(You are at Part 5 of The Energy Chain, if you would like to start at the beginning part, click here.)
So far in The Energy Chain,
we have looked at past energy uses and developments. Before we look at
future and alternative energy uses and developments we need to look at why
those "alternatives" are not the "main" sources of energy today and why
it has been, and in most cases, still is, such an uphill battle in
order to gain acceptance.
Please
read the following excerpt very carefully. This is the "governing
dynamics" (attitude) that is driving present day government economic
policies and big business agendas. [Emphasis is ours]:
"Should
we be taking steps to limit the use of these most precious stocks of
society's capital so that they will still be available for our
grandchildren?
"Economists answer this question in two ways.First, they point out that fossil fuels like oil and gas are finite but not 'essential.' An essential resource is one, like oxygen, for which there are no substitutes. Substitutes exist for all the energy resources.
We can substitute coal for oil and gas in most uses; we can liquefy or
gasify coal where liquid or gas fuels are needed; when coal runs out,
we can use higher-cost solar energy, nuclear fission, and perhaps
someday even nuclear fusion. These last three are superabundant in the
sense that when we run out of solar energy, the earth will already be
uninhabitable.
"A second point concerns the relative productivity of different assets. Many
environmentalists argue that energy and other natural resources like
wilderness areas and old-growth forests are very special kinds of
capital that need to be preserved so that we can maintain "sustainable"
economic growth. Economists tend to disagree.
They look at natural resources as yet another capital asset that
society possesses -- along with fast computers, human capital in an
educated work force, and technological knowledge in its patents,
scientists, and engineers. Both economists and
environmentalists agree that this generation should leave an adequate
stock of capital assets for future generations; but economists worry
less about the exact form of capital than about its productivity.
Economists ask, Would future generations benefit more from larger
stocks of natural capital such as oil, gas, and coal or from more
produced capital such as additional scientists, better laboratories,
and libraries linked together by information superhighways?
"The
substitutability of natural capital and other kinds of capital is shown
by the production indifference curve or 'isoquant' in Figure 18-2. We
show there the amounts of the two kinds of capital that would be
required to attain a certain level of output in the future (Q*),
holding other inputs constant. That output can be produced at point C
with a conservationist policy that emphasizes reducing energy use
today, leaving much oil and gas and relatively little human capital for
the future. Or it might be produced with a low-energy-price and high
education strategy at B. Either of these is feasible, and the more
desirable one would be the one that has a higher consumption both now
and in the future.
"Note
as well that the isoquant hits the vertical axis at point A, indicating
that we can produce future output level Q* with no oil and gas.How
is this possible? With the greater scientific and technical knowledge
represented by point A, society can develop and introduce substitute
technologies like clean coal or solar energy to replace the exhausted
oil and gas. The curve hits the axis to indicate that in the long run,
oil and gas are not essential." (ECONOMICS, Paul Samuelson and William Nordhaus; McGraw-Hill, 1998, p. 328)
OK, now...DEEP BREATH.
In
English, what they are saying is that oil and gas are not essential to
the world because technology will always overcome resources.
Ahh...technology (play Star Trektheme song here)...
NEOCLASSICAL ECONOMICS
Definition:
"Neoclassical
economics, the form of economics derived in the mid-19th century that
prevails today, focuses on problems related to value decisions, the
behavior of economic actors, and the working of markets." (The Need to Reintegrate the Natural Sciences with Economics,
Charles Hall, Dietmar Linderberger, Reiner Kummel, Timm Kroeger, and
Wolfgang Eichhorn, August 2001 / Vol. 51 No. 8 BioScience, p. 663)
The writers continue the definition [emphasis ours]:
"These
problems belong to the sphere of the social sciences (many of which,
incidentally, have their own problems with neoclassical economic
theory; see, for example, Marris 1992). But the wealth that is
distributed in the markets must be produced in the hard sphere of the
material world where all operations must obey the laws and principles
of physics, chemistry, and biology. Our concern is that most
production models of economics are not based on these biophysical laws
and principles; in fact, they tend to ignore them (Georgescu-Roegen
1971, Daly 1973, 1977, Kummel et al. 1985, Leontief 1982, Cleveland et
al. 1984, Hall et al. 1986, Hall 1992,2000).
What
they are saying is that the major economic theories in use today were
developed in the mid-19th century and are not grounded in any sort of a
"whole world" reality. Given the excerpt that we opened with it is easy
to see that there is definitely something amiss.
But wait, you say! That could not be! Surely our governments know best!
Well,
let us hear from the Chief Economist of the largest corporation on the
Earth today, the United States of America, Alan Greenspan:
The Fed chairman rejected theories that the world will soon run out of oil.
