Mining companies under encouragement by the South African Government now want to mine Uranium on a vast scale all around South Africa. 120 years of Uranium pollution due to Gold Mining Activities has never been cleaned up ... what will make this any different?

Wednesday, October 17, 2007

Nuclear Emissions - Helen Caldicott

URANIUM MINING, MILLING, ENRICHING, ROUTINE RELEASES AND ACCIDENTAL RELEASES

In the last chapter we discussed the medical, physical and biological characteristics of radiation.

In this chapter we will deal with the toxic radioactive legacy of each step of the nuclear fuel chain and the ecological and health impacts that this legacy bequeaths for this and all future generations

As we proceed through this chapter it will become more than obvious that the steps necessary for the production of nuclear power are so medically dangerous that the production, dissemination and distribution of nuclear materials should be subject to the same stringent taxes and restrictions as those placed on the global production of carbon dioxide, or, more obviously perhaps this technology should be abandoned immediately. In fact it beggars the mind that we have benignly allowed the nuclear industry to get away with its severely polluting technology for so long.

As a physician I see the extraordinary efforts that I and my colleagues pursue to save the lives of our patients suffering from cancer and genetic diseases, let alone the amount of money allocated to find the cure to cancer. Yet here we have an industry that is actively promoting and incurring massive increases in these disastrous diseases, and society has not yet called their bluff. It is beyond time that we did.

Uranium Mining

Uranium mining began in Europe in the late part of the 19th century when Madam Curie was refining pitch blend from uranium ore and discovering the wonders of radiation. Large scale mining commenced 65 years ago specifically to provide fuel for nuclear weapons. Much of the uranium was located on Navajo and Pueblo tribal land. The mining continued unabated for many decades thereafter and large numbers of Native Americans were employed as below-ground and above-ground miners.

People who mine uranium below the ground are at great risk because they are exposed to a high concentration of radioactive gas called radon 220 which accumulates in the air of the mine. Radon is a daughter or decay product of uranium, and is a highly carcinogenic alpha emitter which if inhaled, deposits in the air passages of the lung irradiating cells which then become malignant. As a result, uranium miners have suffered from a very high incidence of lung cancer. One fifth to one half of the uranium miners in North America, many of whom were Native Americans, have died and are continuing to die of lung cancer. Records reveal that uranium miners in other countries including Germany, Namibia and Russia suffer a similar fate.

Another lethal uranium daughter is radium 226, which is an alpha emitter with a half life of 1600 years. This radioactive element is notorious in the medical literature. In the early part of the 20th century women painted numbers on watch dials with radium enriched paint, so that the numbers glowed in the dark with radioactivity. To make the figures precise, they licked the tips of the paint brushes thereby swallowing large amounts of radium. Because radium is a calcium analogue it deposited in their bones. Many of these women subsequently died of osteogenic sarcoma – a highly malignant bone cancer, affecting their facial bones while others succumbed to leukemia, because white blood cells which were mutated are manufactured in the bone marrow. Uranium miners are exposed to a similar risk because radium is an integral component of uranium dust in the mine. When they swallow the dust, radium is absorbed from the gut and deposits in their bones.

Uranium ore also emits gamma radiation which emanates from the ore face, so the miners are also exposed to a constant whole-body radiation exposure (like X-rays) emitted by other uranium daughters, which irradiates their bodies and continuously exposes their testicles.

As the uranium ore is mined, and the uranium is extracted, large quantities of radioactive dirt and soil are discarded and left lying in huge heaps adjacent to the mine exposed to the air and the rain. This material is called tailings. Most tailings in North America are situated on indigenous tribal land of the Navajo nation and the Laguna Pueblo in New Mexico, and on the Serpent River First Nation in Ontario, Canada. Millions of tons of radioactive dirt constantly leak radon 220 into the air exposing the indigenous populations who live nearby in their pueblos and settlements. As they inhale the radon, many of these people have and are developing lung cancer.

Rain also leaches soluble radium 226 through the tailings piles into the underground water which often is the source of drinking water for these people. When radium enters streams and rivers it bio-concentrates thousands of times at each step in the food chain of the aquatic life and terrestrial plants. Because it is tasteless and odourless, people in these contaminated populations cannot tell whether they are drinking radioactive water, breathing radioactive air or eating fish or food containing radium 226 which induces bone cancer or leukemia.

