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Pakistan’s nuclear and missile assets -- myth vs reality

KHWARZIMIC SCIENCE SOCIETY
A SCIENCE ODYSSEY:
PAKISTAN’S NUCLEAR EMERGENCE
Speech delivered by Dr. Samar Mubarakmand
On Monday, November 30 1998

The Vice Chancellor Punjab University, President Khwarzimic Society, members of the audience, office bearers of the Interact Club.

I feel honoured to be able to come and address this audience on a topic, which has become quite popular, it seems to me, especially in Lahore. The President of the Khwarzimic Science Society has just said that he was not very happy initially with the nuclear weapons programme and the detonation of the nuclear weapon because it can hold hostage several generations of Pakistan. Let me say that this is a moral issue. Anything we do for the defence of the country is a matter of pride, it is not a matter of shame.

Weapons are developed so that they are not used. So that they will establish a fair and honourable deterrent, in the sub-continent with your neighbours. We have not forgotten the discourse from across the border. We have not forgotten the belligerence we heard in the fifteen days between the Indian and the Pakistani tests. I am very sure, had we not detonated the weapons, this belligerence, this aggression would have increased. Who knows they would have pursued some misadventures into Azad Kashmir, into our province of Sind and even across our borders of Punjab. The nuclear detonation has established a deterrent beyond all doubt. Now let me address myself to the topic of today.


Yes, it was on odyssey – the nuclear programme of Pakistan. At the time of partition of India, there were hardly any scientists or engineers in our country who would undertake this programme. There were hardly any establishments or institutions where research in sciences, such as chemistry and physics were being undertaken. Therefore these institutions had to be developed by some pioneers.


One of the pioneers of science, physics and I would say, the true father of the Pakistani nuclear programme was Dr. Rafi Muhammad Chaudhary. He migrated to Pakistan from Aligarh University and established the Physics Department at the Government College Lahore and was also the pioneer setting up the High-Tension Laboratories. There an atomic accelerator was set up and real high level research was possible. One of his early students was Dr. Tahir Hussain who was my teacher and of course, the present Chairman of the PAEC was one of his early students. Similarly the tradition of physics was set up in the Physics Department of the Punjab University. We know the name of Dr. Majeed Mian, Dr. Baseer Pal and some others. The two departments in the GC and the Punjab University had a very healthy competition. This produced a team of physicists that is now leading Pakistan’s nuclear programme.


In 1955, the Atomic Energy Commission (PAEC) was established and its first chairman was Dr. Nazir Ahmed. He had a small office in Karachi Sadr at the top of the post office and the labs were in the West Wharf. The labs were mostly concentrating in fundamental research in high-energy physics and there were less than ten people working there. It was in the early years of the PAEC to train and recruit manpower to initiate Pakistan’s nuclear
programme.


In 1961, PAEC set up a Mineral Centre at Lahore on the campus close by and a similar multidisciplinary Centre was set up in Dhakka. So with these two centres the research work started.


The first thing that was to be undertaken was the search for Uranium. This continued for about 3 years from 1960 to 1963. Uranium deposits were discovered in the Dera Ghazi Khan district and the first-ever national award was given to PAEC’s Mr. K. Aslam who was a geologist who discovered Uranium. Mining of Uranium began in the same year.


The next landmark was the establishment of the PINSTECH – Pakistan Institute of Nuclear Science and Technology at Nilore near Islamabad. The principal facility there was a 5 MW research reactor. Now with the establishment of the PINSTECH, The Lahore Centre and with the manpower we set abroad for their Ph.D.’s in the early 60’s started coming back and the research programme started gaining momentum.


At this time, our chairman Dr. Usmani was a man of great vision and he envisaged that the atomic programme had to split up into 2 branches: one was the peaceful usage of atomic energy. Under this area we set up the agricultural research centres in Tando Jam and nuclear medicine centres in different parts of the country. We also concentrated on the application of radioisotopes to industry and started training industrialists in the peaceful usage of radioisotopes. Of course nobody in the world would expect PAEC just to do research in agriculture and medicine and industry and therefore we had to think about the nuclear weapons programme in parallel with the peaceful programme.


1971 marked the establishment of the KANNUP, which was commissioned the same year and connected to the national grid. In 1972, the scientists of the country were collected in Multan by the then Prime Minister, Zulfiqar Ali Bhutto and a conference was called and at the Multan Conference we really swore to make nuclear weapons and Mr. Munir Ahmad Khan was made chairman of PAEC.


How would we set about this job. The first thing to do was to refine the uranium we had discovered. The discovery of uranium and its refinement is a massive, manpower-intensive job. 10,000 tons of uranium ore has to be recovered and dug up from the ground to produce enriched uranium for one bomb. So you can imagine the effort that goes into the huge refinement process.

The refinement plant was established in a series of smaller plants. The Chemical Production/Plant Complex (CPC) was established in Dera Ghazi Khan and it looks more or less like the chemical complex at Kala Shah Kaku.

From the CPC we get 2 products:


1. One is uranium dioxide which is a metallic powder and which is the input to the Karachi KANNUP reactor. We all know that after the Indian explosion in 1974, the Canadians stopped the supply of fuel for the research reactor. The Canadians said that the streets of Karachi would go dark. We took this as a challenge and we thought that we must be able to make our own reactor fuel. So from the CPC near DG Khan, came uranium dioxide to make fuel for the Karachi reactor.


