Nuclear Power Pros and Cons

December 2007

Introduction

After years of debate about the consequences of CO2 emissions, scientists have finally reached a general consensus – CO2 emissions are perhaps the greatest threat to mankind we now face and emissions must be drastically and urgently cut. The general public, along with the politicians chosen to represent them, are now taking the issue very seriously – although perhaps still not as seriously as the scientific community is urging.

The general public puts great store in wind power, bio-fuel and energy saving building design etc, but scientists generally advocate Nuclear Power. Of course, some scientists are opposed to Nuclear Power, indeed some Scientists even argue CO2 emissions are unimportant, but it’s the general consensus that is important. For example: "The Royal Society" (the preeminent learned society for science in the UK, founded in 1660 and claimed to be the oldest such society still in existence) has frequently advocated the building of new power stations (eg their 2003 press release “Government must show political courage over nuclear power”).

However, for the general public, the considered advice of learned institutions such as the Royal Society often carries little import. It’s well known that the odds of winning the UK lottery are pointlessly small, yet 70% of the UK population still play. Nuclear Power remains unpopular with the general public, and therefore even the few elected politicians who have supported it, such as Tony Blair, have failed to build any new power stations. Even Tony Blair just talked about Nuclear as 'part of the mix' rather than the key technology. Aside from France almost all new Nuclear Power stations are being built by totalitarian governments such as China, and even in these cases the motivation is more the cost of Oil and Gas rather that climate change.

For an intelligent rational person, living in a democracy can be a depressing state of affairs, nevertheless, all one can do is repeatedly argue the case and hope that a majority will eventually see the light. In that spirit I will again outline the case for Nuclear Power, and hope it will convince a few readers…

The Nuclear Power Debate

(1 of 2) The Upside of Nuclear – Leaving safety aside for a moment

CO2 Emissions

About 50 Sizewell B style reactors could generate 100% of the UK’s electricity without any CO2 emissions. This would cut UK CO2 emissions by 25%. In order to decimate CO2 emissions both gas/oil/coal heating (many industrial processes require heat) and petrol/diesel cars/trucks would have to be switched to nuclear produced electricity or hydrogen. The challenge here is cost because converting thermal energy to electricity or hydrogen and then back to thermal energy is very inefficient. Steam turbine electricity production and distribution runs at around 33% efficiency, and the next generation high temperature reactors will probably generate hydrogen with efficiencies of around 50%. Only by mass producing very very cheap Nuclear Power can gas/oil/coal heating be phased out. The economics of electric cars are easier because the combustion engine is much less efficient than the electrical motor. Project Better Place has calculated that if all Israel's 2m cars went electric they would consume just 2,000 megawatts a year. To solve the C02 problem we must phase out the use of fossil fuels in heating and transport as well as electricity generation. Some see Nuclear only as 'part of the mix', but economies of scales are vital to bring down the costs of Nuclear far enough to make this possible. No known renewable fuel could possibly achieve this goal. The Nuclear debate is not just about today's electricity production, it's about completely phasing out fossil fuels across the economy.

Cost

China is very cost conscious and has huge coal reserves, so it unsurprisingly generates 80% of its electricity from coal fired power stations. Currently the Chinese generate just 2% of their electricity from Nuclear Power, but by 2020 an additional 32 reactors will more than quadruple that output. The reactor designs come from French and US companies. In time China is talking about possibly adding another 300 reactors, probably after choosing an optimal design for 'mass production' (to put this into perspective: there are only 460 reactors operating in the world today). China is moving aggressively into Nuclear Power because it believes these new reactors will produce electricity at prices comparable to its coal power stations.

Looking at the costs in detail: Westinghouse claim a three year build time and $1bn construction cost for its new AP1000 reactor after (huge) volume production discounts. Allowing for 5% funding of the construction costs, running costs and decommissioning costs this gives an all in cost of 2.2 US cents per KWHr which equates to cheaper electricity from nuclear than any fossil fuel based generating facility, including Australian Coal power with no sequestration or CO2 emission charges (more info). China has licensed the AP1000 reactor and is expected to offer them for sale. The Indian Steel Power and Infrastructure company Abhijeet is in the process of buying a 1,000M megawatt Coal plant from China with both the equipment and the construction crew will coming from China. In the same way mass produced off the shelf Chinese AP1000s complete with Chinese construction crews could be available in the future.

The UK's mixed record with the cost of Nuclear Power is no guide to the economics of mass produced modern reactor designs. Indeed, even the older French reactors have proven economically successful and today France enjoys the lowest electricity prices in the EU.