Hundreds of mines and tailings heaps lie exposed to the air and wind on Navajo land. Thousands of Navajos are still affected by uranium induced cancers, and will continue to be so for thousands of years unless remediation takes place. In total 265 million tons of uranium tailings pollute the American South West.


Ecological Racism

There has never been any attempt by the government or the nuclear industry to clean up this massive radioactive pollution which contaminates tribal land. It would be hard to imagine that the nuclear industry would be permitted to leave millions of tons of radioactive tailings lying adjacent to the well-heeled town of New Canaan Connecticut or near the Rockefeller estate in the Adirondacks.

Uranium Milling

The US federal government covers the cost of milling uranium. The ore is crushed and chemically treated at the milling plant in the American South West where it is converted to yellow cake. As in the mining process, the waste ore is discarded on the ground. These mill tailings contain radium and a dangerous radioactive element called thorium – a uranium daughter and a high energy gamma emitter with a half life of 80,000 years. Thorium is used in colour television sets. Over the last 40 years over 100 million tons of mill tailings have accumulated in the American South West

Human cost is again important in the energy discussion. To illustrate the dangers of loose unguarded nuclear material, in the mid 1960s, local contractors at Grand Junction in Colorado discovered acres of discarded mill tailings. Not knowing they were radioactive they used them for cheap landfill and concrete mix. Schools, hospitals, private homes roads, an airport and shopping mall were constructed from this material. In 1970, local pediatricians noticed an increased incidence of cleft lip, palate and other congenital anomalies amongst newborn babies born to parents who lived in these radioactive structures, which continually emitted gamma radiation and radon gas.

The EPA allocated monies to the University of Colorado Medial Center to study the correlation between the birth defects and the radioactive dwellings. However one year into the study, funds were abolished because, the government said, it had to save money for budgetary purposes.

Uranium Enrichment

As described in the second chapter, the uranium 235 isotope is enriched from a low concentration of 0.7% to 3% for fuel in nuclear power plants. If uranium 235 is enriched above a concentration of 50% it can be used as nuclear weapons fuel.

Workers at all stages of the enrichment process are exposed to whole body gamma radiation from daughters in the uranium. But the most serious aspect of enrichment is the material that is discarded, and that is uranium 238. This is called “depleted uranium” (DU) because it has been depleted of its uranium 235. But it is not depleted radioactively.

DU is lying around in hundreds of thousands of leaking disintegrating barrels at the enrichment facilities in Paducah Kentucky, Oak Ridge, Tennessee, and Portsmouth Ohio. At Padacah alone, some 38,000 cylinders of DU await disposal. DU has contaminated the ground water, forcing the government to provide alternative drinking water for the local residents.

But the Pentagon, in its wisdom has found a nifty use for this radioactive waste. Because uranium 238 is 1.7 times more dense than lead it has been found to be the ideal antitank weapon. When shot out of a cannon at great speed its ten pound mass develops great momentum, so the solid uranium antitank shell cuts through the steel on the other fellow’s tank like a hot knife through butter.

But DU has several unfortunate properties. It is pyrophoric which means that it bursts into flame upon impact and up to 80% disintegrates into finely powdered aerosol which is distributed to the four winds. It is radioactive, and it has a half life of 4.5 billion years

Nevertheless, the Pentagon is very keen about this weapon. In the 1991 Gulf war invasion they used 360 tons of it in the form of antitank shells. In the 2002 invasion they already have deployed well over 2000 tons, in cities such as Baghdad where half the population of five million people is children who play in the burned out tanks and on the sandy dusty ground. Children are ten to twenty times more susceptible to the carcinogenic effects of radiation than adults. My pediatric colleagues in Basra where this ordinance was used in 1991 report a seven fold increase in childhood cancer and a seven fold increase in gross congenital abnormalities.

Uranium is a heavy metal. It enters the body via inhalation into the lung or via ingestion into the GI tract. It is excreted by the kidney where, if the dose is high enough, it can induce renal failure. It can induce kidney cancer. As a calcium analogue, it lodges in bones where like plutonium, it causes bone cancer and leukemia. Last but not least it is excreted in the semen where it mutates genes in the sperm. This may be one of the causes of the huge increase in congenital disease reported in Basra.

Because of the infinitely long half-life of uranium 238, the food, the air and the water in the cradle of civilization have been forever contaminated. T

In summary, the two gulf wars have been nuclear wars and people, particularly children are condemned to die of malignancy and congenital disease for ever more.