2. We also started making uranium hexaflouride, which came from the same campus. So the CPC was branching down into 2 products. You are sending uranium dioxide to the Karachi reactor. This is a peaceful use of uranium, a part of the nuclear fuel cycle and we are also making uranium hexaflouride from the same chemical facility, which is the input material for the enrichment plant at Kahuta.


So in the early days of about 1976, the establishment of the infrastructure for nuclear technology had begun and this was an effort that was started in parallel at different facilities.


One facility was the establishment of the enrichment plant at Kahuta which of course was the responsibility of the PAEC and this was started by some scientist from the PAEC.


The second step was to set up by PAEC was the Uranium Metals laboratory UML, so that ultimately when we get enriched uranium hexaflouride from the plant at Kahuta, we convert it back to metal and give it the right shape to be used in a bomb.


Then the 3 rd facility that was to be set up by PAEC was the design of the bomb. The critical thrust was to set up a theoretical physics group that could work on the design of the bomb. At that time, the responsibility was entrusted to Dr. Riazzuddin, who was in the Physics Department of the Quaid-e-Azam University and then in Dharan (SA). He was a Member (Technical) of the PAEC in those days and was a theoretical physicist and he set up the group. Dr. Masud who is with us today, was a student of Dr. Riazzuddin and now Dr. Masud heads the team that is the design team. I will come to the capabilities of this group, but I must say that our design was a pure indigenous process.

Nobody in the world would come and help you to design nuclear weapons, or to fabricate them or even test them. It has to be a purely Pakistani effort and our scientists on the theoretical side were so capable, they studied the literature that was available and they worked so hard, developed computer codes, acquired powerful computers to design this system and came up with the design that was to be manufactured.


The 4th facility that was set up in those days was a manufacturing facility for the bomb.

So at the PAEC, the finest experimental physicists, engineers and electronics people, chemical engineers formed a team to manufacture these weapons.


We had to develop our own explosive plants. The explosive used in a nuclear bomb is a very special type of explosive. It is not to be purchased from anywhere in the world, nobody would sell it to you. So we had to put up our own plant for this and we had to have chemical engineers that would operate this plant and make the explosives. Then the explosive had to be given the right shape according to the design that was delivered by our design team. The explosive had to be machined. The machining of the explosive is an awesome task. You know explosives are so difficult materials to handle. Its machining is a very dangerous process. We have a dedicated team of people, mechanical engineers who were not afraid of this and who did this job, which of course is done by remote control. These pioneers in PAEC risk their lives to machine the explosives.


So when a bomb is made, it has to be detonated and the detonation is not from one point.

It is from several points on the surface of the bomb and the trick lies in this that you should be able to detonate the bomb from several points at the same time. This is called simultaneity and the simultaneity has to be of the order of 50 ns (nanosecond). A ns is 1/1000 of a micro second us and I repeat 1 us is one-millionth of a second. So you can imagine, in 50 ns, you have to detonate the bomb at several points so that the implosion takes place in a simultaneous fashion.


This was a challenge for our electronics experts at PAEC because they had to develop the trigger mechanism. I mention this because I want to tell you the dimension of the problem and of course the whole journey to the end, and this is a part of the journey.


Then there was the question that you have made the bomb, you put the electronics in it, the bomb has got explosives, it has metallic uranium which comes from Dr. Khalil Qureshi, out top metallurgist at PAEC and he converts the enriched uranium hexaflouride gas from Kahuta into metal and then he does the coating and machining. So that is one part.


Then you have to have a holding system that holds everything, the bits and pieces in such a way that we get a very rugged device. The device has to be rugged so that if you want to have deliverable weapons, you do not have problems. You can put them on aircraft or missile.


All these things had to be started at the same time in parallel.


Suppose you had a bomb, what to do with it. You have to have a facility, a site where you can test the bomb and you would also like that when the bomb is detonated, you can do the diagnostics or the measurement on it. There can be 2 approaches; either to detonate a bomb and sit back and clap or to treat it as a scientific experiment – try to get the maximum scientific data from the nuclear detonation. We chose to do the latter and for that we had established another Directorate in the PAEC – the Diagnostics Directorate.


They are really smart people. They are trained very thoroughly in capturing the yield of the device. They measure the number of neutrons produced in the device, the efficiency of the nuclear bomb: how much uranium produces how much power – this is the efficiency. One must remember that the phenomenon is a single shot phenomenon. It is a very fast process. You press the button and everything is finished within a us. The bomb goes to maximum power, stays there for some time and comes down to zero power in less than a nano second. So in this time, one must do all the measurements and if you miss the data, it is the end of it, it is finished and would not repeat. So it is a single shot event and our Diagnostics Directorate has the capability of measuring what is the yield of the device. They cannot only measure the yield of the devices that they themselves detonate but also of the devices that are exploded across our border.


The diagnostic people are not only responsible for diagnostics of the device but also for detonating the device. The detonation of a device is not done by sitting close to it. It is a very sophisticated process. This expertise was established over the years by a dedicated team of people and when we did the experiments, the detonation at Chaghi, we were able to detonate the first 5 devices from a distance of about 15 km and the last detonation on the 30th , we were able to do from a distance of 45 km.


