Investments in “green energy” create jobs, just like any other form of investment in physical assets. We’re told, however, that the transition to renewable energy sources will create a veritable jobs bonanza! Apparently, this is believed to be a great selling point for everyone to get behind. Sure, promoting job creation is always popular with politicians, and it is very popular with private actors seeking to win public funding of one kind or another.
The heavy emphasis on jobs creation brings to mind an old Milton Friedman story about a visit to China during which dignitaries brought him to a construction site, no doubt thinking he’d be impressed with their progressive investments in infrastructure. At the site, Friedman noticed workers digging a large trench or arroyo with shovels. When he asked why bulldozers or backhoes weren’t used, he was told that the jobs were too valuable. His response was something like, “Then have them use spoons!” The lesson, of course, is that merely creating jobs is not a prescription for building wealth and prosperity. But there is more at stake here than the low productivity of construction workers who lack the best tools.
There are some bad rationales for heavy investment in renewable energy sources, and I’ve addressed those at length previously. The appeal to job creation, however, is awful on simple economic grounds. It emphasizes a thing that is easily counted while ignoring massive costs that are generally untallied.
In the U.S. we have a huge base of productive capital that meets our energy needs, the bulk of which is built to utilize fossil fuels. That plant constitutes wealth to society, and not just to those with an ownership interest. Dispatchable power is available to the public at a rate below that at which they value the power. That ability to deliver consumer surplus on demand is a major aspect qualifying power capacity as societal wealth. The push for renewables, if wholly successful, would make the existing base of generating capacity redundant. There is no doubt that the ultimate goal of renewable energy advocates is to destroy existing capacity reliant on fossil fuels. They simply have not come to grips with the reality that it meets energy needs far more efficiently than intermittent renewables like wind and solar power. In spirit, the effort bears a strong similarity to destroying bulldozers to replace them with shovels, or spoons!
Recently, Michael Munger discussed the mistaken notion that renewable investments are justified based on job creation. He noted that with a coincident dismantling of the existing base of power generation, it amounts to exactly what Frederic Bastiat called thebroken window fallacy, which insists that breaking windows is a great way to keep glaziers fully employed. There are many examples and variations on this idea, including so-called “planned obsolescence”.
Bastiat poked fun at an elite French government official who had marveled at the economic gains reaped in England with the rebuilding of London following the “Great Fire” of 1666. Bastiat engaged in some satire by suggesting that France could greatly benefit from burning Paris to the ground. But his point was serious: we often hear that reconstruction provides a silver lining for workers following hurricanes or other disasters. Fair enough: rebuild we must. The Keynesians among us would say it works out well for workers who are otherwise unemployed. Disasters destroy wealth, however, and often lives, not to mention opportunities for incremental wealth creation that are lost forever. The reconstruction jobs are not “good news”!
Unfortunately, people get carried away with broken windows arguments, using them to justify their own pet projects. The addition of new competing products and technologies is unquestionably healthy, but not when one side enlists the state as a partner in destroying viable incumbents and existing public or private wealth. For that matter, the state and its allies seem intent on destroying invested physical capital even before it’s services can come on line… if it’s viewed as the “wrong” kind of capital.
The costs of a transition to renewables is massive. The “big ask” for green energy involves not just taxpayer support for the build and usage, with all the inefficiencies endemic to taxation and market interventions. So-called green energy also entails huge environmental costs, and it calls for the wholesale destruction of an embedded industry. That means decommissioning invested assets having many years of useful life. And that goes for physical plant all the way from the wellhead to final use, including the destruction of stoves, cars, and other machines too numerous to mention. Those machines, by the way, still account for roughly 80% of our power use.
I leave you with part of Munger’s closing:
“Once you are duped into believing destruction is productive, almost everything that a rational public policy would label as a cost becomes, by some judo move of seraphic intuition, a benefit. … The problem is that jobs are not wealth. Wealth is access to the goods, products, and services that make our lives better. It is true that ‘studies show’ that wiping out all our productive wealth based on fossil fuels … would create jobs. Those ‘studies’ are among the best arguments against doing anything of the sort.”
Despite evidence to the contrary, there’s one thing climate change alarmists seem to consider a clincher. Well… their stylized account has the seas absorbing heat from our warming atmosphere as human activity forces carbon emissions into the air. That notion seems to be reinforced, at least in the popular imagination, by the fact that the sea is a “carbon sink”, but that is a matter of carbon sequestration and not a mechanism of ocean warming. While ocean temperatures have warmed slightly over the past few decades, it is almost entirely coincidental, rather than a result of slightly warmer air temperatures.
Heat and the Hydrosphere
There is no doubt that the oceans store heat very efficiently, but that heat comes primarily from solar radiation and geothermal sources underseas. In fact, water stores heat far more efficiently than the atmosphere. According to Paul Homewood, a given cross section of sea water to a depth of just 2.6 meters is capable of holding as much heat as a column of air of the same width extending from the ocean surface to the outermost layers of the atmosphere! (See here for an earlier reference.) However, that does not imply that the oceans are very effective at drawing heat from warmer air or particularlycarbon back-radiation. Both the air and water draw heat from solar radiation, and how much in any given location depends on the Sun’s angle in the sky.
A solid guide is that air temperatures are heavily influenced by water temperatures, but not as much vice versa. When temperatures in the upper layers of the ocean rise from natural forces, including reduced upward circulation from greater depths, evaporation causes this heat to radiate into the atmosphere along with evaporation of water vapor. Homewood notes that El Niño patterns make the influence of the Pacific Ocean waters on climate pretty obvious. The impact of the Gulf Stream on European climates is also instructive.
The Indian Ocean accounted for about half of the sea warming that occurred within the globe’s top 700 meters of waters over the years 2000 – 2019, though the Indian Ocean represents only about 20% of the world’s sea surface. The authors of that research found that the warming was not caused by trends in surface forcing of any kind, including warmer air temperatures. They said the ocean warming:
“… has been driven by significant changes in oceanic fluxes and not by surface forcing. … the ocean has been driving a rapid increase in Indian Ocean heat content.”
