Is World Growth Sustainable?

Earlier in this chapter we described the views of Thomas Malthus, the early-nineteenth-century economist who warned that the pressure of population growth would tend to limit the standard of living. Malthus was right about the past: for around 58 centuries, from the origins of civilization until his own time, limited land supplies effectively prevented any large rise in real incomes per capita. Since then, however, technological progress and rapid accumulation of physical and human capital have allowed the world to defy Malthusian pessimism.

Sustainable long-run economic growth is long-run growth that can continue in the face of the limited supply of natural resources and the impact of growth on the environment.

But will this always be the case? Some skeptics have expressed doubt about whether sustainable long-run economic growth is possible—whether it can continue in the face of the limited supply of natural resources and the impact of growth on the environment.

Natural Resources and Growth, Revisited

In 1972 a group of scientists called The Club of Rome made a big splash with a book titled The Limits to Growth, which argued that long-run economic growth wasn’t sustainable due to limited supplies of nonrenewable resources such as oil and natural gas. These “neo-Malthusian” concerns at first seemed to be validated by a sharp rise in resource prices in the 1970s, then came to seem foolish when resource prices fell sharply in the 1980s. After 2005, however, resource prices rose sharply again, leading to renewed concern about resource limitations to growth.

Figure 9-10 shows the real price of oil—the price of oil adjusted for inflation in the rest of the economy. The rise, fall, and rise of concern about resource-based limits to growth have more or less followed the rise, fall, and rise of oil prices shown in the figure.

The Real Price of Oil, 1949–2011 The real price of natural resources, like oil, rose dramatically in the 1970s and then fell just as dramatically in the 1980s. Since 2005, however, the real prices of natural resources have soared.Source: Energy Information Administration.

Differing views about the impact of limited natural resources on long-run economic growth turn on the answers to three questions:

It’s mainly up to geologists to answer the first question. Unfortunately, there’s wide disagreement among the experts, especially about the prospects for future oil production. Some analysts believe that there is enough untapped oil in the ground that world oil production can continue to rise for several decades. Others, including a number of oil company executives, believe that the growing difficulty of finding new oil fields will cause oil production to plateau—that is, stop growing and eventually begin a gradual decline—in the fairly near future. Some analysts believe that we have already reached that plateau.

The answer to the second question, whether there are alternatives to natural resources, has to come from engineers. There’s no question that there are many alternatives to the natural resources currently being depleted, some of which are already being exploited. Indeed, since around 2005 there have been dramatic developments in energy production, with large amounts of previously unreachable oil and gas extracted through fracking, and with a huge decline in the cost of electricity generated by wind and especially solar power.

The third question, whether economies can continue to grow in the face of resource scarcity, is mainly a question for economists. And most, though not all, economists are optimistic: they believe that modern economies can find ways to work around limits on the supply of natural resources. One reason for this optimism is the fact that resource scarcity leads to high resource prices. These high prices in turn provide strong incentives to conserve the scarce resource and to find alternatives.

For example, after the sharp oil price increases of the 1970s, American consumers turned to smaller, more fuel-efficient cars, and U.S. industry also greatly intensified its efforts to reduce energy bills. The result is shown in Figure 9-11, which compares U.S. real GDP per capita and oil consumption before and after the 1970s energy crisis. In the United States before 1973 there seemed to be a more or less one-to-one relationship between economic growth and oil consumption. But after 1973 the U.S. economy continued to deliver growth in real GDP per capita even as it substantially reduced the use of oil.

U.S. Oil Consumption and Growth over Time Until 1973, the real price of oil was relatively cheap and there was a more or less one-to-one relationship between economic growth and oil consumption. Conservation efforts increased sharply after the spike in the real price of oil in the mid-1970s. Yet the U.S. economy was still able to deliver growth despite cutting back on oil consumption.Sources: Energy Information Administration; FRED; Bureau of Economic Analysis.