This was not the first time we were doing these experiments. We had performed so many cold tests before. We had practiced the remote control detonations of the cold test over the years. So we knew what we were doing. We were very professional and very well trained. We had a team of 300-400 people who were responsible for developing the detonation procedure. So this was a massive programme.


This is in short, what I want to say. There are 5-6 different disciplines that have to be dealt with. Each discipline in itself contains electrical and mechanical engineers, electronics people, experimental and theoretical physicists, chemical engineers, metallurgists and so on.


This entire infrastructure came into being by 1980. By 1976, PAEC selected the sites in Chaghi and Kharan and our geologists went to work on these sites. In Kharan there is a desert and we went for a vertical shaft. It is like a vertical well that is 300-400 feet deep and at the bottom of the well you have a horizontal tunnel which is 700 feet long. You do the detonation at the end of this tunnel. So this was an L-shaped configuration. In Chaghi, where we had the mountain range, the Ras-Koh range, we went for an underground horizontal tunnel. The overburden available was about 400 feet. That was the height of the mountain available for containment.


The designing of the tunnels is also a very intricate thing. It is not just blasting a hole into a mountain. Again there is a lot of science. I shall tell you why. If you have a straight tunnel and you put the bomb at the end of the tunnel, you plug the tunnel with concrete and explode the bomb, the concrete is really going to blow out and so all the radioactivity is going to leak out through the mouth of the tunnel. We did not want this to happen. The tunnel is not designed safe but is designed in the form a double-S shape and when we detonate the bomb, the pressures are very great. They move the mountain outward and you use the force of the bomb to seal the tunnel. When the rock expands under the explosion, the rock moves in the direction so that it seals the tunnel. So the tunnel collapses inward by the force of the tunnel. This is how you seal the tunnel through the force of the bomb. Dr. Mansoor Beg is an expert in this. Apart from the manufacturing things, he is the one who does all the calculations and gives it to the geologists who do this work. So in 1976, we selected the sites for the atomic tests. In 1980-81, both the sites were complete and the shafts were all made.


Why were doing all this so keenly in a parallel effort in 1975 and 76? The PAEC was told that whenever you were ready, you would detonate the bomb. So we were all very enthusiastic. We were running day and night concentrating on our effort. But history has proved, it did not happen at that time. The mandate was withdrawn from us when we were ready.


By the end of 1980, the Kahuta plant was completed and Dr A Q khan was made incharge of the plant. First he was working as a scientist within the plant and later on he became the incharge. The plant was commissioned in 1980 and it started to function, first at a slow pace and then gradually picked up speed. All the uranium hexaflouride gas it needed was provided by the PAEC from the CPC at DG Khan. It is still done the same way. After enrichment, the uranium hexaflouride is sent to the UML where it is converted into metal and bombs are being manufactured.

In March 1983, we crossed a milestone. The first nuclear bomb had been manufactured. In March 1983 we went for a cold test. We were very apprehensive. It was the first biggest event in our lifetime and it was conducted. A cold test is the actual detonation of a complete nuclear bomb except instead of enriched uranium, in the middle of the bomb, you put natural uranium. So it will not go into fission. It will not acquire full power, but it is a complete bomb in all respects. What does it do? It produces a high flux of neutrons when the detonation takes place and one has to have the capability of measuring these neutrons.

The Diagnostics Department of PAEC had this capability and they measured neutrons from these cold tests very successfully. When we saw these neutrons on our recorders we were very happy. We thought that we had achieved the objective of our lifetime. I remember that the people were very happy for several days. If you have a cold test and you detect neutrons you can be more than 100 % sure that if you put enriched uranium in the same bomb, it is bound to give you fission. So the test was successful and we were very happy.


Now we had a choice. What would we do next? Where do we go from here. Do we stop, should we go for a hot test, a proper hot test like we had in May this year and when we had positive results from that, we would carry out further work. That was one way of doing it. The second choice was that since our cold tests were successful, so we believe our theoretical physicists. Okay, your design is fine and we go ahead and we develop more modern designs, which are smaller and more rugged and which are being capable of delivery by aircraft and missile.

For every country in the world, which produces this bomb, the first one is very large and very unwieldy and not suitable for deliverable weapons. So the miniaturization or the quantisation of the weapon, should we do it now or wait for a hot test? We went to the Government and said we are ready and we want to do a hot test. The then President said no, it is not the right time and so we had to abide by that decision.


We decided to keep on working on better and better designs and since 1983, over the last 15 years, I must really confess and congratulate the theoretical physicists at PAEC, lead by Dr. Masud, in that they designed one sample after the other. After every 18 months or 2 years or so, we would have a new design and would perform a cold test on that. The success rate in every cold test was 100 percent. Sometimes we started thinking that our diagnostic people are giving us positive results all the time. At least we should fail some time.

Maybe our electronics are faulty and giving us detected neutrons. Probably they are spurious counts but the success was so consistent that we started disbelieving our diagnostic people. Anyway, one design after the other kept coming out, we manufactured the bombs, tested them and were successful.


