A white fog settles along the ridge in the early
morning, the sun engulfed by the white mass.
In a meadow, light white dust settles on top of the scraggly grass. This white blanket covers the entire
landscape, coating roads, roofs and trees for miles around.
As wind whips across the flat, white abyss,
huge clouds of powder are picked up and thrown high into the air, juxtaposing
the navy blue background, and perhaps even more unnerving, the mammoth
industrial complex barely visible through the thick haze. The slowly moving white sludge confirms the
horrific; this powder is not snow, but rather, coal ash.
Hundreds of millions of tons of the gray-white
powder cover the Shanxi providence in China, a disastrous result caused by the nation’s quick rise into industrialism via coal use (Gang). While Chinese coal
technology lags decades behind American and European, the catastrophic
environmental and human toll of this dirty energy source most blatantly
portrays itself in China. Clearly, coal power
must be replaced by a cleaner alternative, and engineering precedent coupled
with societal benefit and risk assessment indicates that nuclear energy is the
best candidate.
Replacing Coal
Nuclear energy is the generation of electricity through the properties of unstable elements, namely, Uranium and Plutonium. As will be outlined in the rest of this paper, generating electricity through these elements is inherently dangerous, with explosions and radiation damage always potential threats. Despite these dangers, nuclear energy provides massive amounts of much needed high-voltage electricity, and does so with very little waste. Throughout this blog post, I will explain why nuclear energy must replace current fossil fuel plants, as well as pragmatically assess the dangers of this form of energy.
For those interested in the technical aspects of electrical girds, continue reading. Otherwise, skip to the "Nuclear as the Base-Load Replacement" heading. From an engineering perspective, nuclear energy is one of the only power sources capable of substituting the functionality of coal on the electrical grid. To understand why coal, nuclear, hydro-electric and geothermal energy are interchangeable only with each other and not with wind, solar and natural gas plants, one must understand the balance between base and peak electrical loads.
For those interested in the technical aspects of electrical girds, continue reading. Otherwise, skip to the "Nuclear as the Base-Load Replacement" heading. From an engineering perspective, nuclear energy is one of the only power sources capable of substituting the functionality of coal on the electrical grid. To understand why coal, nuclear, hydro-electric and geothermal energy are interchangeable only with each other and not with wind, solar and natural gas plants, one must understand the balance between base and peak electrical loads.
Base versus Peak Load
 |
| Power usage and generation over time, KCET |
Base Load Generators
A grid
entirely powered through base load generators would be able to provide cheap
electricity 24/7; however, lack of usage during certain times of day could
damage the electrical grid through overload.
This phenomenon has begun to happen in some nations, such as Germany,
that rely too heavily on base load generators, actually causing a negative
market value of electricity when there is too little demand for it. What this means is that utilities have been
forced to pay electrical users during certain times of day in order to use up
electricity that would otherwise damage the grid.
Peak Load Generators
In contrast,
a grid of entire peak-load generators would be unable to generate consistent
power, resulting in rolling blackouts and damaged equipment, much like what has
occurred in post-Fukushima Japan after the shut-down of most of the nuclear
power plants (BBC Staff).
Advocates of renewable energy, in particular, solar, point out that many
residential houses are run at least partially off of solar energy, and the
technology exists to power these houses entirely through this peak-load
generator. However, as Japanese industry has found, with
only peak-load generators online, assembly lines are routinely ground to a halt
and valuable equipment which requires constant electrical monitoring may be
damaged. In recent months, this
phenomena has threatened to send Japanese manufacturers to China (Kubota).
Nuclear as the Base-Load Replacement
As the situations in Germany and Japan show, grids
must have a balance between base and peak load generators, we cannot possibly
replace coal with primarily peak-load renewable electrical generators. Unfortunately, geothermal and hydroelectric
generators are not sufficient either, as these require very specific natural
conditions which are not present in enough places to be practical means of mass
electrical generation. This leaves
nuclear and coal as the only two base-load generation techniques capable of
universal application.
Coal versus Nuclear
Coal and nuclear power have many of the same
strengths. They are both relatively
cheap, both are excellent base load generators and perhaps most importantly,
both are constructible in nearly every terrestrial climate. The ills of coal power are well known and
documented. Soot, ash and smog pollution have been a signature of
industrialization since its infancy, and 1880’s London stands beside modern Beijing
as a testament to this. However, as its
critics have pointed out, nuclear energy has its own environmental as well as
societal issues.
