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So today, I want to explore the problem that we face,
which is much more than a dilemma, it's a quad-lemma in a
way, or a quint-lemma of how we
manage our future energy demands and how we invest our resources
in alternative forms of energy.
And I'm going to spend most of this session talking about the
possibilities and limitations of nuclear power.
And this will provide a foundation for the lecture on
next Tuesday, which will be particularly
directed at wind, but more broadly at renewables.
So first, I'd like to have you consider the distribution of
nuclear power plants in the world and really reflect on
where they're not located, and their high concentration,
particularly in the Eastern, Midwestern part of the United
States, but also in Europe.
So within the U.S.
you see that they're really concentrated up in the
Northeast, but also south in nearby Chicago.
And California is quite striking in that in 1976 the
State of California enacted a moratorium against new nuclear
power plant development.
If you look more closely at Europe,
and particularly at France, you can see a very high
dependence in some nations in the European Union on nuclear
power.
France now receives approximately seventy-five
percent of its power from nuclear plants.
And inside the United States, also there's quite a bit of
variability in reliance on nuclear.
So in Connecticut, for example,
nearly sixty-five percent of the power that we consume in the
state comes from nuclear plants in Niantic,
which is about forty-five miles to the east of us on the Thames
River from the Millstone nuclear power plants.
So it's quite curious how different parts of the country,
different economies, have treated nuclear power.
And explaining the cultural predisposition to accept the
risks and accept the costs is not an easy thing to do.
So just so you have an overview of the status of the nuclear
industry in the world, there are about 436 different
reactors that are operating in thirty different countries.
Fifty reactors are now under construction,
mostly in Asian nations.
And within the U.S., there are proposals for twenty
new reactors.
And of these, four to eight may be online in
2020.
China has eleven online at present, with twenty-two under
construction, and is the nation where nuclear
development is most rapid in the world.
Within the U.S., the operating licenses that
have had limits placed on them of operating licenses between
thirty and forty years, most of these are going to be
granted operating extensions.
And the concern was that the plant or the infrastructure
would not have the capability of lasting longer than forty years
at the outside.
But they're finding that the engineering integrity of many of
the plants is higher than they thought it might be.
But this basically is a short-term lease on the problem
of decommissioning these nuclear plants and also what we'll be
talking about in a few moments, which will be the problem of
managing nuclear waste.
The MIT report, the faculty report that was
issued in 2003 and then recently updated that we asked you to
read has some really I think important lessons and
conclusions embedded within it.
So they concluded that after five years from 2003,
so this is two years ago, no new plants are under
construction in the United States,
and insufficient progress has been made on waste management.
The sober warning is that if more is not done,
nuclear power will diminish as a practical and timely option
for climate change risk mitigation.
So as one thinks about what are options are,
particularly coal, as opposed to investments in
renewables, as opposed to investments in
nuclear power, one might think about it as a
problem of relative cost.
But you also might think about relative risk and ease of
bringing additional capacity online given the different
sources.
And underlying this, I think, is an underestimated
cultural factor, which is what we worry about in
the United States, and our predisposition to
remember not just Chernobyl, but also what happened at Three
Mile Island in 1979.
The capital costs of constructing a new plant are
often enormous.
And because so much can go wrong, including construction
delays that can cause interest rates to rise and the amount
that has to be paid back to investors to rise,
it's caused what's thought of as a risks premium being put on
an investment funds.
So banks or private investment companies often will loan the
money to a utility company that wants to build a new plant,
but they will do so at a higher rate when it's measured by
kilowatt hour.
And so there's about a two cent per kilowatt hour difference
between nuclear compared to coal and natural gas,
which makes this a very, very expensive proposition.
Basically, the money costs more.
The legal and regulatory structure that surrounds nuclear
power is rather complex.
The initial statute that governed what now exists was the
Atomic Energy Act back in 1954 that we discussed a bit during
the beginning of the term when we were talking about
atmospheric weapons testing.
But now, recall that the technology,
that the science and engineering foundation for
nuclear power plants, really evolved out of the
nuclear weapons development program.
So many of the nuclear power plants that were the earliest
versions, say at Hanford or at Oakridge
in Tennessee, these plants were first
generation, but they were designed
predominantly to provide enriched fuel for atomic
weapons.