We came through a series of 4 or 5 designs and then we came up with a model, which we would say, and our generation of people in the PAEC would claim that is the state-of-the-art.


The real last word in nuclear fission design and here of course, the concept was different from earlier designs. It was very small, compact, high yield and small size. So you could see the efficiency was tremendous and we were all very proud of it. When the cold test was successful on it, we were all very happy and this was the last thing we did in the earlier part of the 1990’s.



Now, I think that the rest is all history and very recent history. It is all the memory of the people. Now we had all these designs available with us. I would not tell you what we were doing beyond that. Then you also have to weaponize so that they become deliverable weapons. I would not also tell you what we did about that but you can draw your own conclusions.


We had spent our lifetimes on the project and still there was no chance of a hot test. And on the morning of the 11th of May, this year, one of our friends, in the Armed Services, phoned me and he said, "Have you heard the news today?" I said. "What?" He said, "The Indians have conducted the explosion in Pokhran." So I said, "Congratulations." I was genuinely happy. He said, "You are congratulating us on the Indian tests?" I said, "Yes, because now we would get a chance to do our own tests."


It is always happening like that. Indians are always trying to do things first and we follow suit. Although as scientists, we would have liked that the Government had allowed us to do the tests in the normal way. Anyway, these were political decisions.


When the Indians conducted the tests on the 11th May, within 2 days, they conducted another test. They claim that they conducted 5 tests in all: Three on the 11th and two on the 13 th. Several people have queried on this. We have thought about what were those tests. The claims were that they conducted 5 tests. We have our capability of detecting nuclear tests, measuring their yields and so on. They claimed that of the 3 tests on the first day, one was a fission device, one was a fusion device and the third was a low-yield device. We have detected only one explosion on that day and the yield of that explosion according to our measurement, and you know we are the ones whose measurements are the most reliable, and the yield was the same as the 1974 Pokhran test. So I think the first test was a repeat of the 1974 test and the yield was the same. We did not detect a thermonuclear or a smaller test. We can detect smaller, sub-kiloton tests, which are of the order of 0.5 – 1.0 kiloton but we could not detect that. So our estimates were such that they had conducted only one test on that day. Later on, when international data started coming in from all overthe world, it was also said that on the 11 th of May they had conducted only one test. Of course, the yield they presented had a greater error in it. They would give a wide range of yield. They said it could be between 10-25 kiloton or 10-40 kiloton. This is because the further the station is, the greater the error margin. On the 13th of May, they said they conducted 2 tests but we did not detect any tests at all and our capability, as I have said, is between 0.5 and 1.0 kiloton sensitivity levels.


After these Indian tests, as we expected very quickly, the Prime Minister was at it. He called me and said, "Are you ready for it?" I said, "Yes, definitely." He said, "OK! Get yourselves ready." I told my colleagues that we have to be ready and we started packing.

There we went on the 20th of May and we conducted the first 5 tests on the 28 th of May.

One test was a huge explosion, a large device. The others were sub-kiloton tests. On the 30th of May, we had an L-shaped shaft in the Kharan desert and it was tested on the latest of our models. In all, we conducted 6 tests and the results are that the results were successful to the hilt, to the last detail. The yield was always as predicted by our theoretical physicists.


I can assure you that if you give them the specifications, we want this much yield; this much size and they would be out with 2 months and Dr. Beg would be out with an actual bomb. This capability is now with us and it is a tribute to thousands of our scientists, engineers, geologists, metallurgists and theoretical physicists who have really spent more than 2 decades in this programme and it is also a tribute to the vital link in the chain at KRL, who are successfully doing the enrichment of uranium.


Very smoothly, this process is going on and we got so much data from the 6 tests, it gives us so much confidence in our design capability that as I have said, we can design any specification weapon we want.


Maybe we acquired this capability from some other country. Somebody came to us and gave us some knowledge or transferred us some technology. I can swear to you that nobody in the world, no matter how friendly he is to Pakistan has ever helped Pakistan.

This I can say on oath. This is an indigenous technology and this should be really hammered in because this gives you pride. You have done it. Pakistan has done it. It is not borrowed technology. You know we are a generation of scientists that has lived under embargoes. Right from the mid-70’s, since India exploded the bomb, embargoes were also levied on Pakistan. I sometimes tell my colleagues that we are an embargoed nation.

We have learned to live under embargoes. No one would give us literature, hardware, components, technology. For everything we have to struggle. We had worked under these adverse circumstances and inspite of this adversity, my colleagues took it up as a challenge. OK, you cannot do it for us, we shall show you how to do it. The Pakistani nation works best when it is handicapped. When you are facing a challenge, you show your best. I firmly believe that the young people of this nation are capable of reaching the skies.


The last thing I want to say is that the PAEC has proved that this country is an island of excellence and to substantiate my statement let me say that if you take the statistics of Pakistan and compare it would the rest of the world, they are dismal. Our life expectancy is 122nd in the world; in the literacy rate we are the 162nd and in per capita income we are the 122nd . The access to health services gives us a ranking of 148 and in clean drinking water we are 114th in the world. In the OHD, we are 139th in the world, almost the last and of course and in nuclear weapons we are the 7 th in the world. The PAEC works with a certain tradition of excellence. What is this tradition?