"If
history is any guide, oil will eventually be overtaken by less-costly
alternatives well before conventional oil reserves run out," Greenspan
said.
In
addition, new technologies to preserve existing oil reserves and
stabilize oil prices will emerge in the years ahead, he said.
"We
will begin the transition to the next major sources of energy perhaps
before mid-century as production from conventional oil reserves ... is
projected to peak," Greenspan said.
(Oil has sapped GDP growth: Greenspan, Gregory Robb, CBS Marketwatch.com, Oct. 15, 2004. Remarks by Chairman Alan Greenspan - Oil, To the National Italian American Foundation, Washington, D.C., October 15, 2004, full text here: http://www.federalreserve.gov/boarddocs/
speeches/2004/200410152/default.htm
Do
you remember the last segment we did on Oil / Natural Gas? Remember
that the current number of gasoline and diesel engines in the world
today was well over 1 billion in number?
Let's review the statement about gasoline:
Gasoline has a tremendous amount of stored chemical energy.
It is also very compact, easily contained and transferred, very
portable, and can be converted very simply into a lot of mechanical
energy to do WORK.
There
is no technology in development or even theoretical that can do what
gasoline can. The same goes for hydrocarbons in general. Well, how
about HYDROGEN, you say? The hydrogen economy! The Governator
Schwarzenegger's battle cry!
Question: Who is going to pay for switching over the 1 billion engines to hydrogen?
Has anybody figured out the cost of this? Forget cost, how about time?
Any ideas on how long it will take to retrofit 1 billion engines? What
about energy? How many MJ (megajoules) of energy does it take to make
one (1) engine? How about 1 billion engines?
According to the auto industry, the top 10 auto manufactures produced 50 Million vehicles in 2002 alone (http://www.autoindustry.co.uk/Hidden/companies/vehicle.xml).
Given that the life expectancy of a new vehicle is 10 years, if the
auto industry geared up to produce hydrogen vehicles it would take more
than 10 years to simply keep up with the current replacement schedule
of 500 million vehicles. That is more than 500 million engines short.
This is also assuming that energy prices and production remains
stable...which it is not.
But
today's economists, the same ones that lawmakers turn to when they are
writing policy that affects YOU, do not believe that gasoline, oil,
hydrocarbons, or any other energy resources are "essential". So don't
worry.
Here is a graphic of what the Neoclassical Economics System looks like:
Figure 1 (Two Paradigms of Production and Growth, Professor Robert U. Ayres, Dr. Benjamin Warr, Center for the Management of Environmental Resources (CMER), INSEAD, France)
Does this system diagram seem a bit strange?
As long as profit goes up and product costs decline, there will be more
money for the consumption of goods and services...which will make
profit go up and product costs decline, so that there will be more
money for the consumption of goods and services...Hey! Wait a
minute...This looks like an endless loop!
But
the 2nd Law of Thermodynamics says that you cannot create an endless
energy-exchange system without the introduction of an outside energy
source.
But there is nothing in this "system" to INPUT into the system. It simply keeps on looping. (Its a bit loopy.)
That is the definition of a perpetual-motion machine...and cannot exist within the physical structure of this current universe.
"In
the closed economic system described by Walras (Walras 1954), Cassel,
(Cassel 1932) von Neumann (von Neumann 1945) and Koopmans (Koopmans
1951), every product is produced from other products made within the
system, plus capital and labor services."
"Lacking
any linkage between the efficiency of materials and energy use and
productivity, there is no theoretical incentive to become more
efficient. There are also no consequences from generating wastes and
pollutants. In the closed Walrasian equilibrium system, where all
products are abstractions, there is no such thing as material waste.
The neo-classical conceptualization implies that wastes and emissions ñ
if they exist at all ñ do no economic harm and can be disposed of at no
cost." (Two Paradigms of Production and Growth, Ayres, Warr, pg. 2, 5)
Time to look at another point of view on economics.
ECOLOGICAL ECONOMICS
Dr. Robert Costanza, of the Gund Institute for Ecological Economics, University of Vermont Rubenstein School of Environment and Natural Resources, defines Ecological Economics this way:
Ecological
Economics transcends traditional disciplinary boundaries in order to
address the complex interrelationships between ecological and economic
systems in a broad and comprehensive way.
Here is an example of an Ecological Economic System:
Ecological Economic System Showing Input and Output (The Need to Reintegrate the Natural Sciences with Economics, Charles Hall et al. p. 664)
Expanded Ecological Economic System: Economics of Life (The Need to Reintegrate the Natural Sciences with Economics, Charles Hall et al. p. 665)
Notice
how the Ecological Economic System closely matches what happens in real
life? There are INPUTS into the system in the form of Solar,
Geophysical, and Nuclear energy; NATURAL RESOURCES; as well as OUTPUT
in the form of consumption and waste. Every aspect of this system has
an energy (exergy) value and can be plotted numericaly.
