China searches for 8 kg of "missing" uranium
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Eight kg (17 lb) of radioactive uranium has gone missing in China, delaying the verdict in a trial of four men charged with attempting to sell it on the black market, state media said on Friday.
A court in Guangzhou, capital of China's southern province of Guangdong, heard the four tried to sell the material between 2005 and January 2007, the China Daily said.
The men were arrested in January after a potential buyer in Hong Kong reported them to the authorities, the paper said.
However, despite having the four men in custody, police were unable to locate the uranium.
"The men claimed it had been lost because it had been moved around so much between potential buyers," the paper said.
A verdict had yet to be reached "as the court said the trial would continue until authorities tracked down" the uranium.
More than 20 people had fallen sick after being exposed to the radioactive material, the Hong Kong-based Information Center for Human Rights and Democracy said, citing an official involved in the investigation.
Court documents identified it as fissile uranium-235, the Center said, adding that it originated in a mine in Hunan province that was open from 1958 to 1985.
Under Chinese law, the illegal trade in uranium carries a sentence of between three and 10 years in prison. In exceptional cases, it can carry the death sentence.
"The radioactive substance uranium does not explode when it is in its raw state, but it is very harmful to people's health," Jiang Chaoqiang, director of the Guangzhou No 12 People's Hospital, told China Daily.
"Therefore it needed to be found as soon as possible."
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Just what sort of bomb would 8kg of Uranium build, you ask? As it turns out, not a very powerful one, when compared with what Hiroshima experienced. The thiefs did steal the U-235 variety of Uranium (as opposed to the stable, unenriched U-238 variety), but I'm not sure what concentration. Not sure what concentration causes radiation sickness (5% or 90%). It is the 5% concentration of U-235 Uranium that is used in power plants. It is the highly enriched 90% concentration U-235 Uranium that is considered weapons grade.
Here is an interesting article from across the pond that discusses how to build a nuke, and further discusses my favorite subject: Iran.
As a side note: The U.S. used gaseous diffusion on uranium hexafluoride in centrifuges during the Manhattan project to enrich uranium. This is an antiquated process that requires physically large production facilities. We now have the capability of using a laser based enrichment process that is much more efficient and requires very little production overhead. For a country to try and establish a weapons grade enrichment facility based on centrifuge technology would require a facility so large that spy satellites could easily identify it.
Issue 123 , June 2006
How to build a bomb
How close is Iran to building a nuclear weapon? And what can the US do to stop it?
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| Other articles in the Prospect online symposium on the Iranian nuclear crisis: Philip Gordon explains why the US is unlikely to bomb Iran Michael Rubin argues that diplomacy is not enough Alastair Crooke says that the west are trampling over Iran's rights Nazenin Ansari suggests that the Iranian state may be susceptible to sanctions Esther Herman on her encounters with everyday Iranians |
Anyone seeking to build a nuclear weapon needs two things: 1) enough fissile material for a critical mass (either 20-25kg of highly enriched uranium, the material used in the Hiroshima A-bomb, or 6-8kg of plutonium, as used in Nagasaki) and 2) a "weaponisation" package for a controlled fission reaction. They will also need a delivery vehicle—typically an aircraft or ballistic missile, but a suicide vessel or truck would do.
In the case of Iran, attention has focused on its uranium enrichment programme. Uranium enrichment involves increasing the concentration of fissile U-235 in uranium. What does this mean? The U-235 isotope makes up 0.7 per cent of naturally occurring uranium. U-235 is an isotope that will split, or fission, when struck by a loose neutron, emitting radiation energy and more neutrons that can split other atoms in a chain reaction. (Isotopes are atoms of a given element with the same chemical make-up and the same number of protons but varying numbers of neutrons. The number after the chemical symbol—U in uranium's case—is the atomic mass, the number of protons and neutrons, and is used to denote different isotopes.) But the bulk of natural uranium is the stable U-238 isotope, which cannot sustain a chain reaction. The point of the process of enrichment is to increase the concentration of U-235.
Uranium is enriched by passing it through a series of centrifuges—1.8cm-high spinning tubes that use centrifugal force to alter the concentration of the different uranium isotopes. Connecting 164 of the centrifuge machines together in a cascade, where the gas is successively enriched in each of several stages, provides a basic module for an enrichment facility. For nuclear fuel for reactors, such as the one Russia is completing at Bushehr, the U-235 content must be enriched to about 3.5 per cent for a controlled nuclear reaction. By contrast, weapons-grade uranium requires enrichment to over 90 per cent. Although that seems to be a far greater leap, once you have reached the 3.5 per cent fuel threshold, half the work is done. To get to weapons-grade, the low-enriched uranium is simply run through the centrifuges more times.
In early April, Iran announced that it had mastered the uranium enrichment process. The International Atomic Energy Agency (IAEA) confirmed that the pilot enrichment plant at Natanz had enriched uranium to the 3.5 per cent level in a connected series of 164 centrifuges. Iran's claimed achievement came twice as fast as analysts had predicted when the enrichment program resumed in January. In an almost reckless hurry, the Iranians had skipped many of the intermediate testing steps. They presumably wanted to establish new "facts on the ground," so that were they persuaded in the future to again suspend the enrichment programme, they would do so at a higher starting point.