One is tremendous team spirit. Nobody works in our organization for money or fame. We do not believe that sensitive work can be done by publicizing it. It should be done quietly and so there is no lust for fame in this organization. There is honesty, dedication. The work is dangerous: we are working with explosives, atom bombs and we are rubbing our shoulders with nuclear weapons. Who can pay you to do this? Who can pay people to work in explosive plants and do explosive machining? Only the people who are dedicated, who put into their head that we are going to make Pakistan a nuclear state, they are able to do it. Only a purpose, motivation and a high philosophy in life could do this.


When a large number of people work together for a large period of time intelligently, they achieve an objective. If one person works hard for a long period of time, he will only achieve a small objective. In our organization, the PAEC, there are 15-20 Directorates, each dedicated to part of the nuclear weapons programme. Each Directorate has 700-800 people and their work is over 25 years, consistent, without greed, publicity and without quarreling with each other.


I can tell you this, the miracle of teamwork I saw in Chaghi. We were there for about 10 days. The PM had told me, "Dr. Sahib, please do not fail, we cannot afford to fail. IF WE FAIL WE CANNOT SURVIVE. This is an hour of crisis for Pakistan."


He was dead sure that if we failed, they would have attacked our nuclear facilities immediately and we could not afford to fail. There was a tremendous burden of responsibility when he said that to me. I came back to my team and said, "This is a responsibility. Let us all share it. You are a team and nobody let me down."


They worked as a team. There were technical difficulties during these 10 days. We took collective decisions and solved the problems. This is not a miracle. This is something you achieve after you work for a lifetime. So team spirit was very much there. There was so much responsibility on the shoulders of a few. One would expect us to become tense, abusive, quarreling with each other and bad-tempered, but you would be surprised to find us there all smiling and in good spirits, cheered up and relaxed.


We all believed that we had worked very hard and God will give us success and success He gave us.
 
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You're welcome.

Its an open secret that the first Pakistani nuclear detonation of around five devices was substandard, half baked, due to the incompetance of Khan and his team of weapons designers in measuring the yield of the devices-virtually identical to NK's 2006 detonation. Two or more of the devices were detonated at the same time to give the impression of a full yield.

EDITED: Assad, this will lead to a digression from the thread topic. Hope you understand.

pakistan's tests are just as controversial as india's. even the so called "thermonuclear" tests gave a measly yield of only 40kT, and this is the indian claim. no thermonuclear weapon to date has given a yield this low.
even the first soviet thermonuclear test Joe 4, only gave off a yield of 400kT. Joe 4's yield was 15% to 20% fusion

Like I mentioned before, pakistan's sixth test was a plutonium device. Samar Mubarakmand said the last device is our most advanced and compact which we use on all our delivery systems. cruise missiles need a miniaturised warhead which has to be made from plutonium.

i'd also like to thank agnostic for showing me just how credible that Stuart Slade guy is. i knew instantly that i was dealing with a bharat-rakshak article here.

The H-bomb issue is crucial
Questions have arisen about the authenticity of the Indian nuclear establishment's claim that a true hydrogen bomb was exploded as part of the Pokhran-II series of tests on May 11.

BUDDHI KOTA SUBBA RAO


THE success claimed in India's first hydrogen bomb test is suspect. The H-bomb success is crucial to afford India a larger role in global power play. The technical debate over the claim of Indian nuclear scientists and seismologists on India's first thermonuclear device (H-bomb) has raised questions about whether it was a deliberately made false claim or a claim made without understanding why it failed.

Immediately after the three nuclear explosions at 3-45 p.m. on May 11 at Pokhran, Prime Minister A.B. Vajpayee announced that "the tests were conducted with a fission device, a low-yield device and a thermonuclear device. The measured yields are in line with expected values." The words "expected values" are significant. The yield values of the three nuclear devices were withheld from the nation for reasons unknown. In common parlance, a fission device is a fission bomb which is also called an atom bomb; a low-yield device is a device which gives firepower equal to conventional chemical high explosives; and a thermonuclear device is a hydrogen bomb, technically known as a fusion bomb. A hydrogen bomb has vast destructive power compared with an atom bomb. What are the differences between a fission bomb and a fusion bomb and what are their basic working principles?

A FISSION bomb is made by fissioning or splitting the atom whereas a hydrogen bomb is made by fusing atoms. A fission bomb before ignition consists of a mass of fissile material (Uranium-235 or Plutonium-239) and surrounding tamper (Beryllium oxide or other reflector of neutrons). The surrounding tamper is intended ultimately to improve the neutron multiplication factor, denoted usually as 'k'.

Much of the ingenuity in a fission bomb lies in correctly calculating the value of the multiplication factor 'k'. The fissile material and the surrounding tamper material are first placed in a geometric form which allows leakage of neutrons and results in 'k' being less than one in numerical value. These materials are suddenly assembled by chemical high explosives or by other means into a more compact and less leaking geometry where 'k' substantially exceeds the numerical value of one. At the same time, the neutrons from spontaneous fission start an explosive divergent chain reaction. The rate of energy release grows exponentially to result in a fission bomb. The rate of reaction tapers off with the depletion of the fissile material.

