Posted on 10/11/2006 2:33:45 AM PDT by TigerLikesRooster
Kong Sung-jin, a S. Korean opposition lawmaker at Intelligence Committee of National Assembly, told on Oct. 11, "We have intelligence that the reason why Russia is the first nation N. Korea gave advance warning of its nuclear test is because Russia gave N. Korea technology for miniaturizing nukes. They are trying to verify the allegation."
Legislator Kong appeared on 'Open World Today with Chang Sung-min,' a news talk show of Pyong-hwa Radio, and commented, "Russia and China were the first to know N. Korea's nuclear test. Even though it is not verified, we heard that N. Korea notified Russia two hours before the test."
He maintained, "I am sure that N. Korea want to keep equal distance from both countries, but it may also reflect N. Korea's deep dissatisfaction with China, due to its recent pressure on N. Korea."
"China got notified 20 minutes before the test, and notified S. Korea, U.S., and Japan in this order. That is why S. Korea got informed at 10:50 am (Oct. 9.) Since neither of U.S., Japan, and China had not detected underground nuclear test (in advance,) it is not fair that our intelligence gathering ability is at fault."
Seoul = Yonhap News
2006.10.11
You only get that if there is venting. Direct radiation emission would not penetrate all the intervening rock.
Why is everyone aplauding that this was only a small nuke - 3 of those in 3 cities can really F things up - much worse than hijacked planes.
I think you are right. Ordinary troops are not dependable and combat-ready. N. Korean military is essentially reduced to big terrorist organization. 100K~200K elite troops who can mount horrific terrorist operation(sabotage, hostage taking of entire city(e.g., Seoul), and WMD attacks.)
They cannot win a sustained conventional war.
Gamma bursts can however. I remember it being referenced in a paper released about our surveillance of some Russian tests. I am not trying to say that it is certain that they did not set off an unsuccessful Nuke, but the odds are against Russia giving them any type of advanced technology.
LLS
What is the Worst Case for Cavity Decoupling?
AU: * Leith, W
EM: wleith@usgs.gov
AF: U.S. Geological Survey, 951 National Center, Reston, VA 20192 United States
AB: A central issue for nuclear monitoring is the possibility that a nuclear test could be conducted while evading identification by international and national monitoring systems. Of several proposed evasion scenarios, decoupling an explosion in a large, deep, underground cavity has received considerable attention. While improvements in monitoring networks and technologies have decreased the event detection threshold in many regions, achievements in underground construction have also increased the feasibility of constructing large caverns that could conceivably be used for nuclear explosion decoupling. The yield range of greatest uncertainty lies between 1 and 10 kt, where underground explosions could be decoupled in salt and perhaps in hard rock. Assuming that full decoupling can be achieved in elongated cavities of moderate aspect ratio (up to 10:1), I have reviewed the literature on large-cavern construction in hard rock and salt (including cost), and the containment of nuclear explosions in these media, with the goal of defining the worst case for cavity decoupling. In thick salt deposits and domes, it is feasible to construct stable cavities of sufficient volume for full decoupling of nuclear tests larger than 10 kt. Salt probably provides an ideal environment for both cavity construction and containment, and it is possible that the cavity would not leak radioactivity for years. However, at 10 kt, the resulting seismic event would be detected and probably identified by regional monitoring networks. Suitable salt deposits are relatively rare and are not present in many countries of nuclear proliferation concern. Salt regions can usually be identified in the literature and by remote sensing, and could conceivably be monitored. In hard rock, construction of cavities of sufficient volume for full decoupling is limited to at most about 10 kt, mainly because of the difficulty in constructing a cavern of sufficient size at depths required for containment, and the possibility of detection. Avoiding identification of a decoupled test in the 1-10 kt range would require: careful site selection; plausible denial (e.g., a mining activity), adequate depth, high-quality rock with low gas content; concealment of the mining operation from public knowledge and remote monitoring systems; attention to containment issues (geologic faults and engineered openings to the cavity); and favorable weather conditions, given the likelihood that radioactivity from the test would eventually seep. As the decoupled yield approaches 10 kt, more elongate cavities (up to 10:1) are required in hard rock. Because suitable thick salt deposits are present in many naturally-seismic regions of proliferation concern, these areas will require special attention to ensure adequate monitoring. For yields less than ~1 kt, construction of the required cavity is not limited by the available mining technology, based on many examples of construction at depth, worldwide. With attention to selection of geologic environment, adequate depth, and stemming of the tunnel complex, the evader could be confident that the test would not promptly vent, limiting detectability by the radionuclide monitoring network. The decoupled test would not be seismically identified for broad areas of most countries. Important technical issues for decoupling in hard rock could be addressed by field experiments using conventional explosives. It is significant that evading identification of a cavity-decoupled nuclear test is not limited so much by geology and engineering technology as it is by the capabilities of regional seismic and other monitoring systems. These findings are inconsistent with the recent joint SSA/AGU statement on the verification of the CTBT.
UR: http://geology.er.usgs.gov/eespteam/EESPT_PUB.html
DE: 1734 Seismology
DE: 7219 Nuclear explosion seismology
SC: S
MN: 2001 Spring Meeting
I did do demolition, BTW, but not with nukes. ;-)
As for width of the tunnel, it is quite possible that the diagram could be misleading. I doubt that the diagram would accurately reflect height:width ratio.
Back in WWII the British recruited academics as intelligence analysts. I recollect reading about a noteworthy analyst who was a college professor of Classics.
I think that intelligence analysis is more a matter of innate aptitude than formal education. Some people are good at it.
Gammas have a hard time making up through mountains.
Several stories are now saying radiation *has* been detected.
Certain kinds of Operational Intelligence, this is true. But for Technical Intelligence you need a good solid technical background, and that same sort of questioning mindset.
The "Red Team" often does things somewhat differently than the blue team. There is usually more than one way to skin a cat, and the Soviets tended to make different design trade offs than US defense contractors and their government program managers.
Hence to defend russian business, Russian defense minister just compels NK offocials now that the warheads on sold newest ICBMs are nuclier indeed..."
I believe you're correct, RusIvan! In America, it's called a 'Flim-Flam' game.
Good catch on your part, and your Russian insight is valuable. Thank you................FRegards
The latest is that the radiation was from the core of a failed detonation. We may never know, but as Bush has said, we will proceed as if it was sucessful because the threat is the same.
BTW, Gamma bursts can penetrate through the earth's core if strong enough.
LLS
>>been a crude attempt at concealment.
Or obfuscation of failure.
What does Mr. seismograph say about the similarity of this event and previous Nork warblings?
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