, cumulative CO₂ emissions since 1870 must stay below 3,200 (2,900–3,600) Gt-CO₂ or 3,500 (3,100–3,900) Gt-CO₂, respectively. This accounts for non-CO₂ forcing agents affecting the temperature response as well. Matthews³³ further estimates the emission limits needed to keep temperature increases under 1.5°C with probabilities of 67% and 50% as 2,400 Gt-CO₂ and 2,625 Gt-CO₂, respectively. As of the end of 2015, ∼2,050 Gt-CO₂ from fossil-fuel combustion, cement manufacturing, and land use change had been emitted cumulatively since 1870³³ suggesting no more than 350–575 Gt-CO₂ can be emitted for a 67%–50% probability of keeping post-1870 warming under 1.5°C. Given the current and projected global emission rate of CO₂, it is necessary to cut energy and land use change emissions yearly until emission cuts reach 80% by 2030 and 100% by 2050 to limit warming to 1.5°C with a probability of between 50% and 67% (Section S10.2).

Section S10.1 lists proposed timeline milestones by energy sector, and Section S11 identifies some of many potential transition policies to select from. Whereas much new WWS infrastructure can be installed upon natural retirement of BAU infrastructure, new policies are needed to force remaining existing infrastructure to be retired early to allow the complete conversion to WWS. Because the fuel, operating, and external costs of continuing to use existing BAU fossil-fuel capacity are, in total, much greater than the full annualized capital-plus-operating costs of building new WWS plants (indeed, the climate and air-pollution costs alone of BAU infrastructure, 28.5 [11.2–72] ¢/kWh-BAU-all-energy, exceed the full cost of new WWS infrastructure), and because substitution of WWS for BAU energy systems increase total jobs, it is beneficial to society to immediately stop operating existing BAU fossil-fuel plants and replace them with new WWS plants. 

Conclusions

Transitioning 139 countries to 100% WWS has the potential to

1. Avoid ∼4.6 (1.3–8.0) million premature air-pollution mortalities/year today and 3.5 (0.84–7.4) million/year in 2050, which along with non-mortality impacts, avoids ∼$23 ($4.1–69) trillion/year in 2050 air-pollution damage costs (2013 USD);
2. Avoid ∼$28.5 ($16.1–60.7) trillion/year in 2050 global-warming costs (2013 USD);
3. Avoid a total health plus climate cost of ∼28.5 (11.2–72) ¢/kWh-BAU-all-energy, or $5,800/year per person, over 139 countries;
4. Save ∼$85/person/year in BAU-electricity-sector fuel costs;
5. Create ∼24.3 million net new permanent, full-time jobs;
6. Stabilize energy prices;
7. Use minimal new land (0.22% of 139-country land for new footprint and 0.92% for new spacing);
8. Enable countries to produce as much energy as they consume in the annual average;
9. Increase access to distributed energy by up to 4 billion people worldwide currently in energy poverty; and
10. Decentralize much of the world power supply, thereby reducing the risk of large-scale system disruptions due to machinery breakdown or physical terrorism (but not necessarily due to cyber attack).

Finally, the aggressive worldwide conversion to WWS proposed here may help avoid global temperature rising more than 1.5°C since 1870. While social and political barriers exist, converting to 100% WWS using existing technologies is technically and economically feasible. Reducing the barriers requires disseminating information to make people aware about what is possible, effective policies (Section S11), and individuals taking actions to transition their own homes and lives.

Author Contributions