This move toward conservation paused after 1990, as low real oil prices encouraged consumers to shift back to gas-greedy larger cars and SUVs. But a sharp rise in oil prices from 2005 to 2008, and again in 2010, encouraged renewed shifts toward oil conservation.

Given such responses to prices, economists generally tend to see resource scarcity as a problem that modern economies handle fairly well, and so not a fundamental limit to long-run economic growth. Environmental issues, however, pose a more difficult problem because dealing with them requires effective political action.

Economic Growth and the Environment

Economic growth, other things equal, tends to increase the human impact on the environment. As we saw in this chapter’s opening story, China’s spectacular economic growth has also brought a spectacular increase in air pollution in that nation’s cities.

It’s important to realize, however, that other things aren’t necessarily equal: countries can and do take action to protect their environments. In fact, air and water quality in today’s advanced countries is generally much better than it was a few decades ago. London’s famous “fog”—actually a form of air pollution, which killed 4,000 people during a two-week episode in 1952—is gone, thanks to regulations that virtually eliminated the use of coal heat. As noted in the chapter’s opening story, the equally famous smog of Los Angeles is also largely gone, again thanks to pollution regulations.

Despite these past environmental success stories, there is widespread concern today about the environmental impacts of continuing economic growth, reflecting a change in the scale of the problem. Environmental success stories have mainly involved dealing with local impacts of economic growth, such as the effect of widespread car ownership on air quality in the Los Angeles basin. Today, however, we are faced with global environmental issues—the adverse impacts on the environment of the Earth as a whole by worldwide economic growth. The biggest of these issues involves the impact of fossil-fuel consumption on the world’s climate.

Burning coal and oil releases carbon dioxide into the atmosphere. There is broad scientific consensus that rising levels of carbon dioxide and other gases are causing a greenhouse effect on the Earth, trapping more of the sun’s energy and raising the planet’s overall temperature. And rising temperatures may impose high human and economic costs: rising sea levels may flood coastal areas; changing climate may disrupt agriculture, especially in poor countries; and so on.

The problem of climate change is clearly linked to economic growth. Figure 9-12 shows carbon dioxide emissions from the United States, Europe, and China since 1980. Historically, the wealthy nations have been responsible for the bulk of these emissions because they have consumed far more energy per person than poorer countries. As China and other emerging economies have grown, however, they have begun to consume much more energy and emit much more carbon dioxide.

Climate Change and Growth Greenhouse gas emissions are positively related to growth. As shown here by the United States and Europe, wealthy countries have historically been responsible for the great bulk of greenhouse gas emissions because of their richer and faster-growing economies. As China and other emerging economies have grown, they have begun to emit much more carbon dioxide.Sources: Energy Information Administration; FRED; Bureau of Economic Analysis.

Is it possible to continue long-run economic growth while curbing the emissions of greenhouse gases? The answer, according to most economists who have studied the issue, is yes. It should be possible to reduce greenhouse gas emissions in a wide variety of ways, ranging from the use of non-fossil-fuel energy sources such as wind, solar, and nuclear power; to preventive measures such as carbon sequestration (capturing the carbon dioxide from power plants and storing it); to simpler things like designing buildings so that they’re easier to keep warm in winter and cool in summer. Such measures would impose costs on the economy, but the best available estimates suggest that even a large reduction in greenhouse gas emissions over the next few decades would only modestly dent the long-term rise in real GDP per capita.

The problem is how to make all of this happen. Unlike resource scarcity, environmental problems don’t automatically provide incentives for changed behavior. Pollution is an example of a negative externality, a cost that individuals or firms impose on others without having to offer compensation. In the absence of government intervention, individuals and firms have no incentive to reduce negative externalities, which is why it took regulation to reduce air pollution in America’s cities. And as Nicholas Stern, the author of an influential report on climate change, put it, greenhouse gas emissions are “the mother of all externalities.”