This was consistent with an earlier study of global sea temperatures covering the period 1984 – 2006 that found:
“… diminished ocean cooling due to vertical ocean processes … A conclusion is that natural variability, rather than long-term climate change, dominates the SST [sea surface temperature] and heat flux changes over this 23-yr period.”
It’s a Water World
Heat released by the oceans tends to dominate variations in global temperatures. A 2018 study found that evaporative heat transfer to the atmosphere from the oceans was closely associated with variations in air temperatures:
“When the atmosphere gets extra warm it receives more heat from the ocean, when it is extra cool it receives less heat from the ocean, making it clear that the ocean is the driving force behind these variations. …
The changes in solar radiation received at the Earth’s surface are clearly a trigger for these variations in global mean temperature, but the mechanisms by which these changes occur are a bit more complex and depend on the time-scale of the changes.”
Measurement
Willis Eschenbach reviewed a prominent study of ocean temperature changes and noted that the authors’ estimate of total warming of the oceans was quite small:
“… over the last sixty years, the ocean has warmed a little over a tenth of one measly degree … now you can understand why they put it in zettajoules—it’s far more alarming that way.”
Eschenbach goes on to discuss the massive uncertainty underlying measurements of ocean temperatures, particularly below a depth of 2,000 meters, but even well above that depth given the extremely wide spacing of so-called ARGO floats. However, the relative stability of the point estimates over 60 years is noteworthy, not to mention the “cold water” doused on alarmist claims about ocean overheating.
Sun Engine
Ocean warmth begins with energy from the Sun and from the deep interior of the Earth. The force of solar energy is greatest in the tropics, where sunlight is perpendicular to the surface of the Earth and is least dispersed by the thickness of the atmosphere. The sun’s radiative force is smallest in the polar regions, where the angle of its light is acute. As Anthony Watts says:
“All elements of Earth’s weather, storm fronts, hurricanes, the jet stream, and even ocean currents, are driven to redistribute energy from the tropics to the poles.”
Both land and sea absorb heat from the Sun and from volcanic activity, though the heat is moderated by the sea. That moderation is especially impactful in the Southern Hemisphere, which has far less land area, greater exposure of sea surface to the Sun, and about half of the average ocean temperature variation experienced in the North.
Ultimately, the importance of natural sunlight on air and sea temperatures can’t be overemphasized. Henrik Svensmark and some co-authors have estimated that a cosmic ray flux of 15% from a coronal mass ejection leads to a reduction in cloud cover within roughly 9 – 12 days. The ultimate increase in the Earth’s “energy budget” over about a week’s time is about the same size as a doubling of CO2, which certainly puts things in perspective. However, the oceans, and hence cloud cover, moderate the impact of the Sun, with or without the presence of additional greenhouse gases forced by human activity.
Vapors
The importance of evaporation from bodies of water also deserves great emphasis. No one doubts the massive influence of greenhouse gases (GHGs) on the climate. Water vapor accountsfor about 90% of GHGs, and it originates predominantly from oceans. Meanwhile, carbon dioxide accounts for less than 4% of GHGs, and it appears that only a small part is from anthropogenic sources (and see here and below).
The impact of changing levels of water vapor dominates GHG levels. They are also a critical input to cloud formation, a phenomenon that climate models are generally ill-equipped to explain. Clouds reflect solar radiation back into space, reducing the Sun’s net contribution to the Earth’s energy budget. On the other hand, clouds can trap heat in the lower layers of the atmosphere. The globe has an average of 60 – 70% cloud cover, and most of that is over the oceans. Increased cloud cover generally leads to declines in temperature.
A 2015 study identified a process through which the sea surface has an unexpectedly large impact on climate. This was from the formation of isoprene, a film on the ocean surface, which leads to more cloud formation. In addition to biological sources, isoprene was found to originate, surprisingly, from the effect of sunlight.
The Big Sink
Man-made emissions of CO2 constitute only about 5% of naturally discharged CO2, which is roughly matched by natural removal. CO2 is absorbed, dissolved, or transformed in a variety of ways on both land and sea, but the oceans collectively represent the world’s largest carbon sink. They hold about 50 times more CO2 than the atmosphere. Carbon is stored in sea water at great depths, and it enhances undersea vegetation just as it does on land. It is sequestered in a variety of sea organisms as calcium carbonate and is locked in sediments as well. A longstanding question is whether there is some limit on the capacity of the oceans and other sinks to store carbon, but apparently the uptake over time has remained roughly constant at just under 50% of all natural and man-made CO2 emissions (also see here). So far, we don’t appear to be approaching any sort of “saturation point”.
One claim about the rising carbon stored undersea is that it will drive down the oceans’ pH levels. In other words, it will lead to “ocean acidification” and harm a variety of marine life. Rud István has ridiculed that term (quite rightly) because slightly less alkaline sea water does not make it “acidic”. More substantively, he notes the huge natural variations in ocean pH levels across different marine environments, the exaggeration inherent in some estimates of pH changes that do not account for physical buffering, and the fact that the impact on many organisms is inconsistent with the presumed harms of reduced pH. In fact, errors in some of the research pointing to those harms has been acknowledged. In addition, the much feared “coral crisis” seems to have been a myth.
Conclusion
The upper layers of the oceans have warmed somewhat over the past 60 years, but the warming had natural causes. Heat transfer from the atmosphere to the hydrosphere is relatively minor compared to the absorption of heat by oceans via solar forcings. It is also minor compared to the transfer of temperature from oceans to surface air. As Jim Steele has explained it:
“Greenhouse longwave energy penetrates only a few microns into the ocean surface and even less into most soils, but the sun’s shortwave energy passes much more deeply into the ocean.”