Nuclear Safety
Although
rare, major nuclear disasters generate global attention when they do occur, because unlike the localized pollution from coal plants, radiation
contamination has the potential to travel hundreds of miles. Furthermore, the infamous Fukushima and
Chernobyl disasters demonstrate nuclear power’s catastrophic potential if
managed improperly. However, commonplaces
regarding nuclear energy ignore the fact that 95% of the 435 plants across the
planet have never experienced so much as a core anomaly (reference my map
of all recorded nuclear incidents), much less a radiation leak (nei.org).
Perhaps the most convincing argument for the safety of nuclear energy is
actually the aftermath of one of the worst nuclear ‘disasters’ in history:
Three Mile Island.
3 Mile Island Incident
 |
| Reconstruction model of the melted down core, courtesy of the Smithsonian |
From the
perspective of nuclear scientists the world over, Three Mile Island is a
disaster of epic proportions, a failure of nearly every safeguard espoused by
the industry. Ultimately, however, Three
Mile Island was only a disaster for the company running the reactor—no
radiation leakage, no employees injured, and no citizen exposed to radiation.
 |
| First entry into the reactor containment building, courtesy of the Smithsonian |
Middletown Interviews
 |
| Middletown |
Fukushima
 |
| A damaged Fukushima reactor building, The New York Times |
As pointed out previously, the citizens of Middletown were not interviewed in light of Three Mile Island, they were interviewed in light of Fukushima, one of the two worst radiological disasters in history. Unlike Three Mile Island, Fukushima will have a real human toll, because the containment structure was breached. However, critics of nuclear energy should note that to date, the UNSCEAR’s ongoing study of the Fukushima disaster has determined that “none of the six former reactor workers who have died since the catastrophe perished due to the effects of radiation” (Jahn).This is not to diminish the Fukushima disaster, merely put it into perspective. Reputable radiologists estimate that even in the worse-case scenario for radiation induced cancer deaths is 1500 deaths, “only 10% of the immediate tsunami deaths” (Muller). While Fukushima is, without a doubt, a terrible accident, the toll must be compared to the cost of coal, which contributes to an estimated 13,000 deaths annually in the United States alone (Zelman). Given that this terrible loss is tolerated on a daily basis, even a disaster as tragic as the Japanese core meltdown is preferable to daily coal pollution.
 |
| The Wall Street Journal |
Comanche Nuclear Power Plant and Safety Measures
The Fukushima
disaster was a result of poor engineering and poor management. As many observers have pointed out, an unimaginably
large tsunami triggered the Fukushima disaster, something we can hardly expect
engineers and urban planners to anticipate.
And yet, across the world, those building and facilitating nuclear
plants have done just that; constructed and maintained plants capable of
remaining safe in even the most apocalyptic conditions. Take, for instance, the Comanche Nuclear
Power plant southeast of Dallas, Texas.
Engineers have rated the containment structures of the complex to be
capable of withstanding 300 mile and hour winds, the highest ever recorded for
a tornado (Weiss). Officials and engineers are
so confident in the construction of the Comanche plant that Dale Klein, previous
head of the NRC, stated that “if there is ever a tornado around Comanche Peak,
you want to be inside the containment structure because that building is
robust” (Weiss).
 |
| The Comanche Plant, Dallas Morning News |
Cooling Failure at Fukushima
Fukushima’s
containment structures were not actually damaged by the tsunami itself; it was
rather the coolant pumps which were damaged and caused the slow meltdown of the
cores. If anything, the durability of
the containment structures was demonstrated by its ability to weather a
tsunami. In the Fukushima incident, the
tsunami destroyed the electrical network which would ordinarily power the
cooling pumps, an event all nuclear facilities are equipped for. Fukushima was no different—it had back up
diesel generators on site to cool the reactor in the case of electrical failure
(Weiss). However, the Fukushima complex had one fatal
design flaw; “the fuel for the
generators was swept away by the tsunami” (Weiss). Even at the Comanche plant, which is safe in
the heartland of the United States, there are “several protected storage tanks
that hold a total of seven days’ worth of fuel” (Weiss). As an engineering student myself, it is
unrealistic to expect engineers to completely prepare for some of the most
unlikely and unpredictable events this universe has to offer, such as tsunamis. However, in the case of Fukushima, the lack
of foresight on the part of Japanese engineers and managers is primarily to
blame for the Fukushima disaster. Even
at landlocked plants, fuel supplies are secured and the failure of the
Fukushima plant management to secure these back-up cooling system assets prior
to the tsunami would be considered criminal here in the United States.