Iran might not be as far along as its leaders would like us to believe. Only a small amount of enriched uranium has been produced, and it is possible that Iran's haste will eventually make waste. But we should not underestimate Iran's technical skill. Last year, western intelligence analysts judged that the uranium hexafluoride Iran was producing at Esfahan was overly contaminated with heavy metals. Now experts, including the IAEA, judge it is good enough for Iran's initial purposes. And Iran has already produced 110 tonnes of the feed material—enough, when enriched, for at least 15 nuclear weapons.
Iran originally planned to build five more 164-centrifuge cascade modules at the pilot plant, then to assemble 54,000 centrifuges in larger cascades in the underground fuel production facility at Natanz. Once the Iranians are confident the smaller cascades work, they can enlarge and replicate them at the underground site.
The Iranians could also replicate the centrifuge cascades in a hidden facility. If they seek to enrich uranium to the level and amount needed for a nuclear weapon, they could do so with 3,000 centrifuges operating for at least nine months. Assembling that number of centrifuges and getting them working smoothly would take some time—three years at least, in the estimate of the International Institute for Strategic Studies (IISS), taking into account the time it takes to build and assemble the centrifuges, and to do all the diagnostic, calibration and sustainability testing that Iran skipped over in its race to demonstrate an enrichment capability this spring. Thus, in the IISS's estimation, the earliest Iran could have a nuclear weapon is at the end of the decade: 2010.
Other reputable analysts believe the earliest timeline for obtaining nuclear weapons could be 2009 or even 2008, while the official CIA estimate remains 2010 to 2015 years. These estimates are within the margin of error, because there are so many unknowns about Iran's programme. Even the Iranians do not know how well their domestically produced components will function and what technical problems they will face along the way. Iran's boast, however, that it will have 3,000 centrifuges installed at Natanz by March 2007 gives reason to fear the worst case scenario. Although the cascade will be configured for fuel production and monitored by the IAEA, Iran could reconfigure the facility for weapons-grade enrichment if it broke out of its nuclear non-proliferation treaty (NPT) commitment.
In November 2004, when Iran suspended its enrichment program under the terms of the Paris agreement with Britain, France and Germany, it had 1,345 centrifuges—of which perhaps half are of questionable quality—and components for several thousand more. Iran may need more and better components for its ambitious 54,000-centrifuge fuel production facility. As far as is known, however, it does not need to import anything more for a weapons programme.
Washington insists that it is focused on a diplomatic solution to Iran's nuclear challenge. It had hoped to forestall that programme before Iran acquired the expertise to enrich uranium, but Condoleezza Rice's recent conditional offer to join multilateral talks with Iran shows that the administration remains focused on the diplomatic track. If, however, these efforts do not stop the programme before Iran nears the worst case timeline for acquiring enough highly enriched uranium for a nuclear weapon, the military option is likely to be considered in earnest.
Seymour Hersh's claim in the April New Yorker that American military planners had included a tactical nuclear weapon among the alternatives considered to destroy underground nuclear facilities produced a flurry of comment and debate, mostly disparaging the notion. In addition to the disastrous consequences, weapons experts note that there is no need for a tactical nuclear weapon; the American GBU-28 Paveway III laser-guided penetration bombs—the so-called "bunker-buster"—can pierce 30 metres of soil or six metres of concrete. The fuel production facility at Natanz is buried ten metres underground. The depth of tunnels at Esfahan evident in satellite imagery last year are harder to judge, but most of the Esfahan facilities are above ground. The tunnels are presumably for storage of the uranium hexafluoride and associated machinery in the event of a foreseen attack.
If Iran refuses Washington's conditional offer for talks, the next step in the diplomatic process is for the security council to make suspension mandatory under Chapter VII of the UN charter, on the grounds that Iran's enrichment programme presents a threat to international peace and security. This could then pave the way for a second resolution authorising sanctions if Iran refuses. It has taken the west longer than planned to win agreement for a mandatory resolution, because Russia and China have refused to go along with any steps that could lead to UN sanctions, believing they would only exacerbate Iran's belligerent defiance.
Russia and China may be right. But it is defeatist to conclude that sanctions will not work before they have been tried. Until Iran has to face real costs for pursuing the enrichment programme, why would it stop? The security council could start with a range of political sanctions that would isolate Iran and hurt the pride that plays such a large role in its nuclear motivations. These could be supplemented by economic steps by the EU and other parties to cut off Iran's access to trade credits and foreign investment. Financial measures the US has effectively deployed to restrict North Korea's access to the international banking system are being employed against Iran as well. If incentives are added to the policy mix—especially the security and economic incentives that only the US can employ and which could be discussed in negotiations—Iran will be faced with a clear set of choices.
The combined impact of sanctions and incentives will not take root in time to stop Iran from furthering the enrichment technology. And air strikes cannot stamp out the knowledge in Iranian heads. But there is time to affect Iran's cost-benefit analysis before it employs this technology to make the bomb.
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