Managing Director & Senior Partner
This article is the second in a series on the future of energy in an increasingly uncertain world.
According to the consensus among climatologists, the upward trajectory of greenhouse gas emissions needs to be reversed by 2025 to hit the Paris target: to limit the global temperature increase by 2100 to well below 2°C higher than pre-industrial (late-19th-century) levels.
Technologies—including renewables, energy efficiency measures, and substitution of energy sources—are available to reverse the growth in emissions. But they must be deployed at scale, and doing so would require fast, forceful, and united action by governments and regulators worldwide, using all the levers at their disposal—well beyond current efforts. It would also call for a huge upfront investment: $19 trillion to $21 trillion from now until 2030, according to our estimates. Both requirements may be difficult to achieve in the scarce time we have left.
Economic disparities among countries are a large part of the problem. Our research confirms that even if China, the European Union, developed countries in Asia, and the US curbed their emissions, the Paris target would still be out of reach. Non-OECD emerging economies would also need to do the same. Yet although the investment required to implement the technologies would be manageable for rich OECD countries and China, most emerging economies, which would need to make a substantial part of the investment, would not be able to afford it on their own.
Climate scientists do not know for sure how warm the world will become or how quickly. While it is imperative that we don’t ease up on actions to curb climate change, companies, governments, and investors need to wake up to the likelihood of a hotter planet and factor that into their assumptions about the future.
For our purposes, we have divided the world into three parts: rich countries from the OECD and developed countries in Asia; China, which has emerged as an economic powerhouse in its own right; and the rest of the world, mainly consisting of less affluent non-OECD countries, which we call “emerging economies” throughout this article.
To meet the Paris target, climatologists contend that manmade emissions would need to fall in the first half of the next decade and then decline steeply such that, by 2040, the global population would produce about half the emissions that it does today. Through efficiency measures, global economic activity would have to be far less energy intensive, and energy usage would need to emit much less carbon. We would need to take aggressive action on all possible fronts to achieve this goal. Even in the event of slow global economic growth, the task would be daunting.
To enable the sharp decline in fossil fuel consumption that is required, global power generation—which accounts for a quarter of anthropogenic emissions—would have to emit at least 70% less carbon dioxide by 2040 (en route to full decarbonation). This implies a steep decrease in coal power generation and far greater deployment of wind and solar power. At the same time, significant progress toward decarbonation would need to be made in the transportation, agriculture, industrial, and building sectors. We would need to increase substantially, and at a global scale, the energy efficiency of our buildings, electrical appliances and lights, and conventional internal combustion engines. Electric vehicles would also need to be broadly deployed.
Reversing the trajectory of global emissions will require radical changes to the global energy mix, but the technologies are available. Insulation, LED lighting, efficient appliances, low-fuel-consumption engines, electric mobility, and self-driving vehicles are starting to create a more energy-efficient world. Moreover, renewable wind and solar power (helped by rapidly declining costs and improved storage technologies) and the shift from coal in power generation and from oil to gas in refineries and heavy transport are reducing the carbon intensity of economic activity.
However, we cannot count on all of these advances to become competitive with conventional technologies in time to achieve the Paris target. For example, solar and wind energy have, through cost reductions, become cheaper than conventional sources—when there is sun or wind. Their intermittent nature means that the cost of these unconventional sources, and of static batteries, will have to continue declining if solar and wind are to pay for the backup storage technologies required and if they are to become competitive on a year-round basis. Regulators and governments around the world would need to act to ensure the widespread adoption of the technologies at scale and in time. Because the environment is a public good, it’s only right that protecting it requires policies that enforce correct behaviors.
Although China is encouraging a domestic renewables industry and is taking dramatic steps to address urban pollution and climate issues, fossil fuel dependence in emerging economies is a significant obstacle to achieving the Paris ambitions. Population growth and energy-intensive economic activity—in power generation, industry, transport, and agriculture—in already densely populated emerging economies are key drivers of rising anthropogenic emissions.
Emerging economies currently account for more than one-third of the world’s fossil fuel power-generating capacity, and their share is set to exceed 45% by 2040. In South American and Asian emerging countries, deforestation (often to make way for beef cattle, which produce methane from enteric digestion) is an important contributor to the 15% of global greenhouse gas emissions from forestry and agriculture.
Emerging countries have a desire and a right to catch up with their wealthier counterparts. But whereas rich OECD nations can invest in energy efficiency measures, that’s not the case in many emerging economies, where economic activity remains energy intensive because of aging factories and traditional manufacturing operations. In addition, the majority of the world’s population growth will be in emerging economies in Africa and Asia.
Using BCG’s Global Energy Scenario Model, we developed a “business as usual” scenario, which assumes the fulfillment of policy commitments to date and continuing progress in energy efficiency. On the basis of that scenario, we estimate that emerging economies will account for more than 130% of the increase in global fossil fuel demand between 2015 and 2040, equivalent to 7 billion tons of carbon dioxide per year, while OECD countries and China will see a dip in demand.
Although rich countries are the main source of the emissions that have warmed global temperatures to current levels, emerging countries account for the fastest growth in emissions and would therefore need to be part of any solution for meeting the Paris target. (See Exhibit 1.) Without the means to pay for the necessary technologies, however, they will be hard pressed to do this.