This defines both state and federal authority concerning
nuclear energy.
And it really was the watershed that ended the monopoly,
the government monopoly on nuclear technology.
And it gave the private sector a role in nuclear development,
and expressly prohibited states from any role in transfer,
delivery, receipt, acquisition,
possession, or use of nuclear materials.
And it also gave the Atomic Energy Commission the exclusive
authority to manage these issues.
What is interesting about the history of the AEC is that they
were both the promoters of the technology and the developers of
the technology, and they were supposed to be
the regulators.
So the fox watching the henhouse, so to speak.
And this was recognized quite early in the history of the AEC,
when Congress decided to break off the responsibilities
associated with regulation to have a higher probability of
safety and environmental protection and worker safety.
So that the Nuclear Regulatory Commission was given these
responsibilities.
So this is an independent agency now that has
commissioners assigned to it that make choices about issuing
licensing decisions and about safety violations or
environmental violations associated with the industry.
So that states have retained authority over electric power
generation, sale, and transmission.
Another aspect of the development of the nuclear
industry which is important to know is that this is not being
protected by private insurance companies.
The Price Anderson Nuclear Industries Indemnity Act really
holds the industry harmless from damage claims in the event of a
serious accident.
And it also sets up a procedure for compensation that has
criteria that are really pretty clear,
that those that claim damage have to show what it was,
they have to calculate their monetary loss,
and they also have to demonstrate causality that is
relatively easy to demonstrate in this case because of a
specific isotope mixture signature that would come from
any sort of a nuclear explosion or an accident.
So the Nuclear Regulatory Commission was created in 1974.
Now, you can imagine also that many states might be more
worried about nuclear power than other states.
And California is really a pretty good example of that.
So that in 1976, the State of California created
a moratorium on new nuclear power plant construction.
So states might have the authority to do that.
And until the federal government approved of methods
to dispose of high level waste, the State of California was
really quite concerned about what the long-term costs might
be to manage that waste, and also what the long-term
costs might be associated with decommissioning the plant.
So the Pacific Gas and Electric Company argued that the
Congressional intent to preempt state regulation of the nuclear
industry was implicit in the Atomic Energy Act.
So again, preemption is a critical legal tool that the
industry relied upon in order to claim that the State of
California did not have authority to create this
moratorium.
So the Supreme Court eventually ruled on this case,
and its finding is quite interesting.
The federal government possesses exclusive regulatory
authority over construction and operation of nuclear facilities
and over radiological safety.
And the states hold authority over decisions concerning the
need for additional generating facilities, licensing,
ratemaking, land use, and planning.
And the Supreme Court argued that federal law would preempt
the moratorium if it was related to safety concerns.
So that's an interesting idea.
The federal government would be the experts in the area of risk
assessment and environmental assessment.
Thank you, Emily Jack-Scott.
You seem to have been quite successful, persuasive.
So that if it's related to safety concerns,
the court argued that California did not have the
authority to establish a moratorium because it was
worried about health effects or environmental dangers.
But it concluded that the federal law would not preempt a
moratorium if California's logic was based on economics.
So if they were worried about cost considerations down the
road.
So a very interesting distinction that allowed this
moratorium to be sustained.
California's assertion that the legislature had enacted the
moratorium based upon economic concerns was eventually
accepted.
The Nuclear Waste Policy Act of 1982 is important because most
nuclear waste had been and is now being stored in or nearby
nuclear power plants.
So it's highly dispersed around the country.
Think back on the U.S.
map that I showed you with the different dots of the location
of the plants.
That's where the nuclear spent fuel, the fuel rods,
that are highly radioactive, are being stored.
Within Connecticut, this would include the Haddam
Neck Nuclear Power Plant that's now been closed that's about
twenty miles from Yale to the east,
and it would also include the three Millstone plants over in
Niantic.
So that under this statute, the Department of Energy was
granted the authority to begin to centralize a nuclear fuel
reprocessing and repository.
So basically, just a storage facility where
this waste could be handled until it might be reprocessed.
But they were unable to open the facility,
and by an amendment, the site at Yucca Mountain was
established by DOE to be the single repository.
So you can imagine that if you were the State of Nevada,
you probably would not be too happy about that.