So there is a broad consensus among economists—although there are some dissenters—that government action is needed to deal with climate change. There is also broad consensus that this action should take the form of market-based incentives, either in the form of a carbon tax—a tax per unit of carbon emitted—or a cap and trade system in which the total amount of emissions is capped, and producers must buy licenses to emit greenhouse gases. There is, however, considerable dispute about how much action is appropriate, reflecting both uncertainty about the costs and benefits and scientific uncertainty about the pace and extent of climate change.

There are also several aspects of the climate change problem that make it much more difficult to deal with than, say, smog in Beijing. One is the problem of taking the long view. The impact of greenhouse gas emissions on the climate is very gradual: carbon dioxide put into the atmosphere today won’t have its full effect on the climate for several generations. As a result, there is the political problem of persuading voters to accept pain today in return for gains that will benefit their children, grandchildren, or even great-grandchildren.

There is also a difficult problem of international burden sharing. As Figure 9-12 shows, today’s rich economies have historically been responsible for most greenhouse gas emissions, but newly emerging economies like China are responsible for most of the recent growth. Inevitably, rich countries are reluctant to pay the price of reducing emissions only to have their efforts frustrated by rapidly growing emissions from new players. On the other hand, countries like China, which are still relatively poor, consider it unfair that they should be expected to bear the burden of protecting an environment threatened by the past actions of rich nations.

The general moral of this story is that it is possible to reconcile long-run economic growth with environmental protection. The main question is one of getting political consensus around the necessary policies.

!worldview! ECONOMICS in Action: The Cost of Limiting Carbon

The Cost of Limiting Carbon

Over the years several bills have been introduced in Congress that would greatly reduce U.S. emissions of greenhouse gases over the next few decades. By 2014, however, it was clear that given the depth of the U.S. political divide, such bills were unlikely to pass for the foreseeable future. However, the U.S. Environmental Protection Agency (EPA) is already required by the Clean Air Act to regulate pollutants that endanger public health, and in 2007 the Supreme Court ruled that carbon dioxide emissions meet that criterion.

So the EPA began a series of steps to limit carbon emissions. First, it set new fuel-efficiency standards that will reduce emissions from motor vehicles. Then it introduced rules limiting emissions from new power plants. Finally, in June 2014 it announced plans to limit emissions from existing power plants. This was a crucial step because coal-burning power plants account for a large part of carbon emissions, both in the United States and in the rest of the world.

The answer is blowing in the wind.

But how would new rules affect the economy? A number of politicians and industry groups were quick to assert that the EPA rules would cripple economic growth. For the most part, however, economists disagreed. The EPA’s own analysis suggested that by 2030 its rules would cost the U.S. economy about $9 billion in today’s dollars each year—a trivial sum in an economy that produces $17 trillion of goods and services annually.

Still, the EPA’s proposed rules would at best make a small dent in the problem of climate change. How much would a program that really deals with the problem cost? In April 2014 the U.N. International Panel on Climate Change (IPCC) estimated that global measures limiting the rise in temperatures to 2 degrees centigrade would impose gradually rising costs, reaching about 5% of output by the year 2100. The impact on the world’s rate of economic growth would, however, be small—around 0.06 percentage points each year. The IPCC’s numbers were more or less in line with other estimates; most independent studies have found that environmental protection need not greatly reduce growth.

Why this optimism? At a fundamental level, the key insight is that given the right incentives modern economies can find many ways to reduce emissions, ranging from the use of renewable energy sources (which have grown much cheaper in the past few years) to inducing consumers to choose goods with lower environmental impact. Economic growth and environmental damage don’t have to go together.

Quick Review

  • There’s wide disagreement about whether it is possible to have sustainable long-run economic growth. However, economists generally believe that modern economies can find ways to alleviate limits to growth from natural resource scarcity through the price response that promotes conservation and the creation of alternatives.

  • Overcoming the limits to growth arising from environmental degradation is more difficult because it requires effective government intervention. Limiting the emission of greenhouse gases would require only a modest reduction in the growth rate.