At the Shakti-1 test site at Pokhran on May 20. The nuclear establishment's claims in respect of the yield value from the detonations on May 11 have raised questions about the nature of the device tested.

In a highly efficient fission device, a total mass of one kilogram of heavy nuclei (Uranium-235 or Plutonium-239) undergoes fission for each 17 kilotons of energy release. But in a less efficient device, 'k' is reduced below unity, primarily through the explosive disassembly of the compact geometry.

The hydrogen bomb uses the nuclear properties of deuterium and tritium (the two isotopes of hydrogen) to set up an uncontrolled, self-sustaining, thermonuclear fusion reaction, as opposed to the fission bomb in which uranium or plutonium is the principal explosive. The hydrogen bomb is thus a fusion bomb that fuses hydrogen to become helium. In a fusion reaction, the collision of two energy-rich nuclei results in a natural rearrangement of their protons and neutrons to produce two or more reaction products, together with a release of energy of an amount E given by Albert Einstein's formula E = mc2 (mass is denoted by 'm' and velocity of light by 'c'). For a hydrogen bomb reaction to become self-sustaining, a so-called critical temperature of very high magnitude (about 35 million degrees Kelvin; zero degree Kelvin is equal to minus 273 degrees Celsius must be attained; the explosion of a fission bomb generates temperatures of that magnitude.

Thus a hydrogen bomb (fusion bomb) needs a fission bomb (atom bomb) as a trigger. Once the high temperature is achieved with the help of a fission trigger, the energy release in the initial fusion reactions maintains the temperature, and the chain proceeds either until the supply of fusionable material is exhausted, or until sufficient expansion has taken place that the fusion material is cooled below the critical temperature to stop the thermonuclear fusion.

ON what basis have doubts been raised on the claimed success of India's first thermonuclear device detonated on May 11, 1998? It is on the basis of the yield value from the detonation.

The power and the consequent success of a nuclear explosion is measured from the yield which results from the explosion. The yield or total energy of a thermonuclear device, is expressed in megatons (one megaton is 1,000 kilotons and one kiloton is 1,000 tons of equivalent chemical high explosive). Submarine-launched Polaris missile warheads have a yield of about one megaton. The first publicised thermonuclear test was in the United States in 1951 and it was more like boosted fission.

The term 'boosted fission' is used because the core of a small atom bomb (fission bomb) is filled with hydrogen fuel and when the atom bomb is detonated the radiation from the exploding atom bomb is focussed for a split second on to the hydrogen fuel. The hydrogen fuel then fuses to cause a fusion reaction to raise the power of an atom bomb by as much as 10 times its original value of yield; a true hydrogen bomb, on the other hand, may be hundreds or even thousands of times as strong.

Stanislaw Ulam and Edward Teller were the fathers of the hydrogen bomb developed in the U.S. The first true hydrogen bomb detonated by the U.S. in 1952 was about 700 times more powerful than the atom bomb (of about 14.5 kilotons yield) dropped on Hiroshima. The former Soviet Union detonated its first hydrogen bomb in 1953. In October 1961, in its Arctic test site the Soviet Union exploded a 58-megaton hydrogen bomb; its father was Andrei Sakharov. The yield of that hydrogen bomb was 4,000 times more than that of the bomb dropped on Hiroshima. It was at that time the most powerful hydrogen bomb ever tested, and it used the same principle which produces nuclear reactions inside stars, including the sun. In subsequent years, however, yields of energetic fusion bombs in excess of 100 megatons were reported.

The United Kingdom exploded its first hydrogen bomb in 1957, followed by France in the early 1960s. China conducted its first hydrogen bomb test on June 17, 1967. Quite early on, China was able to explode a hydrogen bomb with a yield of six megatons.

THE story of the first Indian hydrogen bomb test is a mystery. On May 11, Indian nuclear scientists were silent on the yield from their first hydrogen bomb test, one of the three nuclear devices detonated that day. All one could go by were Prime Minister Vajpayee's words: "The measured yields are in line with the expected values."

The global network of seismometers that monitors the earth for shock waves from earthquakes and atomic blasts had picked up signals which showed that the yield on May 11 from the triple nuclear explosion was between 10 and 25 kilotons. Therefore, it appeared to experts that the first purported Indian hydrogen bomb test was a test not of a true hydrogen bomb but at best of a boosted fission device. Gregory E. Van der Vink, director of planning at the Incorporated Research Institution for Seismology, who advises the U.S. Congress and the Clinton administration, has been reported as saying: "From Monday's test (May 11, 1998) we have a seismic signal of about 5.4. We think this corresponds roughly to an explosive yield of about 10 to 25 kilotons." More or less the same yield was estimated by Japanese and British scientists. But surprisingly, Indian seismologists announced that the yield from the first Indian hydrogen bomb test was about 50 kilotons. This added to the mystery. Experts from other countries openly criticised Indian nuclear scientists and seismologists for exaggerating the yield value of the first Indian hydrogen bomb test.