(2 of 2) The safety side of Nuclear

The general public has four main safety concerns about nuclear:

(a) Cancer Clusters around Nuclear Plants

There have been some reports that suggest an increased rate of cancer or childhood lukemia around Nuclear Power Stations. The major government studies have failed to find any link (eg Distribution of childhood leukaemias and non-Hodgkin's lymphomas near nuclear installations in England and Wales), and since radiation levels around nuclear installations are the same as everywhere else, it is hard to see how there could be one! More recently studies have been looking at a link between high voltage power lines and cancer, so far these results are inconclusive, but if there were clusters around power stations that could be a cause. Clusters or no clusters, the numbers are tiny - mobile phone radiation is probably a greater threat, but for most people the convenience of a mobile phone outweighs the possible risk. Ironically, studies do clearly show asthma clusters in the vicinity of coal fired power stations but the general public appears far less concerned about them.

(b) Waste Disposal

High level nuclear waste, primarily spent nuclear fuel rods, remain radioactive for up to 10,000 years, and the general public usually cite them as their number one concern on Nuclear Power. However, when asked about the amount of waste generated member of the public generally wildly over estimate the volume of waste produced. In fact, a power station like Sizewell B produces only three cubic metres of high level waste per year (link and link). Even if all the UKs electricity was produced by nuclear it would take 500 years to fill Albert Hall with high level waste. Although there is great debate about finding a long term storage facility the total amount of waste is so small it may as well be stored above ground and left for future generations to recycle when the technology is cheaper, or to dispose of in some other way (eg even in space). Yes it’s dangerous, but so are the nuclear submarines and stock piles of nuclear weapons we have developed. To worry about such a small volume of waste is irrational. By contrast the Albert Hall would fill up with general land fill waste from the UK every two hours – that is clearly a much more pressing issue.

For every cubic metre of high level waste about three times as much intermediate level waste is produced. It comprises some reprocessing wastes and some activated reactor components salvaged during decommissioning. It does require some shielding and longer lived isotopes are buried more deeply. Lead is sufficient for this. Due to the low levels of radioactivity compared to high level waste, there is no technical problem in disposing of this properly. Some highly toxic chemicals wastes such as cyanides represent a much greater hazard.

Low level waste comprises 90% of all waste. Most of it is clothes and rags contaminated with small quantities of radionuclides. They do not represent a large hazard and can be buried in shallow landfills such as Drigg at Sellafield. The chemical hazards from all manner of other wastes from other industries represent as much or more of a threat than low level wastes from the nuclear industry.

(c) Will Uranium run out?

Although Uranium is a finite resource there is enough to last thousands of years. In practice an alternative energy source, such as Fusion, is likely to come along long before then. Uranium is about 40 times as abundant as silver in the Earth's Crust.

(d) Earthquakes and Terrorism

Most nuclear plants are designed to withstand earthquakes by shutting down safely in the event of a tremor. Today there are several Japanese Nuclear Plants running in earthquake prone areas, and there have been examples of automatic reactor shut downs due to ground acceleration exceeding trip settings. For example on July 12 2007 a powerful earthquake shook Japan’s northwestern coast killing nine people and injuring 1,000 people. At the Kashiwazaki Kariwa Nuclear Power Plant the reactor automatically shut down. The shaking of the site also caused a small fire, and a tank of very mildly radioactive heavy water waste spilled and leaked outside the plant. The spillage of some low level liquid waste and the fire represented no risk to human safety, and, even though it attracted a lot of publicity, it did not actually represent a design failure – for cost reasons only critical parts of nuclear plants are protected from earthquakes.

Since Sep 11th protection against terrorist attacks is under review. David Kyd, a spokesman for the International Atomic Energy Agency (IAEA) has said: "Reactors have the most robust engineering of any buildings in the civil sector — only missile silos and nuclear bunkers are built to be tougher. They are designed to be earthquake-proof, and our experiences in California and Japan have shown them to be so. They are also built to withstand impacts, but not that of a wide-bodied passenger jet full of fuel. A deliberate hit of that sort is something that was never in any scenario at the design stage." Airplane cockpit doors are now kept locked to prevent the hijacking of large aircraft because the consequences are also horrific if they are used against targets such as the World Trade Centre (2,974 deaths). Also the military are now aware of the risk of hijacking. However, further protection for the Nuclear Industry is being considered. In the Czech Republic some nuclear plants are now being protected by anti-aircraft missiles, other cheaper options under consideration include the erection of steel poles and steel cable approximately 300 feet from and surrounding the reactor building. Any airliner would be shredded, its fuel ignited and dispersed. The terrorism issue needs to carefully considered, but it is not insurmountable problem.

to do: add details of new reactor in Finland with double containment and sep11th proof design now under construction. also reactors may be more plane proof that i suggest above

(e) Risk of an Accident

Chernobyl

The Chernobyl Disaster is of course the accident that really changed the perception of nuclear power in the minds of the general public. After Chernobyl politicians abandoned nuclear power in several European countries, and a moratorium was placed on new plants in many other countries- although interestingly not in Ukraine where the disaster actually occurred.