  • There is broad consensus that government action to address climate change and greenhouse gases should be in the form of market-based incentives, like a carbon tax or a cap and trade system. It will also require rich and poor countries to come to some agreement on how the cost of emissions reductions will be shared.

9-5

  1. Question 9.13

    Are economists typically more concerned about the limits to growth imposed by environmental degradation or those imposed by resource scarcity? Explain, noting the role of negative externalities in your answer.

  2. Question 9.14

    What is the link between greenhouse gas emissions and growth? What is the expected effect on growth from emissions reduction? Why is international burden sharing of greenhouse gas emissions reduction a contentious problem?

Solutions appear at back of book.

How Boeing Got Better

When we think about innovation and technological progress, we tend to focus on the big, dramatic changes: cars replacing horses and buggies, electric lightbulbs replacing gaslights, computers replacing adding machines and typewriters. A lot of progress, however, is incremental and almost invisible to most people—yet such unglamorous change can have huge effects over time. Consider, for example, the progress of jet travel, as illustrated by the history of Boeing Corporation.

The Boeing 707, introduced in 1957, was the first commercially successful jetliner, and for a number of years it ruled the skies. When the Beatles made their famous 1964 arrival in America, it was a 707 that brought them there. So what did the 707 look like? What’s striking about it, from a modern perspective, is how ordinary it appears. Basically, it looks like a jet airliner. If you walked past one today, and nobody told you it was an antique, you probably wouldn’t notice; 50-year old jets aren’t nearly as different on the outside from their contemporary descendants as, say, a classic Cadillac—fins and all—is from a modern SUV.

Furthermore, the visible performance of modern jets, like the Boeing 777 or the even more advanced 787, isn’t that much better than those of the old 707. They only fly slightly faster; once you take extra security procedures and air traffic delays into account, traveling from London to New York probably takes more time now than it did in 1964. It’s nice to have a selection of movies (although there never does seem to be anything you want to watch), and business-class travelers now get flatbed seats that make sleeping easier. Still, all of this seems fairly marginal.

Yet Boeing’s modern jets (and those of its main competitor, Airbus) are vastly more efficient than jets half a century ago—so much more efficient that average air fares, adjusted for inflation, are only about a third what they were in 1960. What changed?

The answer is, things passengers can’t see. Most important, there has been a drastic improvement in fuel efficiency, with modern planes using less than a third as much fuel per passenger-mile than their ancestors. Behind this improvement, in turn, lie fundamental changes in engine design (high-bypass engines that direct most of their intake around the combustion chamber rather than through it), small but important improvements in aerodynamics, and the use of new materials to make airframes much lighter.

The moral is that the technological progress that drives growth is much broader and more powerful than meets the eye. Even when things look more or less the same, there is often enormous change beneath the surface.

QUESTIONS FOR THOUGHT

  1. Question 9.15

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    A modern jet airliner does pretty much the same thing as an airliner from the 1960s: it gets you there from here, in about the same time. Where’s the technological progress?

  2. Question 9.16

    2d3XAxc7j7wEhySzGtUtr7vY5uwFi53Z11LWFoO6x818EPQd560qKo+83WnoumjyGuRohMRu1b0nQzDNYTxepl5G7HMu5QAyABGeZcI8h7z6dbrJ
    Do scientific advances play any role in the progress we’ve described? Explain.

  3. Question 9.17

    z3fv3lsnklY0VJTjSN3o3HgBvEmfX5ekOJsRCKXVbM6c6zIugmIA/c2vaJRsR5LoQfAm1VUhYZYwDwRvD5Q0afqcrrmuU5kAHPtzJSsKgy6A2IuMT/752MGHvgXCXSkfUsI56AzCJZf3hGXcyBFBzpubhZzI41efh5k9lmpV1W4=
    Some travelers complain that the flight experience has gone downhill. Does this refute the claim of technological progress?