Other countries involved in uranium enrichment include Britain, China, Russia, Israel, Japan, Germany, Argentina, France, North Korea, Iran, Pakistan, Brazil and India. Any of these countries if they so desired could make nuclear weapons if they decided to enrich their uranium beyond 50%. America set the example and the world follows.

Fuel Fabrication.

After milling, the uranium fuel is made into cylindrical ceramic pellets the size of a cigarette filter and placed in zirconium fuel rods, half and inch thick and twelve to fourteen feet long. Each rod contains at least 250 pellets. About 50,000 of these rods are then packed into the core of a thousand megawatt reactor within a cylindrical space, fourteen feet high and twenty feet in diameter. Fuel fabrication workers are once again exposed to gamma radiation emanating from the uranium as well as to radium radon gas and uranium dust.

It Does Not Take An Accident

Routine Releases

Once the fuel in a nuclear reactor reaches critical mass, the high radiation ambiance causes uranium fuel to swell over time, pinhole breaks appear in the zirconium cladding and some faulty welds rupture in the fuel rods themselves releasing radioactive isotopes into the cooling water. In addition, the radiation emitted through the wall of the fuel rods activates water molecules and impurities in the water itself. For example, neutrons emitted from the fuel rods interact with water molecules to form tritium – a radioactive isotope of hydrogen. The primary coolant - water which cools the reactor core thus becomes intensely radioactive.

This thermally hot primary coolant is piped through a steam generator to heat the secondary cooling system. This secondary water is converted to steam which turns the generators to produce the electricity. The primary coolant is not supposed to mix with the secondary coolant but of course it does, allowing radiation to be released to the environment from this secondary system.

Because of these factors and many more to be described, a nuclear power plant cannot operate without routinely releasing radioactivity into the air and water.

Radioactive gases which leak from fuel rods are routinely released or “vented” into the atmosphere at every nuclear reactor. Before release they are temporarily stored to allow the short lived isotopes to decay and then released to the atmosphere through engineered holes in the reactor roof and from the steam generators. This process is called “venting”. About 100 cubic feet of radioactive gases are also released hourly from the condensers at the reactor. Planned ventings increase in frequency when the reactor shuts down due to mechanical malfunctions. Accidental ventings are not infrequent.

Planned “purges” when radioactive gases are actively flushed into the atmosphere by a fan, are officially permitted by the NRC so that utility operators can decrease the intensely radioactive environment into which maintenance workers must enter. Older reactors are allowed 22 purges per year during routine operation and 2 purges per year during cold shut-down. (Cold shut occurs when the fission reaction is stopped at the reactor and 30 tons of very radioactive fuel is removed and replaced by new fuel).

Some of the more dangerous gases such as iodine 131 are usually trapped by filters, but not always. After the radioactive iodine is filtered, noble gases are routinely released. The nuclear industry argues that noble gases are chemically inert and therefore not capable of reacting biochemically in the body but they actually decay to daughter isotopes which themselves are chemically very reactive.

Noble gases have names that remind me of superman - xenon, argon, krypton. There are many varieties of these elements, some of which I will describe below. They are inhaled into the lung, particularly on a day when a meteorological inversion system causes the plume of radioactive gases to cling to the ground in a concentrated form.

Noble gases are high energy gamma emitters and they are readily absorbed from the lung, and enter the blood stream. Because they are very fat soluble, they tend to locate in the abdominal fat pad and upper thighs, adjacent to the testicles and ovaries. There, they can induce significant mutations in the eggs and sperm of the people living adjacent to a reactor.

There have never been any epidemiological studies performed on the effects of exposure to the noble gases xenon and krypton. This is a grave deficit in the study of radiation biology because these gases are so ubiquitous around nuclear reactors, and are released with irresponsible impunity.

But many noble gases decay to other more dangerous isotopes, all of which have different metabolic pathways in the body. I will describe several of the more dangerous.

Xenon 137 with a half life of 3.9 minutes converts almost immediately to the notoriously dangerous cesium 137 with a half life of 30 years.
Krypton 90 , half life of 33 seconds, decays to rubidium 90, half life of 2.9 minutes, then to the medically toxic strontium 90, half life 28 of years.
Xenon 135 decays to cesium 135 with an incredibly long half life of 3 million years. Large amounts of xenon 133 are released at operating reactors, and although it has a relatively short half life of 5.3 days, it remains radioactive for 106 days.
Krypton 85 which has a half life of 10.4 years is a powerful gamma emitter.
Argon 39 has a 265 year half life.