It’s reasonable to concede that warmer air temperatures via man-made GHGs might be a minor reinforcement to natural sources of ocean warming, or it might slightly moderate ocean cooling. However, measuring that contribution would be difficult against the massive background of natural forcings on ocean temperatures.
Oceans are dominant in terms of heat storage from natural forcings and in terms of carbon sequestration. In fact, the oceans have thoroughly outperformed alarmist projections as a carbon sink. Dire prognostications of the effect of carbon dioxide on marine life have been drastically over-emphasized as well.
A copy of a post from last week appears below. This was necessary because two of the sites to which I cross-post required a revised link. I don’t know why, but they did.
A few weeks ago I argued that raising living standards and eliminating poverty are human imperatives, and therefore growth is an imperative. Growth is a natural process for a free and creative people, and the alternative to growth is not zero growth. The coercion necessary to “achieve” a static economic environment would invariably lead to decline. It would be impossible to maintain average living standards while attempting a coerced leveling of those standards.
People have a notion, however, that it’s impossible to sustain growth due to the planet’s finite base of resources. If that is the case, we have available a mechanism to warn us as the time of hard limits approaches, which I’ll discuss below. So far, that signal hasn’t been activated. Moreover, the claim that growth is unsustainable can be challenged on several levels, which I’ll also address.
Effective Resources
First, a word about what I mean by the “accretion of resources”. The phrase refers to growth in the total effectiveness or productive potential of known resources given the rate of discovery and improvements in extraction and production technologies. Of course, if these discoveries and efficiencies are exceeded by current use, then there is no accretion, but depletion.
So let’s say we have a particular known stock of a resource we can readily draw on, so many pounds of resource X. In addition, we might know of the existence of another equally large quantity that can’t be readily drawn upon. Those are additional known (or proved) but undeveloped reserves. They might be difficult to exploit except at high cost, but we know they exist. We’d want to get on with the business of developing those reserves for extraction if they were needed any time soon, and we might want to begin prospecting for new reserves as well. As we’ve learned over the years. discoveries of previously unknown reserves of resources can be quite large. Prospectors are willing to bet that more resources exist, and they’ll undertake the risks of exploration if the potential rewards are adequate.
All of those concepts are straightforward. However, suppose we discover ways in which resource X can be used more efficiently, making things stronger or run longer or harder with less X. If we double the efficiency with which X is used, we have doubled the effective known reserves of X and, at least theoretically, unknown reserves as well. We’d have witnessed a doubling in the years that resource X can last. This is a form of resource accretion. Improvements in extraction or purification methods are also examples. Technological leaps like this, not to mention untold small increments in the efficiency of practices, have made economic growth possible in the past and will continue to do so in the future. Our effective resources seem to keep expanding. Accretion has occurred even with respect to resources like land as the world urbanized and the efficiency of farming advanced many-fold.
Growth In Real Time
Perceptions of growth are sometimes shaped by graphic depictions that some parties find alarming, so it might be helpful to take a quick look at some growth curves. First is an oldie-but-goodie chart showing GDP per capita taken from “Statistics on World Population, GDP, and Per Capital GDP, 1- 2008 AD” by Angus Maddison of the IMF:
This shows the explosion in the value of production that occurred during and after the industrial revolution, in contrast to very slow progress before that. The point I want to make here is how dramatic growth can look on a broad but visually compressed time scale. OMG! Look what we’ve done! How can we go on like this??? Often, the crux of the limits to growth argument is that such growth seems impossible assuming that we face fixed resource limits.
In fact, we experience growth in a very “local” way with respect to the passage of time. The two charts below illustrate a difference in perspectives using a hypothetically constant annual growth rate of 2.5%. The first chart shows 200 periods of growth, while the second expands only the last 20 periods of that time frame.
There is a great difference in the way the two vertical axes are scaled, which is important, but the second chart conveys that a respectable growth rate doesn’t really feel extreme when you’re in the middle of it, or, that is, in real time. It can look very extreme at the end of a long interval, depending on how severely the time axis is compressed. That’s not to discount the reality of much larger levels of activity (the vertical axes) and demands for resources as time goes on. However, those levels, and growth from those levels, is not at all alarming if our ability to achieve them has kept pace. So how can we know when we’re approaching a point at which resource limits will make it impossible to achieve those levels of activity? Market prices are the key signals, and they are the key to resource accretion.
Market Signals Light the Way
The market price is the best gauge of the scarcity of a resource. When resources become especially scarce, higher prices tell us so. That leads to conservation, which obviously extends the availability of those resources. Prices also function as an incentive for sellers to exploit new or harder-to-reach stores of a resource. That kind of resource accretion is one of the lessens the oil market has taught us again and again: oil exploration and known reserves tend to expand as the price rises, such that the prospect of oil depletion moves out to ever more distant horizons. There are certain minerals, elements, or isotopes (tritium?) that seem to be quite rare on Earth, but our ability to find them or extract them often improves with time. Space mining, which would vastly reduce the scarcity of resources like platinum, iron, nickel, cobalt, and many others, may become a reality in the near future. Interestingly, much of that activity could be in private hands. Space mining would lead to resource accretion on a whole new scale, and if we aspire to be a “grabby” civilization, it is a logical next step. So let’s go grab an asteroid!
When a price spikes due to greater scarcity, opportunities for substitution, exploration, and new efficiencies arise because the higher price justifies the cost of exploiting them. In addition to more difficult or costly extraction, a higher price encourages the use of close and even novel substitutes that may involve new technologies. In turn, that substitution reduces the relative scarcity of the original resource in question. And finally, back to conservation, users respond to price increases by finding their own innovative efficiencies in how a resource is utilized. The price response to scarcity is a channel through which much technological progress is encouraged.