But if you were the State of California,
Connecticut, or any other state that had
nuclear power plants, you'd be really happy about the
prospect of getting rid of the waste that's sitting inside your
state boundary.
So this prompted a lot of litigation.
Litigation on the part of Nevada, that did not want the
repository to be located there.
And litigation on the part of other states,
including the State of Washington, most recently,
arguing that they wanted their waste taken to this power plant
and that the Obama administration did not have the
right to decide that this storage facility should not
open.
When one thinks about the location of either the plants or
the storage facilities, you need to think carefully
about evacuation requirements.
So before the Three Mile Island accident in Pennsylvania,
the emergency response plans by nuclear power plants in the U.S.
were voluntary.
That's quite striking, given what the Atomic Energy
Commission and the Nuclear Regulatory Commission understood
about the potential for these nuclides to move over long
distances, being transported in the air.
Now, the plans have to cover a ten-mile radius.
Now think about that.
Ten miles, would that be sufficient?
Well, we're about twenty miles from the nearest nuclear power
plant here.
But if you think about the Indian Point Nuclear Power Plant
outside of New York City, then you need to think about
the capacity to move tens of millions of people away from a
zone that would likely be highly contaminated in the event of a
meltdown or an explosion or a serious fire,
such as existed at Three Mile Island or at Chernobyl.
So the Indian Point facility prompted Governor Pataki to
commission a report to evaluate the evacuation plan,
and criticized the communication between local
agencies, the size of the area that would
be affected by release, and the plan's premise is that
an orderly evacuation, rather than mass panic,
would likely ensue.
It's kind of interesting, because if you drive around
Connecticut within ten miles of the nuclear power plants,
occasionally, you'll see a sign on the side
of the road, sometimes very rural roads,
that notify the public that this is part of an evacuation
route in the event of a nuclear accident.
So that the capacity to move people away from a contaminated
zone, to be able to predict how that
zone might vary given weather patterns,
it really is quite limited.
Also, there was no consideration of the probability
or likelihood of a terrorist attack at these plants.
And this raised the possibility that there ought to be aerial
surveillance, that there ought to be planes
that are flying nearby these nuclear power plants,
as there was shortly after the 9/11 terrorist attack in New
York.
So that the Commission reported that "Any plant adjacent to
high population areas should have different requirements than
plants otherwise situated because protective actions are
more difficult and the consequences of a failure or
delay are higher."
And the "planning problems are more serious because of the
large population concentrations."
So I'm going to jump ahead here.
The core problem associated with waste is radioactive
half-life.
And the key concern is over plutonium.
And there are 270 tons of separated plutonium from
reprocessing of fuel rods around the world that now are sitting
at sites and being stored.
And it has a half-life of roughly 24,000 years.
So when engineers and safety experts were thinking about the
problem posed by Yucca Mountain, this is the mountain in Nevada
where the storage facility has been partially constructed,
using about nine billion dollars of taxpayers' money.
So that the problem really here was how do you ensure the
integrity of a storage facility for nearly a million years?
And they chose this site because of its remoteness.
Poor Nevada.
Remember, Nevada was also the site of the Atmospheric Weapons
Testing Facility, the largest and most often used
in the U.S.
And they designed a machine that would bore into the rock
and create a tunnel within which either canisters would be stored
as dry fuel, or they could be stored in
water.
So the fuel is highly radioactive, and it's cooled in
pools of water or in these dry casks.
And it's currently stored at sixty-six sites in the U.S.
This is what one of the storage facilities might look like.
And that honeycombed set of boxes that you can barely see in
the bottom of the pool over here, that's how they store the
fuel rods, side by side.
By the way, it also creates radioactive water so that the
amount of liquid waste that is contaminated is far larger in
volume than the amount of waste that is either low level or high
level waste.
So it was also curious that if you're projecting out a risk
management strategy over tens of thousands or hundreds of
thousands of years, you know what happens if
something occurs and society no longer speaks a language that is
understood today?
What if some massive accident occurred,
nuclear war or whatever it is, that leads whatever society
exists that stumbles across this plant to recognize it?
Kind of interesting.
In a way, it was a labeling issue.
How do you communicate risk, not using language,
but using symbols instead?