Environmental Toll
The
human cost of nuclear energy is not the only one that must be considered, as the
environmental toll is another important concern. As far as the environmental toll of
radiation, there are four primary ways of
measuring radiation exposure, according to the Nuclear Regulatory Commission:
radiation released by a radio-active object, radiation traveling through an
area, radiation absorbed and effective dose absorbed (“MeasuringRadiation”). The first two measurements apply
to all living creatures, but the second two are unique to the way a species
absorbs radiation. The measurement traditionally
used to measure the aftermath of a radiological event, the rem, applies only to
humans. The broad concepts described in
these human-based studies are applicable across most living things, but given
the geographical entrapment of the majority of species, are also incredibly
difficult to measure. As a result, arguments
regarding the environmental impact of radiation are best limited to its impact
on mankind, using our species as a radiological barometer. Measuring radiation in the context of mankind
is not only an excellent environmental indicator; it is actually more sensitive
than required, as shown in
the aftermath of the Chernobyl incident.
Chernobyl
 |
| The abandon city of Pripyat, with the Chernobyl reactor in the distance, Huffington Post |
For those unaware
of the history of the Chernobyl incident, it occurred in April of 1986. Only a few years after the scare at Three
Mile Island, the Chernobyl incident epitomizes everything that could possibly
go wrong with a nuclear reactor. Until
Fukushima, Chernobyl stood in infamy as the most horrific nuclear accident in
the history of man, and given the prompt response of the Japanese government to
Fukushima, will probably retain this position indefinitely. A poor clean up, failure to publicize the
meltdown and a hesitance to evacuate cities resulted in tens of thousands of
deaths across the Ukrainian countryside in the next two decades.
Aftermath of Chernobyl
 |
| The Red Forest, destroyed by radiation |
Disposal of Radioactive Waste
Apart from
concerns over nuclear disasters, disposal of the radioactive waste is a serious
but misunderstood issue. For more information on the permanent disposal of high-level nuclear waste, visit this site discussing the proposed disposal site at Yucca Mountain. Currently, all
“high-level nuclear waste” is stored in
“temporary storage, mainly at nuclear power plants” (Radioactive Waste: Production, Storage, Disposal (NUREG/BR-0216,Revision 2)). One of the common misconceptions
of nuclear energy is the alleged lack of safety of “temporary” containers high-level
waste is stored in now. In fact, the containers are designed to withstand “a 30
foot drop,” “immersion of the package under 15 feet of water” and the “exposure
of the entire package to 1475 degrees F” (SectionTwo Packaging, Transportation and Storage of Radioactive Materials). Additionally, even Level III (highest-level) waste
containers are constructed such that they release less than 0.1 mrem/hr, which
is next to no ambient radiation (Section Two Packaging, Transportation andStorage of Radioactive Materials). There
is little concern about radiation leakage from the waste containers currently used;
the real concern is with the security of the containment facilities. Short of nuclear weapons, no attack on the
containment structure of a nuclear plant would be capable of inducing a
meltdown; however, conventional attacks on current waste storage facilities are
a risk. Permanent disposal of high-level
nuclear waste is a distinctly separate environmental and governmental issue,
separate from the proliferation of nuclear power. It should be noted, however, that current
storage systems, absent a malicious attack, pose next to no risk to surrounding
populations or environments.
Nuclear
energy has inherent risks, but we can mitigate these risks through intelligent
engineering and management. Furthermore,
since nuclear energy is competing with the coal industry, which has already
demonstrated itself as a more deadly means of power production, the ills of
nuclear power must be compared with the ills of coal energy. When compared, it becomes very obvious that
nuclear energy is the superior choice: less emission, less waste and less
fatalities while producing the same amount of power at nearly the same
price.
 |
| Diablo Canyon Nuclear Power Plant, Central California |
Or
 |
| Coal power plants along the Ohio River |
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