During the daytime of April 25 1986, reactor 4 was scheduled to be shut down for maintenance. A decision was made to test the ability of the reactor's turbine generator to generate sufficient electricity to power the reactor's safety systems in the event of a loss of external electric power. As conditions to run this test were prepared another power station unexpectedly went offline. The Kiev grid controller requested the test be postponed as electricity was needed to satisfy the evening peak demand. The ill-advised safety test was then left to be run by the skeleton crew night shift. Many of this reactor crew had been drafted in from coal powered plants and had no experience in nuclear power plants, others had only a little experience in nuclear submarine power plants.

A combination of inexperience, miscommunication, failure to follow procedure, and bad design led to the lid blowing off the reactor, followed by a fire sending material into the atmosphere. The nuclear meltdown provoked a radioactive cloud which floated over Europe. In Sweden workers at the Forsmark Nuclear Power Plant 1,100 km from the Chernobyl site found radioactive particles on their clothes. It was Sweden's search for the source of radioactivity, after they had determined there was no leak at the Swedish plant, which led to the first hint of a serious nuclear problem in the western Soviet Union.

The 2005 report prepared by the Chernobyl Forum, led by the International Atomic Energy Agency (IAEA) and World Health Organization (WHO), attributed 56 direct deaths (47 accident workers, and nine children with thyroid cancer), and estimated that there may be 4,000 extra deaths due to cancer among the approximately 6.6 million most highly exposed.

A 30km radius area (the “Zone Of Alienation”) around the reactor remains to this day mostly evacuated. Today the Zone has become something of a wildlife haven and has provided some interesting research about the impact of radioactive contamination (see BBC News Story). Hiroshima was rebuilt after the US Nuclear attack on it, in this isolated area of the Ukraine cleaning up was not deemed worth the cost.

Three Mile Island

The next most significant accident in the history of commercial Nuclear Power was the 1979 Three Mile Island Accident in the USA (the serious 1957 Windscale Fire in the UK was at a military reactor used for weapons production). At Three Mile Island operators under stress misdiagnosed a fault after a series of instrument failures and ended up with a partial reactor core meltdown (The Three Mile Island project started in 1968. Today technology has vastly improved and such an accident is believed impossible with the latest reactor designs). Although the reactor core partially melted it was still contained within the reactor building so there was no leakage. However, in the week following the accident, some steam and hydrogen was very controversially removed from the reactor by deliberately venting straight to the atmosphere. The average radiation dose to people living within ten miles of the plant as a result of this venting was calculated at about equal to a chest X-ray, therefore it was deemed a safe operation and no one was evacuated from the area. The accident occurred, by some strange fate, just 12 days after the release of the popular film “The China Syndrome”, in which Jane Fonda investigates a fictional near-accident in a nuclear plant. Although the accident caused no deaths or injuries to plant workers or members of the nearby community, it destroyed US public support for Nuclear Power.

Accident Analysis

According to the World Nuclear Organization, a major private-sector organization that seeks to promote the nuclear power, “Apart from Chernobyl, no nuclear workers or members of the public have ever died as a result of exposure to radiation due to a commercial nuclear reactor incident”.

So in these many years of Nuclear Power Generation we have had one totally irresponsible accident in a decaying eastern block country that, according to the World Health Organization, is responsible for around 4,000 deaths (taking account of all deaths in the past and the future). To put that into perspective China is currently losing more than 7,000 miners a year just digging up coal to feed its many power stations (link). After that coal is burnt organizations like the WHO estimate the number of premature deaths in China caused by the coal burning airborne emissions is in the hundreds of thousands. In fact, the World Bank recently estimated worldwide deaths from fossil fuel burning air pollution at 5 million people per year - replacing fossil fuels with nuclear would save as many lives as 1,000 Chernobyl accidents a year!!! Yet, the number of deaths from climate change in the future is likely to dwarf even this shocking number.

Conclusions

Clearly the scientific community is right in their long held pro Nuclear viewpoint, the argument is more black and white than it is shades of grey. However, given the long failure of alternative fuels and climate change treaties to solve the CO2 problem I believe the issue is now critically important and the educated must make every effort to enlighten the general public.

It is ironic that idealistic notions of social equality led to socialism, a philosophy which instead of enriching the average man actually plunged him into poverty, sometimes even starvation. In the same way, Environmentalists who hold the future of the planet so dear to their heart, have fought against Nuclear Power and in the process created a hellish world of fossil fuel dependence which has served only to impoverish and pollute our world. Unworthy nations have profited and wars have been waged over a filthy and primitive resource which should have been phased out years ago. In the Darwinian world we live in, drive, courage and intelligence allow life to thrive - stagnation, indecisiveness and a irrationality lead eventually to death.