So the Department of Energy commissioned anthropologists to
think about different forms of symbolism.
And they went back and looked at what symbols would best
convey the idea that there was something extremely dangerous
nearby or to stay away.
And the symbolism that is chosen is not represented here.
But the nuclear symbols that you see in the upper right hand
side of this slide are those that are commonly used by the
nuclear industry.
But you can imagine if you did not know the culture today,
if you'd never seen any symbol on the side of a truck,
for example, sometimes trucks have some of
these symbols that you wouldn't have any idea what this meant.
The symbols on the lower right are symbols that are commonly
applied for industrial and worker safety situations,
whereas the symbol on the left is several hundred years old.
So that I mentioned a lawsuit.
This most recent lawsuit this year, this spring,
by Washington State v.
The Department of Energy, was designed to encourage the
federal government to keep the Yucca Mountain Repository
viable.
"The Attorney General McKenna made the right decision
to file his lawsuit today to stop the Administration from
closing down Yucca Mountain."
Now, another problem with nuclear power is the potential
for proliferation of nuclear weapons.
So one might think that we need to think about an international
strategy to control the distribution of nuclear fuel.
So processed nuclear fuel could be further enriched to form a
weapon grade that could produce nuclear weapons.
So the International Atomic Energy Agency and several other
private organizations banded together to encourage the
creation of a nuclear fuel bank so that the G8 has been proposed
to constitute this bank and be responsible for the
dissemination of nuclear fuel and then for its recovery once
it's spent.
In this way, they would have a collaborative
attempt to try to manage the fuel.
Thinking also about the MIT faculty's conclusions regarding
safety, they ended their report saying
that parallel with improved operations,
the safety record of the nuclear industry has really been
quite remarkable in the last twenty years.
And it plays-- the "nuclear power industry
displays by far the highest capacity factor among all
generation technologies, providing now about twenty
percent of the U.S.
electrical supply."
So that the belief is that most reactors,
particularly the latest generation reactors,
have the capacity to operate safely,
but that the probability of bringing them online in a way
that would make a significant difference in the world with
respect to effects of energy consumption and climate change
is really quite limited.
So that with respect to the enrichment problem,
for example, uranium, when it's mined,
is approximately point seven percent uranium-235,
but it needs to have that increased to four to five
percent in order for it to be useable as fuel in a nuclear
power plant, compared to twenty percent that
it has to be for nuclear devices.
The Three Mile Island example in 1979 created quite a bit of
alarm in the United States, and it was also a time when a
movie came out called The China Syndrome that
dramatized the effects of a nuclear accident in an urban
area.
And the nuclear facility at Three Mile Island experienced
what was about a sixty percent meltdown.
And like most major accidents, whether or not it's the space
shuttle that blew up or the Bhopal incident in India,
where it's estimated that more than 100,000 people were killed
in a chemical plant explosion, or in Chernobyl,
many people think about the problem being assigned to and
caused by technical failure, technology failure,
hardware failure.
When in fact, it's almost always human
failure, human failure to monitor equipment effectively.
And that was certainly the case at Three Mile Island,
when workers mistook the need to open a valve to allow cooling
water to go in and cool down the fuel rods that were heating up.
So in Bhopal, it was a problem of gauges.
With the space shuttle blowing up,
it was a problem of misrecognizing the heat shield
tiles that had fallen off, and that were highly
temperature sensitive.
So that the shuttle took off during temperature conditions
that some recognized made it dangerous.
So the case history that is most important I think for us to
think about, which caused the greatest
amount of environmental damage in history with respect to a
nuclear power plant occurred at the Chernobyl plant in Pripyat,
then within the Soviet Union.
And this occurred in April of 1986 and occurred during a
yearly maintenance operation, where they were pursuing a
gradual power reduction.
And they basically lost control of their maintenance efforts.
And the control rods were removed too quickly,
and then the power shot back down too low,
and the water in the plant was turned in an improper direction.
The workers were confused about what to do.
The power surged 1,500 times its safe level within five
seconds, and a steel shield on the roof
of the building was blown into the sky,
and the entire facility caught fire for a period of several
weeks.
So four days later, after the Soviet Union has
maintained their silence, the government announced,
"An accident has occurred at the Chernobyl Atomic Power
Station.