While our earth-bound resources or even our star-system’s resources are finite, their effective quantity is highly flexible. Their potential at any time depends on our stage of discovery and the state of technology. Human ingenuity is a marvel at stretching the effective quantity of resources, and the greatest gains always occur when market forces are unleashed.
Thus, we see that prices, markets, and capitalism itself enable rational and sustainable responses to scarcity. Yet too often we hear claims that capitalism must be destroyed in order to save humanity. In fact, capitalism itself is the one system of social organization capable of achieving resource accretion, sustained growth, and lifting mankind from poverty. In fact, growth might well be an insurmountable problem without the dynamic energies of capitalism. Government planners are incapable of gathering and processing the vast information that markets process each and every day. Planners must substitute their own weak judgements, which prove flawed again and again.
Scarcity of the Commons
The environmental Left is quick to marshal a different kind of limits-to-growth argument. This one has to do with the scarcity of non-priced common resources and their overuse in production. For example, if a certain activity degrades the environment and those costs are not internalized by producers, they will tend to produce “too much”, leading to some degree of deterioration in human living conditions or the natural quality of the environment. In that case, we might not notice the limits to growth bearing down on us before corrective action is taken. Or so goes the theory that accumulating externalities lead to catastrophe. This is another front along which the limits to growth are asserted, particularly by climate alarmists and the environmental Left. Most prominently today, they contend that increases in atmospheric carbon concentration will lead to an unlivable warming of Earth’s climate.
Sense and Nonsense
The most glaring shortcoming of climate change advocacy is that the trends it decries are exaggerated. I’ve discussed the absurdly brief climate record cited by alarmists in several past posts (many of which appear here). We can start with the contention that carbon emissions are “poison”. In fact, carbon is life nourishing, as we’ve witnessed with the “greening” of the planet at current carbon concentrations of 4 parts per 10,000 of atmospheric gas. Furthermore, a longer historical temperature record using paleoclimate data shows that we are well within the range of past variation, even with the huge distortions to the record caused by urban heat islands and questionable downward adjustments to records of five to 15 decades ago.
The alarmist perspective is also inflamed by simplistic models of carbon forcing that ignore the impact of solar radiation, volcanic activity, and the behavior of aerosols in the atmosphere. Those models have consistently over-predicted temperature trends for decades. Equally troubling is that these models promote the fiction that mankind can control global temperatures by a little fiddling with a “carbon dial”, as if such fiddling could be accomplished without a massive centralization of political and economic power. The panicked narratives related to sea level increases and alleged increases in violent weather are equally flawed.
Growth Can Cure It
Another compelling response to climate arguments against growth is that technological advances have already enabled us to produce power without carbon emissions. Unfortunately, as a matter of public policy (regulation and bad choices by government industrial planners), we have increasingly failed to avail ourselves of these opportunities, instead choosing extremely wasteful methods of generating power. These are the windmill and solar “renewables”, which are resource-intensive, intermittent, low utilization, non-dispatchable, lacking storage for excess generation, intensive in land use (reversing prior accretions), and environmentally disastrous in fabrication, operation, and at disposal. Nuclear power is a far superior technology, especially with the advent of small, modular reactors and potential breakthroughs in fusion energy. These might help to rescue us from the spectacle of bone-headed industrial planning and greedy, renewable-energy rent seekers, but regulators have done seemingly all they can to prevent nuclear facilities from being built.
Just as human ingenuity is capable of expanding the exploitable stock of tradable, priced resources, it is also capable of inventing non-carbon power technologies that are more efficient and less environmentally destructive than ground-based solar and wind. Collection of non-intermittent solar energy in space arrays with wireless transmission to Earth is another promising alternative, as is geothermal energy. And carbon capture technologies show promise for neutralizing emissions or perhaps even reversing carbon concentrations one day, if that is deemed necessary. Much of this development work is in private hands, but barring drastic reductions in scale, the bulk of these efforts are (or will be) dependent on government funding.
It’s worth acknowledging here that resource accretion has a safety component in an expected value sense. Sometimes those risks can be internalized if risk reduction is of value to buyers. But the costs of “reasonable” risk mitigation cannot always be internalized without government action. For example, deflecting asteroid threats to the planet might be done best by private actors, but paying for that activity is a worthy application of public finance. The ability to deflect incoming asteroids is a noteworthy example of resource accretion via risk reduction.
Somehow, governments must be convinced to begin dedicating a larger share of the vast sums they spend on misguided climate interventions (including renewable technologies) to more sensible innovations. We might then benefit from accelerated breakthroughs that would settle not only our energy future, but a great deal of political strife as well. Like the market response to changes in scarcity, creative entrepreneurs will always step forward to compete for government funding. But if you pay them for crap, you’ll get a lot of crap!
Growth Once More
One day we might learn we are reaching the top of an s-curve. We aren’t there yet, if our ongoing accretion of resources is any guide, and there are new frontiers of space and technology to explore. The primary obstacles we face are not natural, but political and regulatory.
One area neglected above is the accretion of human capital. Certainly education is another way to expand our boundaries. However, population growth (and therefore labor force growth) tends to slow as living standards rise, and many argue that demographics have already become a drag on growth. A shrinking and aging population places a tremendous burden on young workers, making other sources of growth and productivity all the more critical. But new physical capital, resource development (including education), and new technologies can all continue to drive productivity and growth.
Growth depends on resource accretion, and there are many ways in which our effective stock of resources can be expanded. That includes enhancements in quantities, efficiencies, and safety. Private investment should be the primary avenue through which these are accomplished, which in turn requires flows of saving. Those flows are much more difficult to conjure without growth, so we have a chicken and egg cross-dependency. But chickens will lay eggs, just as saving and all kinds of investment will take place given the right incentives. Those would promote expansion in our effective stock of resources, improved adaptation to change, and enhanced well being. In the end, the rationale is simple: ending poverty requires growth.