The waves of hysterical joy whipped up by supporters of the Bharatiya Janata Party, describing the triple nuclear explosion a "spectacular success", contrasted with the doubts expressed by the international scientific community. This obliged the Chairman of the Atomic Energy Commission (AEC), Dr. R. Chidambaram, who is hailed as the father of India's hydrogen bomb, to address the doubts at a May 17 press conference in New Delhi along with A.P.J. Abdul Kalam, Scientific Adviser to the Defence Minister. The press conference looked like a damage control exercise. Chidambaram's attempts at the press conference to dispel the doubts on India's success spawned more doubts and questions.

Chidambaram claimed that from the three nuclear explosions, the item-by-item yield was: from the fission device 15 kilotons; from the low-yield device 0.2 kilotons; and from the thermonuclear device (comprising a fission trigger and a fusion device) 12 kilotons from the fission trigger and 45 kilotons from the fusion device. Chidambaram added that the two sub-kiloton devices exploded on May 13 gave 0.5 kilotons and 0.3 kilotons respectively.

How far was the head of India's nuclear energy establishment able to dispel the doubts? According to him, the reason for the low values recorded by international seismic sensors was the simultaneous triggering of the three devices on May 11. He meant that the simultaneous explosions resulted in interference of shock waves travelling through the earth, which in turn led to a low recording of seismic data on the global network of seismic sensors. But how is it that the shock waves had no interference at the seismic sensors located in various parts of India, such as the one in Karnataka and the one at the Bhabha Atomic Research Centre (BARC), Trombay? How can the shock waves have travelled correctly towards the Indian seismic sensors and in a different manner towards the global network of seismic sensors? Even the seismic sensor in Pakistan, about 437 km from Pokhran, recorded a low seismic value.

Chidambaram's explanation was unscientific in another respect. At the press conference, he revealed that the two shafts, one of which contained the fission device and the other the thermonuclear device, were only 1 km apart. In such a close configuration, given the simultaneous detonation of the two nuclear devices, the epicentre from which the shock waves travel will be more like from one location, and the possibility of interference of shock waves is practically nil.

If two stones thrown into a pond of still water fall simultaneously into the water an inch apart from each other, the ripples will be as if only one stone was thrown into the pond. The simultaneous detonation of two nuclear devices at a distance of 1 km, likewise, would show that there was no scope for any shock wave interference of practical value. Thus it is clear that Chidambaram, in his attempts to dispel the doubts on India's first hydrogen bomb test, used scientific jargon and came out with unscientific statements.

ABDUL KALAM, who spoke at the press conference on May 17, claimed that the nuclear tests conferred on the country "a capability to vacate nuclear threats". His remark only ended up vacating the boundary between a political statement and a scientific statement. A political statement can mean many things, but a scientific statement has only one meaning. That is the characteristic of science. Both Chidambaram and Kalam appear to have ignored this.

When a launch by the Department of Space fails, the failure is not hidden from the public. But the Department of Atomic Energy, under the veil of secrecy, is privileged to hide its failures and also to paint failures as grand successes. Such a privilege, it appears, is fully exercised in respect of India's first hydrogen bomb test. It looks like a major S&T scam.

Referring to the yield values of the five nuclear explosions by India on May 11 and 13, Ray Kidder, a former bomb designer at the Lawrence Livermore National Laboratory, in California, said: "Maybe they tried and failed." Also, Herbert York, a former arms designer and director of the Pentagon's research who once directed the Livermore Laboratory, said very small blasts made little or no sense. He added: "It is a funny thing to do at this stage" of India's atomic evolution.

There are two possibilities that fit the facts. The first is that the scientists at the DAE informed Vajpayee of the true state of the tests but the Prime Minister chose to hide the failure of the hydrogen bomb test. Alternatively, the scientists misled the Prime Minister into believing that the tests, including the hydrogen bomb test, were a grand success. Only a debate in Parliament followed by an inquiry by a Joint Committee of Parliament can resolve this issue. There should be an informed debate in Parliament on the White Paper promised by the Government on the subject.

The irony is not in making the Buddha smile a second time over the experimentation of mass destructive nuclear power in the very land of the peace-loving Buddha. The striking irony is that an utter failure of India's first thermonuclear explosion could be sold to Indians as a "spectacular success".
http://www.hinduonnet.com/fline/fl1512/15120260.htm
 
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Vish,

That article in the NEw Scientist is based on a lot of conjecture.

Read their justification of why the measured yield was lower carefully:

The “magazine” said the tests could have had their seismic signals muffled, possibly by “Decouping” the devices-suspending them within caverns in the ground or burying them in sand.
In theory, 10 kilotonne of explosive force can be completely hidden in this way.
There could be peculiarities in Rajasthan’s geology that may have weakened the signals, the write-up in the magazine says.

It seems a lot of "could be", and not very much actual data substantiating their conclusions.

Also read the bold part in Dr. Samar's interview regarding Pakistan's measurements of the tests. Of course it is a Pakistani opinion, but in conjunction with the doubts raised regarding the yield by independent researchers, it seems damning.
 
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What I have googled indicates he was jailed because of something he posted on an online forum.

FOXNews.com - Student Convicted of Threatening to Kill President Bush, Faces Up to 35 Years in Prison - Local News | News Articles | National News | US News

Student Convicted of Threatening to Kill President Bush, Faces Up to 35 Years in Prison
Friday, June 29, 2007


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A Purdue University graduate student was convicted of threatening to kill President Bush, vice president Dick Cheney and others in postings on the Internet.