One of the nuclear reactors has been damaged.
Measures are being taken to eliminate the consequence of the
accident, aid is being given to the
victims, and a government commission has been
established."
So anyone who knows anything about industrial accidents or
nuclear power plants would recognize that being able to
warn the public immediately after an accident was
exceptionally important.
The only nuclear event that this could be compared to was
one at Windscale, now known as Sellafield,
in the northern part of Great Britain,
where in 1956, there was a fire in the plant
and a significant amount of radiation was released into the
air.
And the workers of the plant went out and commandeered the
tractors and cars of farmers that lived in the surrounding
area.
And the farmers were standing in the field watching these
workers basically drive away in a caravan as quickly as they
could so that they could reduce their exposure.
Again, no government warning, no attempts to evacuate the
area.
So that the failure to take action soon after an accident
like this results in the population being exposed at the
highest levels.
So the Soviets then disclosed "a certain leak of
radioactive substances," and then finally told the
public that 200 people were hospitalized,
but that the water and the air in Kiev were safe.
They were reassuring the public in fact,
at the same time that their air force was seeding the clouds in
the area, trying to induce rain so that
it could wash the radiation from the sky before it reached the
Russian state and also to protect the reservoir that is to
the north of Kiev.
So finally, President Gorbachev in '86 came on the news one
evening and said, "Good evening,
comrades.
All of you know that there's been an incredible misfortune.
The accident at the Chernobyl plant has painfully affected the
Soviet people and shocked the international community,
and for the first time, we confront the real force of
nuclear energy out of control."
There are a variety of different stories and lessons
here, but perhaps the one that is most sad is the way that
workers were mistreated.
The effects of being exposed to radiation in the absence of
protective gear was very well known to the Atomic Energy
Commission and to the Soviet scientific experts from their
experiences with nuclear weapons.
But other than potassium iodide pills and the normal kind of a
suit that a fireman might wear as protective gear,
they were left helpless, even though they were told to
go in and try to put out the flames of the burning and
charring fuel rods.
So also, the Soviets and others misunderstood the pattern of
distribution of the radionuclides once they reached
the atmosphere.
So here you see April 26, the white that you see in the
right hand side of the upper left air photo here,
is demonstrating the direction of the plume.
By April 28, the plume had reached up over
Norway, Sweden, and Finland.
By April 30, you can tell that the plume was
being dispersed and being blown back around northern Europe.
And eventually, by May 6, it had scattered
itself pretty much all over Europe, with a patchy kind of a
concentration.
And you remember the surprise on the part of the Atomic Energy
Commission to the patchiness of the fallout,
finding high levels of strontium-90 in New York and
Connecticut when the cloud intercepted a rainstorm.
And this affected a fallout pattern that was really quite
similarly non-uniform in Europe.
And it took roughly about ten days for this plume to make its
way all the way around the world,
moving across China and then the Pacific Ocean to reach the
United States, when it became detectable in
the milk supplies in states such as Utah and Arizona and
California.
So that the sensors that existed at that point in time
were picking up contaminants eventually distributed around
the United States and eventually the rest of the world.
So as you look at this map, you see a radiation deposition
gradient from lightest color to darkest color.
And what's so striking about it is that you see the patchiness
demonstrated here, where you have a significant
deposition in Austria, a significant deposition in
Finland and up in both Norway and in Sweden.
And the distance, by the way, is probably about
600 to 700 miles, maybe about 800 miles,
from Chernobyl up to Northern Europe.
So one thing that this did was it created complete chaos in
European food markets.
So if it reached the ground, it was getting into the food
supply.
Well, they realized that the different nations all had
separate radiation standards.
So that they did not have a uniform regulatory system to
protect against one nation selling one commodity that had a
radiation level that might not be accepted by another nation
that had a tougher standard.
Also, the detection process, you can imagine that the
government was slow to go out and try to figure out this
patchiness with precision.
And that had tremendous implications for the period of
exposure by the population.
So here's a good example of the distributional pattern as it was
being recognized by the Soviet Union back in the late 1980s.
And as they tested more, they found more.
So that this map was constantly changing in response to more
rigorous testing.
So that the different zones that you see here are designated
as confiscated areas, permanent control areas,
period control areas, and unregulated areas.