Addendum: I just noticed that Don Boudreaux posted (and beautifully elaborated upon) this great Julian Simon quote:
“The quantity of a natural resource that might be available to us – and even more important the quantity of the services that can eventually be rendered to us by that natural resource – can never be known even in principle, just as the number of points in a one-inch line can never be counted even in principle.”
A few weeks ago I argued that raising living standards and eliminating poverty are human imperatives, and therefore growth is an imperative. Growth is a natural process for a free and creative people, and the alternative to growth is not zero growth. The coercion necessary to “achieve” a static economic environment would invariably lead to decline. It would be impossible to maintain average living standards while attempting a coerced leveling of those standards.
People have a notion, however, that it’s impossible to sustain growth due to the planet’s finite base of resources. If that is the case, we have available a mechanism to warn us as the time of hard limits approaches, which I’ll discuss below. So far, that signal hasn’t been activated. Moreover, the claim that growth is unsustainable can be challenged on several levels, which I’ll also address.
Effective Resources
First, a word about what I mean by the “accretion of resources”. The phrase refers to growth in the total effectiveness or productive potential of known resources given the rate of discovery and improvements in extraction and production technologies. Of course, if these discoveries and efficiencies are exceeded by current use, then there is no accretion, but depletion.
So let’s say we have a particular known stock of a resource we can readily draw on, so many pounds of resource X. In addition, we might know of the existence of another equally large quantity that can’t be readily drawn upon. Those are additional known (or proved) but undeveloped reserves. They might be difficult to exploit except at high cost, but we know they exist. We’d want to get on with the business of developing those reserves for extraction if they were needed any time soon, and we might want to begin prospecting for new reserves as well. As we’ve learned over the years. discoveries of previously unknown reserves of resources can be quite large. Prospectors are willing to bet that more resources exist, and they’ll undertake the risks of exploration if the potential rewards are adequate.
All of those concepts are straightforward. However, suppose we discover ways in which resource X can be used more efficiently, making things stronger or run longer or harder with less X. If we double the efficiency with which X is used, we have doubled the effective known reserves of X and, at least theoretically, unknown reserves as well. We’d have witnessed a doubling in the years that resource X can last. This is a form of resource accretion. Improvements in extraction or purification methods are also examples. Technological leaps like this, not to mention untold small increments in the efficiency of practices, have made economic growth possible in the past and will continue to do so in the future. Our effective resources seem to keep expanding. Accretion has occurred even with respect to resources like land as the world urbanized and the efficiency of farming advanced many-fold.
Growth In Real Time
Perceptions of growth are sometimes shaped by graphic depictions that some parties find alarming, so it might be helpful to take a quick look at some growth curves. First is an oldie-but-goodie chart showing GDP per capita taken from “Statistics on World Population, GDP, and Per Capital GDP, 1- 2008 AD” by Angus Maddison of the IMF:
This shows the explosion in the value of production that occurred during and after the industrial revolution, in contrast to very slow progress before that. The point I want to make here is how dramatic growth can look on a broad but visually compressed time scale. OMG! Look what we’ve done! How can we go on like this??? Often, the crux of the limits to growth argument is that such growth seems impossible assuming that we face fixed resource limits.
In fact, we experience growth in a very “local” way with respect to the passage of time. The two charts below illustrate a difference in perspectives using a hypothetically constant annual growth rate of 2.5%. The first chart shows 200 periods of growth, while the second expands only the last 20 periods of that time frame.
There is a great difference in the way the two vertical axes are scaled, which is important, but the second chart conveys that a respectable growth rate doesn’t really feel extreme when you’re in the middle of it, or, that is, in real time. It can look very extreme at the end of a long interval, depending on how severely the time axis is compressed. That’s not to discount the reality of much larger levels of activity (the vertical axes) and demands for resources as time goes on. However, those levels, and growth from those levels, is not at all alarming if our ability to achieve them has kept pace. So how can we know when we’re approaching a point at which resource limits will make it impossible to achieve those levels of activity? Market prices are the key signals, and they are the key to resource accretion.
Market Signals Light the Way
The market price is the best gauge of the scarcity of a resource. When resources become especially scarce, higher prices tell us so. That leads to conservation, which obviously extends the availability of those resources. Prices also function as an incentive for sellers to exploit new or harder-to-reach stores of a resource. That kind of resource accretion is one of the lessens the oil market has taught us again and again: oil exploration and known reserves tend to expand as the price rises, such that the prospect of oil depletion moves out to ever more distant horizons. There are certain minerals, elements, or isotopes (tritium?) that seem to be quite rare on Earth, but our ability to find them or extract them often improves with time. Space mining, which would vastly reduce the scarcity of resources like platinum, iron, nickel, cobalt, and many others, may become a reality in the near future. Interestingly, much of that activity could be in private hands. Space mining would lead to resource accretion on a whole new scale, and if we aspire to be a “grabby” civilization, it is a logical next step. So let’s go grab an asteroid!
When a price spikes due to greater scarcity, opportunities for substitution, exploration, and new efficiencies arise because the higher price justifies the cost of exploiting them. In addition to more difficult or costly extraction, a higher price encourages the use of close and even novel substitutes that may involve new technologies. In turn, that substitution reduces the relative scarcity of the original resource in question. And finally, back to conservation, users respond to price increases by finding their own innovative efficiencies in how a resource is utilized. The price response to scarcity is a channel through which much technological progress is encouraged.
While our earth-bound resources or even our star-system’s resources are finite, their effective quantity is highly flexible. Their potential at any time depends on our stage of discovery and the state of technology. Human ingenuity is a marvel at stretching the effective quantity of resources, and the greatest gains always occur when market forces are unleashed.
Thus, we see that prices, markets, and capitalism itself enable rational and sustainable responses to scarcity. Yet too often we hear claims that capitalism must be destroyed in order to save humanity. In fact, capitalism itself is the one system of social organization capable of achieving resource accretion, sustained growth, and lifting mankind from poverty. In fact, growth might well be an insurmountable problem without the dynamic energies of capitalism. Government planners are incapable of gathering and processing the vast information that markets process each and every day. Planners must substitute their own weak judgements, which prove flawed again and again.
