Here is my problem with nuclear power plants

How long will the world's uranium supplies last?
Steve Fetter, dean of the University of Maryland's School of Public Policy, supplies an answer:

f the Nuclear Energy Agency (NEA) has accurately estimated the planet's economically accessible uranium resources, reactors could run more than 200 years at current rates of consumption.

Most of the 2.8 trillion kilowatt-hours of electricity generated worldwide from nuclear power every year is produced in light-water reactors (LWRs) using low-enriched uranium (LEU) fuel. About 10 metric tons of natural uranium go into producing a metric ton of LEU, which can then be used to generate about 400 million kilowatt-hours of electricity, so present-day reactors require about 70,000 metric tons of natural uranium a year.

According to the NEA, identified uranium resources total 5.5 million metric tons, and an additional 10.5 million metric tons remain undiscovered—a roughly 230-year supply at today's consumption rate in total. Further exploration and improvements in extraction technology are likely to at least double this estimate over time.

More: http://www.scientificamerican.com/article.cfm?id=how-long-will-global-uranium-deposits-last

...the vast majority of the heat in Earth's interior—up to 90 percent—is fueled by the decaying of radioactive isotopes like Potassium 40, Uranium 238, 235, and Thorium 232 contained within the mantle. These isotopes radiate heat as they shed excess energy and move toward stability. "The amount of heat caused by this radiation is almost the same as the total heat measured emanating from the Earth."

Thanks for your question, John… You are absolutely correct in
stating that Earth has been cooling since its formation approximately
4.6 billion years ago… and with that statement, you have hit on the
important issue; what is the source of that heat in the first place?
The primary energy source of Earth is radioactive decay. The sun,
gravity, and meteorite impacts all contribute some energy, as well,
but not nearly as much as that provided by radioactive decay
(estimated for the bulk Earth at around 6.18x10-12 watts/kilogram).

As a radioactive isotope decays, particles are ejected from its
nucleus for the purpose of stabilizing the atom. Radioactive decay
processes produce electromagnetic radiation (gamma rays, for example)
which transmit energy from the nucleus to the environment.
Additionally, the ejected particles have kinetic energy that
ultimately converts to thermal energy as the particles are
mechanically resisted by their environment. The crust, mantle, and
core of Earth contain varying amounts of radioactive elements, the
most important for heat production being Uranium-238, Uranium-235,
Thorium-232, and Potassium-40, with half-lives of roughly 4.47 billion
years, 704 million years, 14.1 billion years, and 1.28 billion years,
respectively. From the half-lives of these isotopes and a comparison
with the age of Earth, you can see that internal heat production via
radioactive decay will likely persist at near current levels for quite
some time to come.

http://www.newton.dep.anl.gov/askasci/env99/env276.htm

http://en.wikipedia.org/wiki/World_energy_resources_and_consumption

The estimates of remaining non-renewable worldwide energy resources vary, with the remaining fossil fuels totaling an estimated 0.4 YJ (1 YJ = 1024J) and the available nuclear fuel such as uranium exceeding 2.5 YJ. Fossil fuels range from 0.6-3 YJ if estimates of reserves of methane clathrates are accurate and become technically extractable. Mostly thanks to the Sun, the world also has a renewable usable energy flux that exceeds 120 PW (8,000 times 2004 total usage), or 3.8 YJ/yr, dwarfing all non-renewable resources.

http://www.treehugger.com/files/2009/09/surface-area-required-to-power-the-whole-world-with-solar-power-wind.php

Surface Area Required to Power the Whole World With Solar and Wind Power

Citigroup Global Markets
New Nuclear – The Economics Say No

9 November 2009

Green lighting new nuclear? — The UK government today announced a fast-track planning process for new nuclear power stations. 10 sites have been approved for possible development. The government is presenting today’s announcement as providing the green light for a major new nuclear programme, which it says is needed to meet climate change and security of supply targets.

-But no financial support has been offered — The government has not announced any direct financial support for new nuclear. The government still seems to expect the private sector to take an unacceptable level of risk, in our view.

-The five big risks — Nuclear power station developers face five big risks: Planning, Construction, Power Price, Operational, and Decommissioning. The government today has sought to limit the Planning risk. While important for encouraging developers to bring forward projects, this is the least important risk financially.

-The three Corporate Killers — Three of the risks faced by developers — Construction, Power Price, and Operational — are so large and variable that individually they could each bring even the largest utility company to its knees financially. This makes new nuclear a unique investment proposition for utility companies.

-No where else in the world — Government policy remains that the private sector takes full exposure to the three main risks; Construction, Power Price and Operational. Nowhere in the world have nuclear power stations been built on this basis.

-Nor will they be built in the UK — We see little if any prospect that new nuclear stations will be built in the UK by the private sector unless developers can lay off substantial elements of the three major risks. Financing guarantees, minimum power prices, and / or government-backed power off-take agreements may all be needed if stations are to be built.
Download full report: https://www.citigroupgeo.com/pdf/SEU27102.pdf

Estimates for new nuclear power place these facilities among the costliest private projects ever undertaken. Utilities promoting new nuclear power assert it is their least costly option. However, independent studies have concluded new nuclear power is not economically competitive.