Other dangerous noble gases include xenon 141, 143 and 144 which decay to cerium 141, 143 and 144. According to the National Council on Radiation protection (NCRP Report No 60) these three cerium isotopes which are beta emitters, are abundant products of nuclear fission reactions and have moderately long half lives. They bio-concentrate in the food chain and they irradiate the lung, liver, skeleton and gastrointestinal tract where they act as potent carcinogens.

A very important and little discussed isotope that is routinely emitted in large quantities into the air and waste water from nuclear power plants is tritium, (H3) a radioactive isotope of hydrogen which is composed of one proton and two neutrons. Tritium has a half life of 12.4 years and as such is radioactive for 248 years. H3 combines readily with oxygen to form tritiated water (H3O).

Because it is impossible to remove tritium gas or tritiated water via filters, it is released continuously from reactors into the air and into lakes, rivers or seas – depending upon the reactor location. At least 1360 curies of tritium are released annually from each reactor.

Tritium gas is an interesting radioactive material which is utilized extensively in exit signs, runway signs at airports and on watch faces. But it is very reactive and tends to chemically bind with any material in which it is enclosed.

Tritiated water in particular is scary material. If one is immersed in a cloud of tritiated water on a foggy day near a reactor it is absorbed straight through the skin. It is also readily absorbed through the lungs and the GI tract.

Because tritium is a soft energy beta emitter, all the radiation it gives off is readily absorbed by the surrounding cells, hence it is biologically very mutagenic.

There is a vast literature on the biological effects of tritium demonstrating that it is highly mutagenic and causes chromosomal breaks and aberrations. In animal experiments it has been shown to induce a five fold increase in ovarian tumours in offspring of exposed parents while also causing testicular atrophy and shrinkage of the ovaries. It causes decreased brain weight in the exposed offspring and mental retardation with an increased incidence of brain tumours in some animals. Increased perinatal mortality was observed in these experiments as well as a high incidence of stunted and deformed foetuses.

These effects were observed with surprisingly low concentrations of tritium, becoming three times more dangerous biologically at very low doses.

Tritium is also more dangerous when it becomes organically bound in molecules of food. As such it is incorporated into molecules including DNA within bodily cells. Chronic exposure to contaminated food causes 10% of the tritium to become organically bound within the body where it has a biological half life of 21 to 550 days - meaning that it can reside in the body from one year to twenty five years.

When tritium is released to the environment it is taken up by plants and trees, partially incorporating into the ecosystem. Trees constantly transpire water vapour into the air it has been found that higher concentrations of tritium occur at night at breathing height in a forest that has incorporated tritium from a nearby reactor.

Let’s look again at the reactor.

The primary coolant water becomes extremely radioactive over time because the fuel rods leak. But to add fuel to the fire, the NRC is now allowing nuclear operators to retain uranium fuel in reactors for six years instead of three, lengthening the “burnup” time and substantially increasing the radiation levels in the fuel. As well the NRC is allowing a concentration of 4.5% uranium enrichment in the fuel instead of the previously approved maximum of 3.5%. This policy will also substantially increase the amount of radioactivity produced in the fuel rods.

The longer the time that the zirconium fuel cladding is exposed to high levels of radiation, and the higher the radiation levels, the greater the damage to the cladding subsequent leakage of radioactive materials into the primary coolant.

Radioactive corrosion or activation products not the result of uranium fission are produced as neutrons bombard the metal piping and the reactor containment. These elements which are powerfully radioactive include cobolt 60, iron 55, nickel 63, radioactive manganese, niobium, zinc and chromium. These materials slough off from the pipes into the primary coolant. Officially called CRUD (Chalk River Unidentified Deposits), this material is so intensely radioactive that it poses a severe hazard to maintenance workers and inspectors in certain areas of the reactor.

According to David Lochbaum, a nuclear engineer at the Union of Concerned Scientists, during shutdowns of reactors, the utilities not uncommonly flush out pipes, heat exchangers etc to remove highly radioactive CRUD build-up. Some of the CRUD is sent to radioactive waste dumps while some is released to the river, lake or sea on which the reactor is located.

The utilities admit that about 12 gallons of intensely radioactive primary coolant leaks daily into the secondary coolant via the steam generator through breaks in the pipes which is then released to the air. Some of these emissions are not even monitored. Likewise about 4,000 gallons of primary coolant water are intentionally released to the environment on a daily basis while some just leaks out unplanned. Many other emissions are simply not monitored.