Vikram Buddhi, 35, an Indian national who was attending advanced engineering classes at Purdue's West Lafayette campus, was found guilty by a federal jury Thursday on 11 counts of making threats that were posted in a chat room in 2005 and 2006.

Buddhi faces up to 35 years in prison when he is sentenced later this year.

Buddhi hijacked online identities of other Purdue students to post messages, the federal indictment said. The messages justified the murder of Bush and Cheney and the rape of their wives. He also made threats against then-Defense Secretary Donald Rumsfeld and sensitive American infrastructure, U.S. attorneys said during the three-day trial.

Buddhi, who spent a decade studying at Purdue in West Lafayette, never disputed writing online messages such as, "Call for the assassination of GW Bush" and "Rape and Kill Laura Bush."

Rather, the U.S. District Court jury in Hammond had to decide whether Buddhi's comments were true threats or part of a crude online protest of the Iraq War that should be protected by free speech rights.

"I hope this will serve as a deterrent to other people who want to kill human beings, blow up power plants," said Assistant U.S. Attorney Philip Benson.

Defense attorney John Martin said Buddhi had no intention of actually harming anyone.

"Where does it say Mr. Buddhi is going to kill the president, the vice president?" he argued. "It doesn't. These comments are posted in the context of the debate about the Iraq War,"

Buddhi's messages were posted on Yahoo! Finance messages boards, although prosecutors said Buddhi attempted to conceal his actions by using someone else's digital identity.

He was convicted of making threats against the president and successors to the president, making threats against former presidents and their families, making threats by interstate communications and use of the Internet to threaten destruction by fire.

Buddhi never took the stand in his trial, and the defense offered only one witness, an attorney who had located other threatening messages on the same financial news message board that Buddhi used.

The messages were reported to the Secret Service by three readers, and Purdue staff helped investigators track the postings to Buddhi's computer despite his use of software that disguised his computer address.
 
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Vish,

That article in the NEw Scientist is based on a lot of conjecture.

Read their justification of why the measured yield was lower carefully:

It seems a lot of "could be", and not very much actual data substantiating their conclusions.

Also read the bold part in Dr. Samar's interview regarding Pakistan's measurements of the tests. Of course it is a Pakistani opinion, but in conjunction with the doubts raised regarding the yield by independent researchers, it seems damning.

The same can be said for reports that state that the Indian tests were duds.

The point I'm making is that lessons on the H-bomb have been learned and the design will be fine-tuned.
 
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Yowsers. Jailed for ranting on an online forum.

Tough luck on his part I say. I can't count the number of times I have read stupid stuff like that on forums, and bathroom stalls!

I say he was unlucky. The decision to jail him was overkill.

Back to the thread topic though please.
 
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The same can be said for reports that state that the Indian tests were duds.

The point I'm making is that lessons on the H-bomb have been learned and the design will be fine-tuned.

The reports of low yields in the Indo-Pak tests are based on actual measurements, while the arguments of high yield are based on speculation around possible reasons explaining why the measurements were lower.

I agree with you that the designs have been fine tuned and issues probably rectified - no arguments over that in either India or Pakistan's case.

However I am curious about what Pakistan (not so much India, and Assad lets move away from India now) tested.

Dr. Samar says that Pakistan tested low yield tactical weapons in the first set of tests. From the Pakistani perspective this explains the lower reported yields. From the international perspective, this is harder to believe since the speculation has been that Pakistan did not have the expertise to construct compact nukes.

But does the above speculation hold in the face of the new discovery of an advanced design being sold (refer to Albrights article)?
 
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The sixth detonation was made by testing a Pu based device using Plutonium from Khushab Nuclear Reactor which was kept a secret for many years. The considerably small and compact design was developped by PAEC/Nescom inorder to further miniaturise it to fit in multipl delivery systems.

To my knowledge Sino-Pak cooperation in restricted to HEU technology (headed by A.Q. Khan). A similar Pu based nuclear programme was running paralell under PAEC/Nescom for decades and this technology is believed to be the base for our future designs now.

HEU technology will be restricted to generate fuel for our nuclear power plants.
 
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From a David Albright report at ISIS
After the Libyan discoveries in 2003 and 2004, Pakistani officials categorically asserted that Khan did not sell their nuclear weapon designs. Although Pakistan’s designs were developed from the Chinese-supplied design, Pakistan had gone further in designing warheads that were lighter and smaller than the Chinese design.....

...Soon after learning of the weapon designs, a senior IAEA official told Pakistani government officials about the designs found in Switzerland. The Pakistanis were upset, since they realized that the designs had to be from their nuclear weapons arsenal. They were genuinely shocked; Khan may have transferred his own country’s most secret and dangerous information to foreign smugglers so that they could sell it for a profit. And these advanced nuclear weapons designs may have long ago been sold off to some of most treacherous regimes in the world.
http://www.isis-online.org/publications/expcontrol/Advanced_Bomb_16June2008.pdf
 
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I am thinking about buying some wholesale water pipes from this company in China
but I am not sure if they are legal to bring in to the states? What are the laws on water pipes, bongs, and pipes?
 
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