Here
are two more examples of the Conventional Model of the Economy and the
Expanded Ecological Economic System (click on the pictures for larger
versions):
(Visions, Values, Valuation, and the Need for an Ecological Economics, Robert Costanza,
June 2001 / Vol. 51 No. 6, BioScience, pg. 461)
THE EVOLUTIONARY PARADIGM (Ayres, Warr)
Economists
Emeritus Professor Robert U. Ayres, and Dr. Benjamin Warr, of the
Center for the Management of Environmental Resources (CMER), INSEAD,
France, have outlined the "Evolutionary Paradigm" of economics:
"...the
disequilibrium evolutionary paradigm discussed hereafter characterizes
the economy at the macro-level as an open multi-sector materials/energy
processing system. The system is characterized by a sequence of
value-added stages, beginning with extraction of crude resources and
ending with consumption and disposal of material and energy wastes,
which can do harm if not eliminated." (Two Paradigms of Production and Growth, Ayres, Warr, pg. 5)
WHY DO NEOCLASSICAL ECONOMISTS THINK THE WAY THEY DO?
No, that was not a joke...but some may think so.
VALUE: If it has no value, it is not even considered in the equation.
"The
history of economic thought is replete with struggles to establish the
meaning of value, both what is it and how is it measured. Aristotle
first distinguished between value in use and value in exchange. The
distinction between use and exchange value has been "resolved" several
times, but it remains an important issue even today." (Value Theory and Energy, Robert Costanza, University of Vermont, Encyclopedia of Energy, Volume 6., 2004, Elsevier Inc., pg. 338)
ENERGY has a VALUE problem with neoclassical economic theory due to one major point: the cost of energy has been cheap!
"The
conventional neoclassical view of the low importance of energy and
materials dates back to the first stages in the development of
neoclassical economics. Initially the focus was not so much on the
generation of wealth as on its distribution and the "efficiency of
markets." Consequently, the early thinkers in economics started with a
model of pure exchange of goods, without considering their production."
..."Here
lies the historical source of the economists' underestimation of the
production factor energy, because in advanced industrial market
economies the cost of energy, on the average, is only 5% to 6% of the
total factor cost (Baron 1997). Therefore, economists tend to either
neglect energy as a factor of production altogether or they argue that
the contribution of a change of energy input to the change of output is
equal only to energy's small cost share of 5% to 6% (Denison
1979,1984)." (The Need to Reintegrate the Natural Sciences with Economics,
Charles Hall, Dietmar Linderberger, Reiner Kummel, Timm Kroeger, and
Wolfgang Eichhorn, August 2001 / Vol. 51 No. 8 BioScience, p. 666)
So, low cost has come to mean low value.
In
neoclassical economics, one can also readily see how little value is
placed on resources, since resources can be substituted for other
resources [emphasis is ours]:
"...[In neoclassical economics:]
On the production side, inputs are also considered to be substitutable
for one another. Machines and technology can substitute for people and
natural inputs."
"...[But the reality is:] On the production side, no number of lumbermen is a substitute for timber when there is no timber.
Production may require certain inputs, but at the same time there may
be substitutability between others...As Krutilla suggests, there
may be close substitutes for conventional natural resources, such as
timber and coal, but not for natural ecological systems."(Value Theory and Energy, Robert Costanza, University of Vermont, Encyclopedia of Energy, Volume 6., 2004, Elsevier Inc., pg. 341)
READING LIST in Adobe PDF format
Here
are papers as presented by the various researchers cited in this study.
The files are in Adobe Acrobat PDF version 6.0 ; this is done for size
and downloadability. If you are on a corporate or university system
that can only read Acrobat PDF version 5, please email us and we will
more than happy to email it to you.
You will need free Acrobat Reader to read the papers presented here in PDF format.
If not installed on your computer, download a free copy here:
Costanza, R. 2000. Visions of alternative (unpredictable) futures and
their use in policy analysis. Conservation Ecology 4(1):5. [online] URL: http://www.consecol.org/vol4/iss1/art5
Charles Hall (used with permission)
The Need to Reintegrate the Natural Sciences with Economics
David Pimentel Water Resources, Agriculture and the Environment (200k) [download] Energy Use in Agriculture: An Overview (72k) [download]
BOOKS WE RECOMMEND - Ecological Economics
BOOKS TO READ - To see where people are coming from.
This is the book where we got that amazing quotation
that starts off this section.
For you Star Trek fans, someone sent us a bluegrass version of the original Star Trek
theme song. As Spock would say, "Fascinating". You can listen to it [here].
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Energy Economics 