Given this discrepancy, nuclear’s history of cost overruns, and the fact new generation designs have never been constructed any where, there is a major business risk nuclear power will be more costly than projected. Recent construction cost estimates imply capital costs/kWh (not counting operation or fuel costs) from 17-22 cents/kWh when the nuclear facilities come on-line. Another major business risk is nuclear’s history of construction delays. Delays would run costs higher, risking funding shortfalls. The strain on cash flow is expected to degrade credit ratings. Generation costs/kWh for new nuclear (including fuel & O&M but not distribution to customers) are likely to be from 25 - 30 cents/kWh. This high cost may destroy the very demand the plant was built to serve. High electric rates may seriously impact utility customers and make nuclear utilities’ service areas noncompetitive with other regions of the U.S. which are developing lower-cost electricity.

http://www.fas.org/rlg/980826-pu.htm

August 26, 1998

Reactor-Grade Plutonium Can be Used to Make Powerful and
Reliable Nuclear Weapons: Separated plutonium in the fuel
cycle must be protected as if it were nuclear weapons.

<snip>

These facts are interpreted by various bodies as follows:

Mark 1993:
"The difficulties of developing an effective design of the
most straightforward type are not appreciably greater with
reactor-grade plutonium than those that have to be met for
the use of weapons-grade plutonium."

CISAC(3) 1994:
"In short, it would be quite possible for a potential
proliferator to make a nuclear explosive from reactor-grade
plutonium using a simple design that would be assured of
having a yield in the range of one to a few kilotons, and
more using an advanced design. Theft of separated plutonium
whether weapons-grade or reactor-grade, would pose a grave
security risk."

American Nuclear Society Special Panel Report(4) 1995:
"We are aware that a number of well-qualified scientists in
countries that have not developed nuclear weapons question
the weapons-usability of reactor-grade plutonium. While
recognizing that explosives have been produced from this
material, many believe that this is a feat that can be
accomplished only by an advanced nuclear- weapon state such
as the United States. This is not the case. Any nation or
group capable of making a nuclear explosive from weapons-
grade plutonium must be considered capable of making one
from reactor- grade plutonium."

U.S. Department of Energy(5) 1997:
"Proliferating states using designs of intermediate
sophistication could produce weapons with assured yields
substantially higher than the kiloton-range made possible
with a simple, first- generation nuclear device." and

"The disadvantage of reactor-grade plutonium is not so much
in the effectiveness of the nuclear weapons that can be made
from it as in the increased complexity in designing,
fabricating, and handling them. The possibility that either
a state or a sub-national group would choose to use
reactor-grade plutonium, should sufficient stocks of
weapon-grade plutonium not be readily available, cannot be
discounted. In short, reactor-grade plutonium is
weapons-usable, whether by unsophisticated proliferators or
by advanced nuclear weapon states. Theft of separated
plutonium, whether weapons-grade or reactor-grade, would
pose a grave security risk."

As an author of the 1994 CISAC report, I helped formulate
the statement that I quote above. What should the reader
believe? Individuals are often skeptical of official
statements, and it is often said "Those who know, don't
speak; and those who speak, don't know." But that is not
the case with the members of CISAC, all of whom endorsed
this statement; they both know and speak. It is
particularly to be noted that among the Committee are the
following physicists who are knowledgeable about nuclear
weapons and who reviewed a secret study done for CISAC by
the Los Alamos National Laboratory and the Lawrence
Livermore National Laboratory-- the United States' two
nuclear weapon design laboratories. Besides myself, these
include John P. Holdren, Michael M. May, and W.K.H.
Panofsky. May is a former director of the Lawrence
Livermore National Laboratory.

<snip>

The global nuclear order is changing. Concerns about climate change, the volatility of oil prices, and the security of energy supplies have contributed to a widespread and still-growing interest in the future use of nuclear power. Thirty states operate one or more nuclear power plants today, and according to the International Atomic Energy Agency (IAEA), some 50 others have requested technical assistance from the agency to explore the possibility of developing their own nuclear energy programs. It is certainly not possible to predict precisely how fast and how extensively the expansion of nuclear power will occur. But it does seem probable that in the future there will be more nuclear technology spread across more states than ever before. It will be a different world than the one that has existed in the past.

This surge of interest in nuclear energy — labeled by some proponents as "the renaissance in nuclear power" — is, moreover, occurring simultaneously with mounting concern about the health of the nuclear nonproliferation regime, the regulatory framework that constrains and governs the world's civil and military-related nuclear affairs. The Nuclear Non-Proliferation Treaty (NPT) and related institutions have been taxed by new worries, such as the growth in global terrorism, and have been painfully tested by protracted crises involving nuclear weapons proliferation in North Korea and potentially in Iran. (Indeed, some observers suspect that growing interest in nuclear power in some countries, especially in the Middle East, is not unrelated to Iran's uranium enrichment program and Tehran's movement closer to a nuclear weapons capability.) Confidence in the NPT regime seems to be eroding even as interest in nuclear power is expanding.