In summary, radioactive gases, radioactive water, and CRUD particulates are intentionally released in daily batches, some in continuous streams and some during accidents.

Very radioactive primary coolant filters which frequently contain often contain intensely carcinogenic plutonium 238, 239, 241, americium and curium are shipped to nuclear waste facilities. Other dangerous elements in the filters include technetium 99 with a 211,100 year half life, iodine 129 with 15,700,000 year half life, carbon 14 with a 5700 year half life, nickel with a 100.1 year half life, and plutonium 241 with a 14.29 year half life.

Almost certainly these extraordinarily dangerous materials which are present in the primary coolant are escaping also in small quantities via the gaseous or liquid effluents into the environment at the nuclear power plant where they will bio-concentrate in the food chain, there to enter human bodies!

It is instructive to note that most of the data of radiation releases are not real measurements but are only estimates made by computerized mathematical models based on data generated from operational reactors, field and laboratory tests and plant specific design calculations.

Hence the nuclear industry is consistently guessing about its radioactive releases and has no real idea what specific isotopes are escaping from its radioactive mausoleums. They even admit that when their operating data is non existent, information that was confabulated – made up and drawn from laboratory and field tests and from engineering judgement! The reference for this material is dated 1985, the last such document published by the NRC available for the public scrutiny. Also note that this last document was published when reactors were relatively young and plagued with fewer corrosion and maintenance problems.

In other words, all the releases are done in secret, they are at best guesstimates, and the general public is kept in the dark.

Reports indicating gaseous and liquid radioactive releases vary enormously. For instance, the Millstone One reactor in Connecticut alone released a remarkable 2.97 million curies of noble gases in 1975, while Nine Mile Point One released 1.3 million curies in 1975. In 1974, the total release from all reactors in the US was 6.48 million curies while in 1993 it ranged between 96,600 curies to 214,000 curies.

Some years the nuclear industry is collectively releasing millions of curies annually. But remember that the nuclear industry claims it is “emission” free and they are gearing up to build a new generation of nuclear power plants!

Lesson? Do not live near a nuclear power plant, otherwise you will never know what you are breathing, eating and drinking.

Niger's Uranium Rebelllion

David Lewis
17 September 2007 11:59


Before the protest march, leaflets were scattered around town claiming Libyan troops had entered Niger to annex the country’s oil and land while French business people were busy looting the country of its meagre wealth.

And when hundreds of Nigeriens took to the streets of their capital recently, they did more than accuse neighbouring Libya of backing rebels and call for Areva, a French nuclear firm mining uranium in the north of the country, to leave.

They highlighted the complexity of Niger’s latest rebellion, which, though not even officially recognised by the government, has killed some 50 government soldiers, seen dozens more kidnapped and sparked a vast military operation in the north.

Seven months ago, the Niger Movement for Justice (MNJ), a Tuareg led rebel group, emerged from relative obscurity, launching strikes on military and strategic installations in remote corners of Niger’s desert north. Mainly targeting isolated military camps or patrols, the rebels have also attacked fuel depots and foreign mining interests.

In response, the army has sent 4 000 men to the region, where they operate under special powers granted by the president. The region of Agadez is now effectively under martial law as government forces continue their operations and impose strict controls on movements.

Since then, the MNJ has outlined its demands for justice and a fairer distribution of Niger’s modest wealth. But, for some, the complaints have fallen on deaf ears. “It is not about rebellion, but a bunch of bandit mercenaries who are benefiting themselves,” explained Nouhou Arzika, the head of the Citizens Movement, which organised the march.

Arzika believes that the MNJ is just another band of criminals involved in the Sahara’s lucrative trade in weapons, drugs and cigarettes. Areva’s involvement stems from its anger that the Nigerien government recently ended its 35 year monopoly on uranium, while Libya is hoping the rebellion will boost its claims to Niger’s oil, he says.

The government largely agrees, though not publicly in such vociferous terms, but many feel that it may be lending Arzika’s movement a helping hand.

Looking to profit from a resurgence in global interest in nuclear power, Niger has issued 90 exploration licences for uranium mines in the last year and hopes to double production by 2011. Among other issues, claims that some of Niger’s potential oil fields belong to Libya are at the heart of tensions with that country.