Scarcity of the Commons
The environmental Left is quick to marshal a different kind of limits-to-growth argument. This one has to do with the scarcity of non-priced common resources and their overuse in production. For example, if a certain activity degrades the environment and those costs are not internalized by producers, they will tend to produce “too much”, leading to some degree of deterioration in human living conditions or the natural quality of the environment. In that case, we might not notice the limits to growth bearing down on us before corrective action is taken. Or so goes the theory that accumulating externalities lead to catastrophe. This is another front along which the limits to growth are asserted, particularly by climate alarmists and the environmental Left. Most prominently today, they contend that increases in atmospheric carbon concentration will lead to an unlivable warming of Earth’s climate.
Sense and Nonsense
The most glaring shortcoming of climate change advocacy is that the trends it decries are exaggerated. I’ve discussed the absurdly brief climate record cited by alarmists in several past posts (many of which appear here). We can start with the contention that carbon emissions are “poison”. In fact, carbon is life nourishing, as we’ve witnessed with the “greening” of the planet at current carbon concentrations of 4 parts per 10,000 of atmospheric gas. Furthermore, a longer historical temperature record using paleoclimate data shows that we are well within the range of past variation, even with the huge distortions to the record caused by urban heat islands and questionable downward adjustments to records of five to 15 decades ago.
The alarmist perspective is also inflamed by simplistic models of carbon forcing that ignore the impact of solar radiation, volcanic activity, and the behavior of aerosols in the atmosphere. Those models have consistently over-predicted temperature trends for decades. Equally troubling is that these models promote the fiction that mankind can control global temperatures by a little fiddling with a “carbon dial”, as if such fiddling could be accomplished without a massive centralization of political and economic power. The panicked narratives related to sea level increases and alleged increases in violent weather are equally flawed.
Growth Can Cure It
Another compelling response to climate arguments against growth is that technological advances have already enabled us to produce power without carbon emissions. Unfortunately, as a matter of public policy (regulation and bad choices by government industrial planners), we have increasingly failed to avail ourselves of these opportunities, instead choosing extremely wasteful methods of generating power. These are the windmill and solar “renewables”, which are resource-intensive, intermittent, low utilization, non-dispatchable, lacking storage for excess generation, intensive in land use (reversing prior accretions), and environmentally disastrous in fabrication, operation, and at disposal. Nuclear power is a far superior technology, especially with the advent of small, modular reactors and potential breakthroughs in fusion energy. These might help to rescue us from the spectacle of bone-headed industrial planning and greedy, renewable-energy rent seekers, but regulators have done seemingly all they can to prevent nuclear facilities from being built.
Just as human ingenuity is capable of expanding the exploitable stock of tradable, priced resources, it is also capable of inventing non-carbon power technologies that are more efficient and less environmentally destructive than ground-based solar and wind. Collection of non-intermittent solar energy in space arrays with wireless transmission to Earth is another promising alternative, as is geothermal energy. And carbon capture technologies show promise for neutralizing emissions or perhaps even reversing carbon concentrations one day, if that is deemed necessary. Much of this development work is in private hands, but barring drastic reductions in scale, the bulk of these efforts are (or will be) dependent on government funding.
It’s worth acknowledging here that resource accretion has a safety component in an expected value sense. Sometimes those risks can be internalized if risk reduction is of value to buyers. But the costs of “reasonable” risk mitigation cannot always be internalized without government action. For example, deflecting asteroid threats to the planet might be done best by private actors, but paying for that activity is a worthy application of public finance. The ability to deflect incoming asteroids is a noteworthy example of resource accretion via risk reduction.
Somehow, governments must be convinced to begin dedicating a larger share of the vast sums they spend on misguided climate interventions (including renewable technologies) to more sensible innovations. We might then benefit from accelerated breakthroughs that would settle not only our energy future, but a great deal of political strife as well. Like the market response to changes in scarcity, creative entrepreneurs will always step forward to compete for government funding. But if you pay them for crap, you’ll get a lot of crap!
Growth Once More
One day we might learn we are reaching the top of an s-curve. We aren’t there yet, if our ongoing accretion of resources is any guide, and there are new frontiers of space and technology to explore. The primary obstacles we face are not natural, but political and regulatory.
One area neglected above is the accretion of human capital. Certainly education is another way to expand our boundaries. However, population growth (and therefore labor force growth) tends to slow as living standards rise, and many argue that demographics have already become a drag on growth. A shrinking and aging population places a tremendous burden on young workers, making other sources of growth and productivity all the more critical. But new physical capital, resource development (including education), and new technologies can all continue to drive productivity and growth.
Growth depends on resource accretion, and there are many ways in which our effective stock of resources can be expanded. That includes enhancements in quantities, efficiencies, and safety. Private investment should be the primary avenue through which these are accomplished, which in turn requires flows of saving. Those flows are much more difficult to conjure without growth, so we have a chicken and egg cross-dependency. But chickens will lay eggs, just as saving and all kinds of investment will take place given the right incentives. Those would promote expansion in our effective stock of resources, improved adaptation to change, and enhanced well being. In the end, the rationale is simple: ending poverty requires growth.
Addendum: I just noticed that Don Boudreaux posted (and beautifully elaborated upon) this great Julian Simon quote:
“The quantity of a natural resource that might be available to us – and even more important the quantity of the services that can eventually be rendered to us by that natural resource – can never be known even in principle, just as the number of points in a one-inch line can never be counted even in principle.”