This realization raises crucial questions for the future of global security. Will the growth of nuclear power lead to increased risks of nuclear weapons proliferation and nuclear terrorism? Will the nonproliferation regime be adequate to ensure safety and security in a world more widely and heavily invested in nuclear power? The authors in this two-volume (Fall 2009 and Winter 2010) special issue of Dædalus have one simple and clear answer to these questions: It depends.

On what will it depend? Unfortunately, the answer to that question is not so simple and clear, for the technical, economic, and political factors that will determine whether future generations will have more nuclear power without more nuclear proliferation are both exceedingly complex and interrelated. How rapidly and in which countries will new nuclear power plants be built? Will the future expansion of nuclear energy take place primarily in existing nuclear power states or will there be many new entrants to the field? Which countries will possess the facilities for enriching uranium or reprocessing plutonium, technical capabilities that could be used to produce either nuclear fuel for reactors or the materials for nuclear bombs? How can physical protection of nuclear materials from terrorist organizations best be ensured? How can new entrants into nuclear power generation best maintain safety to prevent accidents? The answers to these questions will be critical determinants of the technological dimension of our nuclear future....

Spent fuel from a power reactor *IS PERFECTLY SUITABLE* as the feedstock
for weapons-grade plutonium production as long as the burn period is
short. What you get out of the power reactor in such situations is just as
useful as what you get out of a purpose-built plutonium production
reactor.

Sure, you're wasting some fuel value, but if the point is to divert the waste
into weapons production, that's a reasonable tradeoff.

Nuclear power plants *ARE* a proliferation hazard, and no amount of fancy
statistical dancing can deny that.

I don't see how this post pertains to the OP.

http://www.democraticunderground.com/discuss/duboard.php?az=show_mesg&forum=389&topic_id=7839893&mesg_id=7840249

There are such things as "Breeder Reactors" They can make fuel for other reactors.

and seeing as the United States is a signer of the Nuclear Non-proliferation agreement, I would like to see how that would work.

It wasn't the United States who's been giving away nuclear info to non-nuclear countries.

http://en.wikipedia.org/wiki/Atoms_for_peace

The United States then launched an "Atoms for Peace" program that supplied equipment and information to schools, hospitals, and research institutions within the U.S. and throughout the world. The first nuclear reactors in Iran and Pakistan were built under the program by American Machine and Foundry.

nowhere has statistical or any one else for nuclear power talked about giving power plants to non-nuclear countries.

http://www.democraticunderground.com/discuss/duboard.php?az=view_all&address=389x6527356

Statistical Fri Sep-11-09 05:08 PM

IAEA hikes nuclear power projections for 2030 (40% more reactors in next 2 decades).

<snip>

We are a global leader in reactor design, construction, and operation. We should be able to take a substantial portion of the world market.

<snip>

http://en.wikipedia.org/wiki/Atomic_bombings_of_Hiroshima_and_Nagasaki

After six months of intense strategic fire-bombing of 67 Japanese cities the Japanese government ignored an ultimatum given by the Potsdam Declaration. By executive order of President Harry S. Truman the U.S. dropped the nuclear weapon "Little Boy" on the city of Hiroshima on Monday, August 6, 1945,<1> <2> followed by the detonation of "Fat Man" over Nagasaki on August 9. These are the only attacks with nuclear weapons in the history of warfare.<3>

<snip>

Plans for more atomic attacks on Japan

The U.S. expected to have another atomic bomb ready for use in the third week of August, with three more in September and a further three in October.<77> On August 10, Major General Leslie Groves, military director of the Manhattan Project, sent a memorandum to General of the Army George Marshall, Army Chief of Staff, in which he wrote that "the next bomb . . should be ready for delivery on the first suitable weather after 17 or August 18." On the same day, Marshall endorsed the memo with the comment, "It is not to be released over Japan without express authority from the President."<77> There was already discussion in the War Department about conserving the bombs in production until Operation Downfall, the projected invasion of Japan, had begun. "The problem now is whether or not, assuming the Japanese do not capitulate, to continue dropping them every time one is made and shipped out there or whether to hold them . . . and then pour them all on in a reasonably short time. Not all in one day, but over a short period. And that also takes into consideration the target that we are after. In other words, should we not concentrate on targets that will be of the greatest assistance to an invasion rather than industry, morale, psychology, and the like? Nearer the tactical use rather than other use."<77>

In total, Dr. Sternglass estimates that 19 million adults have died prematurely and that an additional million children have died as a result of radiation in the air from nuclear bomb tests, nuclear plant accidents and radiation released into the atmosphere from power plants.

Some people have found Sternglass' radiation research to be "groundbreaking".<6> However, his research has also been frequently criticized by local, state and federal environmental and health agencies, when the results of his research on the health effects of low level radiation
could not be verified by peer review.<7> Sternglass has been accused of using faulty methodology, including selection bias, in his research.<1>

Radon gas occurring naturally in the soil is a problem for many parts of Eastern Pennsylvania. It is a known radioactive health hazard. Scopelliti, who lives one mile from his power plant, has installed a passive radon vent in his basement. “If there is a regional pattern that might be caused by radioactivity, I would first look to radon,” he said.