So that the darkest red are the confiscated areas.
So that lands, agricultural lands,
urban lands, homes, residential communities,
commercial areas, were literally confiscated so
that hundreds of thousands of people were moved off of their
land because the soils, the plants, as well as the
building materials, and even the vehicles,
were contaminated.
Hundreds of thousands of vehicles turned into hazardous
waste, almost within a matter of days.
So what to do with this area?
What do you do with people that you're going to pull out of
their homes?
Well, they had to build new communities.
And in some instances, they even built new communities
in areas that were contaminated because they hadn't tested
carefully enough.
Kind of interesting, because it should ring bells
with you with respect to the Bikini Island history,
where the Bikinians were allowed to move back into an
area that the government supplied funds for constructing
new homes, and then they went in and
tested that more carefully and found that they had to move out.
So that the tension here is that the government will want to
limit its own liability, its own costs for evacuating or
for dealing with hazardous waste,
or for rebuilding a community.
So it has very little incentive to disclose with precision the
intensity of the concentrations.
So in this case, the precision grew in response
to international pressure because they were finding the
patchy highly contaminated areas in many different European
communities.
And those different countries wanted to have international
authority to take the Soviet Union to court so that they
could be compensated for their losses as well.
The construction workers that were trying to put out the fire
and then deal with the contaminated areas would drive
vehicles in whether they were aircraft,
whether or not they were cars or trucks such as this.
The workers eventually were suited up in protective gear,
and they had to wash down the vehicles as they left the site
to keep the vehicles from tracking the radionuclides to
different parts of the affected area.
I mentioned that agricultural lands were obviously affected,
especially those within the red zones on the map that you just
saw.
What do you do with contaminated lands like this?
Well, you basically have to scrape the surface off of it and
figure out how you're going to bury the contaminated material.
So that think about this, 76,000 thousand square
kilometers of contaminated land.
And what about the forest lands?
What would happen to the timber that were growing in the area?
Well, they also absorb the radionuclides.
And many of those trees were still standing.
And many people would cut down the contaminated trees,
cut the timber, saw it up, turn it into
building material, and people would build their
houses of it.
There's a similar analogy to the way that the uranium mines
created the fuel for the power plants,
the way that those mines left waste of uranium mine tailings.
So what did they do with that?
Well in some instances, they used the mine tailings as
a construction material for homes, particularly on Native
American reservations.
So there's a very unhappy and costly history of how Navajos
were living in homes that were built from cement products that
contained uranium.
So that the enormity of the effect of the contamination was
just beyond anybody's expectation.
Cars, trucks, tanks had to be buried.
And there are many stories about how cars would be buried
at night.
They'd be dug up before dawn, and parts from those cars would
then be removed and sold on the black market.
So you all know that there's a very robust used car part market
virtually everywhere in the world.
So that these radioactive used parts were brought back,
recycled back into circulation.
In Sweden it's interesting.
Because the Swedes found out about this,
not because they were notified by the Soviets or any other
nation, but because their workers
showed up at their nuclear power plants and they started setting
off alarms.
So that power plants in Sweden were shut down one after
another, but not because there was a
problem at their plant, but because their workers were
walking in the door to the plant in the morning and they had
picked up the radionuclides that had been deposited on the
streets or the sidewalks in Sweden,
and that contamination had set off the alarms.
That's when they started looking at weather patterns and
trying to figure out what the source might be.
There was no evidence that a nuclear weapon had been
detonated, so they started at the location
of nuclear power plants and were able to piece together the
weather pattern over the past several days to pinpoint the
Chernobyl plant.
So that within several days, the radiation in Sweden was
1,000 times higher than it previously had been.
So I'm going to jump ahead here to a discussion about
evacuation.
Civil defense officials were finally able to convince the
government and plant officials of the need to evacuate areas
that were closest to the plant.
But thirty-six hours had passed.
And these are, if you look at the current
charts about the periodicity of the release of the radiation,
you find that this first thirty-six hours was a crucial
period, when that population should not
have been allowed to stay in the area.
So that they really had no plan.
The government eventually was able to put together 1,000 buses
and picked up first the children and then moved them hundreds of
miles away to different camps.
So as they studied the pattern of deposition,
they found that their evacuation zone had been defined
too narrowly.