It’s as if people view the debt limit controversy as a political nuisance rather than the stopgap enforcement mechanism for fiscal sanity that it’s intended to be. That’s a lesson in how far we’ve gone toward an unhealthy acceptance of permanent federal deficits. Oh, most people seem to realize the the government’s spending is prodigious and beyond our capacity to collect taxes, but many don’t grasp the recklessness of the ongoing blowout. Federal deficits are expected to average $1.6 trillion per year over the next decade, versus less than $0.9 trillion and $1.25 trillion over the two previous decades, respectively. That $1.25 trillion includes the massive (and excessive) transfers that took place during the pandemic, which is why we’ve bumped up against the debt limit earlier than had been expected. The trend isn’t abating, despite the fact that the pandemic is behind us. And keep in mind that the Congressional Budget Office has been too optimistic for the past 20 years or so. Take a look at federal debt relative to GDP:
Unpleasant Arithmetic
With federal debt growing faster than GDP, the burden of servicing the debt mounts. This creates a strain in the coordination of fiscal and monetary policy, as described by David Andolfatto, who last year reviewed the implications of “Some Unpleasant Monetarist Arithmetic” for current policy. His title was taken from a seminal paper written by Thomas Sargent and Neil Wallace in 1981. Andolfatto says that:
“… attempting to monetize a smaller fraction of outstanding Treasury securities has the effect of increasing the rate of inflation. A tighter monetary policy ends up increasing the interest expense of debt issuance. And if the fiscal authority is unwilling to curtail the rate of debt issuance, the added interest expense must be monetized—at least if outright default is to be avoided.
Andolfatto wrote that last spring, before the Federal Reserve began its ongoing campaign to tighten monetary policy by raising short-term interest rates. But he went on to say:
“Deficit and debt levels are elevated relative to their historical norms, and the current administration seems poised to embark on an ambitious public spending program. … In the event that inflation rises and then remains intolerably above target, the Federal Reserve is expected to raise its policy rate. … if the fiscal authority is determined to pursue its deficit policy into the indefinite future, raising the policy rate may only keep a lid on inflation temporarily and possibly only at the expense of a recession. In the longer run, an aggressive interest rate policy may contribute to inflationary pressure—at least until the fiscal regime changes.”
So it is with a spendthrift government: escalating debt and interest expense must ultimately be dealt with via higher taxes or inflation, despite the best intentions of a monetary authority.
Fiscal Wrasslin’
Some people think the debt limit debate is all a big fake. Maybe … there are spendthrifts on both sides of the aisle. Still, the current debt limit impasse could serve a useful purpose if fiscal conservatives succeed in efforts to restrain spending. There is, however, an exaggerated uproar over the possibility of default, meaning a failure to make scheduled payments on Treasury securities. The capital markets aren’t especially worried because an outright default is very unlikely. Establishment Republicans may well resort to their usual cowardice and accept compromise without holding out for better controls on spending. Already, in a politically defensive gesture, House Speaker Kevin McCarthy has said the GOP wishes to strengthen certain entitlement programs. Let’s hope he really means restoring solvency to the Social Security and Medicare Trust Funds via fundamental reforms. And if the GOP rules out cuts to any program, let’s hope they don’t rule out cuts in the growth of these programs, or privatization. For their part, of course, Democrats would like to eliminate the debt ceiling entirely.
One of the demands made by Republicans is a transformation of the federal tax system. They would like to eliminate the income tax and substitute a tax on consumption. Economists have long favored the latter because it would eliminate incentives that penalize saving, which undermine economic growth. Unfortunately, this is almost dead in the water as a political matter, but the GOP further sabotaged their own proposal in their zeal to abolish the IRS. Their consumption tax would be implemented as a national sales tax applied at the point of sale, complete with a new Treasury agency to administer the tax. They’d have done better to propose a value added tax (VAT) or a tax on a simple base of income less saving (and other allowances).
Gimmicks and Measures
We’ve seen proposals for various accounting tricks to allow the government to avoid a technical default and buy time for an agreement to be reached on the debt limit. Treasury Secretary Janet Yellen already has implemented “extraordinary measures” to stay under the debt limit until June, she estimates. The Treasury is drawing down cash, skipping additional investments in government retirement accounts (which can be made up later without any postponement of benefits), plus a few other creative accounting maneuvers.
Payment prioritization, whereby the Treasury makes payments on debt and critical programs such as Social Security and Medicare, but defers a variety of other payments, has also been considered. Those deferrals could include amounts owed to contractors or even government salaries. However, a deferral of payments owed to anyone represents a de facto default. Thus, payment prioritization is not a popular idea, but if push comes to shove, it might be viewed as the lesser of two evils. Missing payments on government bonds could precipitate a financial crisis, but no one believes it will come to that.
Two other ideas for avoiding a breach of the debt ceiling are rather audacious. One involves raising new cash via the sale of premium bonds by the Treasury, as described here by Josh Barro (and here by Matt Levine). The other idea is to mint a large denomination ($1 trillion) platinum, “commemorative” coin, which the Treasury would deposit at the Federal Reserve, enabling it to conduct business as usual until the debt limit impasse is resolved. I’ll briefly describe each of these ideas in more detail below.
Premium Bonds
Premium bonds would offer a solution to the debt limit controversy because the debt ceiling is defined in terms of the par value of Treasury debt outstanding, as opposed to the amount actually raised from selling bonds at auction. For example, a note that promises to pay $100 in one year has a par value of $100. If it also promises to pay $100 in interest, it will sell at a steep premium. Thus, the Treasury collects, say, $185 at auction, and it could use the proceeds to pay off $100 of maturing debt and fund $85 of federal spending. That would almost certainly require a “market test” by the Treasury on a limited scale, and the very idea might reveal any distaste the market might have for obviating the debt limit in this fashion. But distaste is probably too mild a word.
An extreme example of this idea is for the Treasury to sell perpetuities, which have a zero par value but pay interest forever, or at least until redeemed beyond some minimum (but lengthy) term. John Cochrane has made this suggestion, though mainly just “for fun”. The British government sold perpetuities called consols for many years. Such bonds would completely circumvent the debt limit, at least without legislation to redefine the limit, which really is long overdue.