Using our model, we then assumed modest real global GDP growth of 3% per year from 2015 to 2040—slower than the growth rate of up to 3.5% many institutions anticipate over this period. We also assumed that governments continued with their current policies for transitioning to a low-carbon economy. Taking these steps stabilized the amount of greenhouse gas emissions in the atmosphere and reduced the volume that would need to be removed to achieve a trajectory of 2°C.
We then assumed that both rich OECD countries and China took very aggressive action—well beyond their current policies—to cut their emissions, including energy efficiency measures, significant adoption of renewables and electric vehicles, substitution wherever possible of oil by gas in petrochemicals and heavy transport, and a faster retirement of coal-fired power plants. This reduced the volume of emissions that would need to be removed between 2015 and 2040 by about half. The remaining amount would have to be addressed with equally aggressive and exhaustive action by emerging economies to curb their own emissions. (See Exhibit 2.)
In the absence of unified global action, countries that pursue a low-carbon agenda unilaterally would face a first-mover disadvantage—in short, the benefits of their investment would pay off only if all other countries did the same, and at a similar pace. Certainly, wealthier countries, in addition to regulating to promote energy efficiency and lower carbon usage by their own citizens and corporations, should show leadership through a combination of policies and support aimed at changing behaviors around the world.
Indeed, a global approach might persuade governments in rich countries to help poor nations with the technology bill. Wealthier governments could also take regulatory action to curb emissions in their companies’ supply chains, which often span developed and emerging countries. Regardless, without financial assistance and appropriate incentives, the investment required remains a significant obstacle for the poorest countries.
The $19 trillion to $21 trillion that would need to be invested from now until 2030 would cover the deployment of technologies and energy efficiency measures at scale, and the replacement of conventional polluting assets. Between 60% and 80% of this sum would fall on emerging economies. This upfront investment would be very large for governments and the private sector. It would largely be paid back, though over many years, through lower fuel, labor, and maintenance costs.
Despite this, most emerging economies cannot afford to stop using their fossil-fuel-fired power plants, cease building new ones, or make a huge investment in zero- and low-carbon technologies. In emerging countries, most power plants are coal-fired and are less than ten years old, far younger than in the OECD, where coal plants are typically at least 30 years old. Achieving the step change in the global energy landscape necessary to hit the Paris target would require the “accelerated mortality” of the world’s conventional power generation assets. But such a move would hit emerging economies hardest because of their lower GDPs and the age of their assets.
We estimate that OECD countries and China would have to invest 0.9% and 1.2% of their annual GDP, respectively, in these technologies from now until 2030 to achieve the Paris target. For emerging countries, the investment required over the same period would be 1.4% to 1.5% of annual GDP. For these countries—faced with the pressure to invest in essential infrastructure, improve public health, and provide citizens with food and other basic amenities—this amount is beyond their means. And the populations of these countries would not accept the tradeoffs that would be required.
Our view risks placing us in the crossfire of an emotionally charged debate. We don’t know for sure the impact that progressively higher temperatures will have on the environment. According to some scientific studies, the world could face a growing risk of famine with a rise of more than 3°C and a higher probability that major cities would be devastated by rising sea levels with an increase of more than 4°C. The science behind this analysis is hugely complex; we may have more leeway than this, or less. Even so, we cannot take the chance of getting it catastrophically wrong because of our failure to act. The probability of these events may be low, but the risk is not worth taking.
Governments, companies, and individuals should step up their actions to limit climate change in the following ways:
In parallel, all players need to be pragmatic and consider how to prepare for a warmer world:
Participants across the energy industry are struggling to find their footing in a rapidly evolving landscape. The pace of change, and the disruption it brings, is set to accelerate before we reach a new equilibrium. And no one knows precisely what that will look like.
For decades, the industry had familiar contours: energy sources and markets operated in virtual silos, investment horizons were long, and technological development was steady but not disruptive. The uninterrupted growth of global demand for all sources—whether coal, oil, or natural gas—was taken as a given.
Now, all that is in flux. Rapid structural changes in energy markets—at times initiated by regulation but fundamentally driven by technological innovation—have intensified competition among both traditional and renewable sources. Disruptions that were unimaginable not long ago—such as the emergence of environmentally friendly electric vehicles and the substantial use of wind and solar energy in power generation—are now realities.
The myriad potential combinations of these disruptive factors and others would lead to very different outcomes for energy companies and for countries.
But whatever the outcome, industry players will need to adapt. Companies must minimize the risk of stranded assets, manage complex resource exposures, and stay on the right side of upcoming regulations. Governments must ensure that the transition to cleaner energy is not overly costly for citizens and industry, and promote long-term technologies without generating windfall profits for a few.
Industry players and governments also face a higher-order challenge: given an uncertain world, they must develop the capability to examine the assumptions behind conflicting outlooks, assess the impact of various disruptions, individually and in combination, and prepare for the range of possible energy futures.
Companies and national authorities need to navigate strategic energy decisions and engage in a dialogue with stakeholders about solutions that will help make the energy transition as effective as possible while addressing environmental challenges.
Despite the technologies at our disposal, we will probably miss the Paris climate target. However, it remains an important yardstick. By striving to achieve it, we can take vital steps that will help limit climate change for our own and future generations. This will likely require a global commitment to support emerging countries with their transition to low-carbon economies. Nevertheless, we should also concede that the world will get warmer, and we must take steps to prepare for that eventuality.
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