So the evacuation zone had to be continually expanded.
So that by May 3, this was only about six or
seven days later, 45,000 residents had been
evacuated from a ten-kilometer radius.
Eventually, 210,000 people were resettled into less contaminated
areas.
By the way, if you take the United States' requirement that
every nuclear power plant in our nation have an evacuation plan
that would cover an area that is defined by a ten-mile radius and
you compare it to the movement of contamination from this
plant, you can see the ten-mile radius
in green here compared to the eventual location of the deep
red colored confiscation zones more than a hundred miles away.
So I'm going to jump ahead here because I'm going to run out of
time.
The safety regulations varied quite highly among the different
nations, leading to a chaotic set of bans.
So that finally, the Europeans decided to ban
meat, live animals, and produce from all areas
within 1,000 kilometers of the site.
The economic consequences were enormous.
So that the Austrian government banned the import of East Block
milk, fruit and vegetables,
the Dutch Agricultural Ministry prohibited cattle grazing.
The Swiss were warned against providing fresh milk to young
children.
Italy banned the sale of its own leafy vegetables.
And even the U.S.
was warning people not to go to several European nations because
of the extent of the contamination.
So the economic consequences just associated with the food
supply and its contamination were far higher than anybody
imagined.
There's also a sad story about the Sami indigenous group in
northern Sweden that have long relied upon the livestock of
reindeer.
And reindeer feed on moss and lichen,
and the radionuclides built up heavily in the moss and lichen
and were detectable in their meat within a matter of several
days following the accident.
So that the Swedish government decided that it was going to ban
the sale of all future products from these animals except for
the sale of furs.
So to come to a conclusion here, you'll be able to study
this slide not from this lecture, but up on the Classes
server.
So that if you think about the relative amount of radioactivity
that was released by the first atomic bombs in curies,
you see the first atomic bombs up here on the top at Nagasaki
and Hiroshima having released about 250,000 curies from atomic
weapons testing totally.
During that period, the atmospheric weapons
testing, those figures are given here.
But then if you look down here at Chernobyl,
you find that the estimates of exposure and the estimates of
those exposed are really quite amazing.
Seventeen thousand and four hundred fatal cancers were
expected among 2.9 billion people exposed.
So more than half of the world's population was exposed
to fallout from this nuclear power plant explosion,
with a very serious estimate of fatal cancer outcomes.
Compared to the Atomic Weapons Testing Program,
where among everybody at the time--this report was done back
in the 1990s by the National Cancer Institute--
everybody in the world was anticipated to have been
exposed, but only 12,000 fatal cancers
were expected from that entire program.
So the magnitude of exposure, the magnitude of risk,
is associated with this kind of a failure, has long been
underestimated.
Now I'm going to leave you at this time with one other
thought, because I opened the lecture
saying that we're facing a very difficult decision on how to
allocate our resources and investments in different kinds
of fuels.
And I want you to think too about the relative risks
associated with coal-fired power plants.
We don't have too much time to talk about coal.
But coal produces not just sulfur and nitrogen oxides,
it produces particulates.
And particulates, particularly in combination--
particulates, particularly,
sorry.
Particulates in combination with the sulfates pose a very
serious health threat.
And many people don't realize that between 20,000 and 60,000
premature deaths in the United States alone every year are now
attributable to coal-fired power plants.
On a world scale, the number is far more
significant.
So these are deaths that are premature deaths,
particularly among those that have background conditions of
cardiovascular illness or other kinds of respiratory illnesses.
So that premature deaths from this form of energy are far
higher than have ever been accounted for with respect to
the nuclear industry.
So that coal has this image of being a relatively safe fuel
compared to nuclear power.
But I'm hoping to get you to rethink that.
The nuclear waste issue I think is overwhelmingly persuasive to
me that the nuclear industry should not be seriously
encouraged.
And I am disappointed and surprised by the Obama
Administration's support that came out just a few weeks ago
for it.
And next Tuesday, we'll be talking about the
future of renewables, and particularly,
the different kinds of legal strategies that have been
employed, including tax strategies,
different subsidies, different kind of credit
systems, in order to try to increase human investment in
renewable sources.
So have a great weekend and enjoy the weather.