The $1 Trillion Coin
Minting a trillion dollar coin is another thing entirely. Barro has a separate discussion of this option, as does Cochrane. The idea was originally proposed and rejected during an earlier debt-limit controversy in 2011. Keep in mind, in what follows, that the Fed does not follow Generally Accepted Accounting Principles (GAAP).
Skeptics might be tempted to conclude that the “coin trick” is a ploy to engineer a huge increase the money supply to fund government expansion, but that’s not really the gist of this proposal. Instead, the Treasury would deposit the coin in its account at the Fed. The Fed would hold the coin and give the Treasury access to a like amount of cash. To raise that cash, the Fed would sell to the public $1 trillion out of its massive holdings of government securities. The Treasury would use that cash to meet its obligations without exceeding the debt ceiling. As Barro says, the Fed would essentially substitute sales of government bonds from its portfolio for bonds the Treasury is prohibited from selling under the debt limit. The effect on the supply of money is basically zero, and it is non-inflationary unless the approach has an unsettling impact on markets and inflation expectations (which of course is a distinct possibility).
When the debt ceiling is finally increased by Congress, the process is reversed. The Treasury can borrow again and redeem its coin from the Fed for $1 trillion, then “melt it down”, as Barro says. The Fed would repurchase from the public the government securities it had sold, adding them back to its portfolio (if that is consistent with its objectives at that time). Everything is a wash with respect to the “coin trick”, as long as the Treasury ultimately gets a higher debt limit.
Lust For the Coin
In fairness to skeptics, it’s easy to understand why the “coin trick” described above might be confused with another coin minting idea that arose from the collectivist vanguard during the pandemic. Representative Rashida Tlaib (D-MI) proposed minting coins to fund monthly relief payments of $1,000 – $2,000 for every American via electronic benefit cards. She was assisted in crafting this proposal by Rohan Grey, a prominent advocate of Modern Monetary Theory (MMT), the misguided idea that government can simply print money to pay for the resources it demands without inflationary consequences.
Tlaib’s plan would have required the Federal Reserve to accept the minted coins as deposits into the Treasury’s checking account. But then, rather than neutralizing the impact on the money supply by selling government bonds, the coin itself would be treated as base money. Cash balances would simply be made available in the Treasury’s checking account with the Fed. That’s money printing, pure and simple, but it’s not at all the mechanism under discussion with respect to short-term circumvention of the debt limit.
Fed Independence
The “coin trick” as a debt limit work-around is probably an impossibility, as Barro and others point out. First, the Fed would have to accept the coin as a deposit, and it is under no legal obligation to do so. Second, it obligates the Fed to closely coordinate monetary policy with the Treasury, effectively undermining its independence and its ability to pursue its legal mandates of high employment and low inflation. Depending on how badly markets react, it might even present the Fed with conflicting objectives.
Believe me, you might not like the Fed, but we certainly don’t want a Fed that is subservient to the Treasury… maintaining financial and economic stability in the presence of an irresponsible fiscal authority is bad enough without seating that authority at the table. As Barro says of the “coin trick”:
“These actions would politicize the Fed and undermine its independence. In order to stabilize expectations about inflation, the Fed would have to communicate very clearly about its intentions to coordinate its fiscal actions with Treasury — that is, it would have to tell the world that it’s going to act as Treasury’s surrogate in selling bonds when Treasury can’t. …
These actions would interfere with the Fed’s normal monetary operations. … the Fed is currently already reducing its holdings of bonds as part of its strategy to fight inflation. If economic conditions change (fairly likely, in the event of a near-default situation) that might change the Fed’s desired balance sheet strategy.”
On With The Show
Discussions about the debt limit continue between the White House and both parties in Congress. Kevin McCarthy met with President Biden today (2/1), but apparently nothing significant came it. Fiscal conservatives wonder whether McCarthy and other members of the GOP lack seriousness when it comes to fiscal restraint. But spending growth must slow to achieve deficit reduction, non-inflationary growth, and financial stability.
Meanwhile, even conservative media pundits seem to focus only on the negative politics of deficit reduction, ceding the advantage to Democrats and other fiscal expansionists. For those pundits, the economic reality pales in significance. That is a mistake. Market participants are increasingly skeptical that the federal government will ever pay down its debts out of future surpluses. This will undermine the real value of government debt, other nominal assets, incomes and buying power. That’s the inflation tax in action.
Unbridled growth of the government’s claims on resources at the expense of the private sector destroys the economy’s productive potential, to say nothing of growth. The same goes for government’s insatiable urge to regulate private activities and to direct patterns of private resource use. Unfortunately, so many policy areas are in need of reform that imposition of top-down controls on spending seems attractive as a stopgap. Concessions on the debt limit should only be granted in exchange for meaningful change: limits on spending growth, regulatory reforms, and tax simplification (perhaps replacing the income tax with a consumption tax) should all be priorities.
In the meantime, let’s avoid trillion dollar coins. As a debt limit work-around, premium bonds are more practical without requiring any compromise to the Fed’s independence. Other accounting gimmicks will be used to avoid missing payments, of course, but the fact that premium bonds and platinum coins are under discussion highlights the need to redefine the debt limit. When the eventual time of default draws near, fiscal conservatives must be prepared to stand up to their opponents’ convenient accusations of “brinksmanship”. The allegation is insincere and merely a cover for government expansionism.
In advanced civilizations the period loosely called Alexandrian is usually associated with flexible morals, perfunctory religion, populist standards and cosmopolitan tastes, feminism, exotic cults, and the rapid turnover of high and low fads---in short, a falling away (which is all that decadence means) from the strictness of traditional rules, embodied in character and inforced from within. -- Jacques Barzun
Sacred Cow Chips 