But the origins of the latest rebellion lie in previous Tuareg-led rebellions in the region, the first of which was in the 1960s in Mali. Violence broke out again in Mali and in Niger in the early 1990s as Tuaregs, who are divided up between the five countries that share the Sahara, accused their respective governments of marginalising them until peace deals silenced the guns in 1995.

However, while they were then promised development, jobs and a greater say in the running of their part of the country, critics say violence has erupted because the deals were never fully implemented.

“The first rebellion was about reducing the gap between the north and the south,” says Iguelas Weila, president of Timidria, a Nigerien human rights organisation. “Peace deals were signed and people took jobs, but nothing has changed for people on the ground.”

Initially without a clear set of goals, the MNJ has set up a regularly updated website that claims military successes and clarifies its strategies. “Our community has been persecuted. Our people haven’t been able to integrate into society,” complains MNJ political secretary Ahmed Akoli. “This is a situation that is imposed. We have an ideal. It is not just banditism.”

According to the UN, Niger remains the least developed country in the world. The literacy rate is estimated at about only 25% and with a population growing at 3%, there is increasing pressure on food security, even in a good year. Buyers from neighbouring Nigeria will often pay more for food, leading to food shortages. A recent increase of seven US cents in the price of a baguette prompted threats of a boycott of bakeries.

Some say the failure to implement past peace deals was as much a lack of ability as a lack of will and that Niger has been simply too poor to improve the lives of any of its people, not just the Tuaregs.

Now, though, internal politics are also at play. So far the government has pursued a policy of denying that there even is a rebellion; local broadcasters have been banned from holding live debates on the situation and foreign journalists are not allowed to travel to the region.

Analysts say Nigerien President Mamadou Tandja’s refusal to recognise the rebels and begin talks is compounded by the southern-dominated armed forces’ desire for a military solution and politicians’ reluctance to make further compromises.

Source: http://www.mg.co.za/articlePage.aspx?articleid=319475&area=/insight/insight__africa/

Friday, October 12, 2007

DEADLINE: Public Comment- Nuclear Energy Policy (Deadline 17 October 2007)

Public Comment: Nuclear Energy Policy & Strategy for the Republic of South Africa

 

The Department of Minerals and Energy has invited the public to make written submissions on the Nuclear Energy Policy and Strategy.

 

Deadline: 17 October 2007

 

For Attention: The Director-General, Mr T Maqubela

Postal Address:  Private Bag X59, Pretoria, 0001

Or Fax:              012 322 8570

Or Emailkedibone.theko@dme.gov.za

 

The document is available at HERE, HERE or HERE (PDF – Adobe Acrobat Format)

Contact Person:

Mr T Maqubela 012 317 8340

Monday, October 8, 2007

Finally some sense - more African governments need to do this.

DRC says Brinkley uranium venture 'won't progress'

By: Liezel Hill
Published: 8 Oct 07 - 11:53

The government of the Democratic Republic of Congo (DRC) has fuelled undercurrents of concern regarding the security of investments in the country, by announcing on Friday that a “questionable” mining joint venture between UK-based Brinkley Mining and the country’s Atomic Energy Authority (CGEA) “will not be progressing”.

Brinkley said in July this year that it had signed an agreement with the CGEA to form a uranium exploration and development joint-venture company.

However, in a statement released by public relations firm Bell Pottinger, the government said that it had determined that the agreement between Brinkley and the CGEA did not meet “the highest standards of integrity”.

Further, the Commissaire General of the CGEA, Professeur Francois Lubala Toto, who negotiated and promoted the relationship with Brinkley Mining, and scientific director Professeur Leopold Makoko Moyengo, had been dismissed, and were currently the focus of a criminal investigation into the origins and terms of the agreement.

However, in a statement also issued on Friday, Brinkley said that, while it had seen the press statement, it had not received any confirmation from the government of the DRC that the joint venture would be cancelled, and was seeking further clarification from the CGEA.

The DRC is conducting a review of about 60 existing mining contracts, and seeking to determine the validity of mining permits, in an attempt to “clean up” and “stabilise” its mining industry, which had been damaged by years of political instability.

“This [the Brinkley] enquiry has been in progress for some time. Just as my colleagues in the Ministry of Mines are moving to ensure that the mining industry is based on deals that have been fairly and properly transacted, so must we ensure that all nuclear issues are managed according to the law,” said DRC Minister for Science and Higher Education Sylvain Ngabu Chumu.

Source: http://www.miningweekly.co.za/article.php?a_id=118523