Violet Club

Last updated

Violet Club was a nuclear weapon deployed by the United Kingdom during the Cold War; the name was chosen in adherence to the Rainbow code system. It was Britain's first operational "high-yield" weapon and was intended to provide an emergency capability until a thermonuclear weapon could be developed from the 1956–1958 Operation Grapple tests. Violet Club was ultimately replaced in service by the Red Snow warhead, derived from the US W28 warhead.

Contents

Conception, design and development

In 1953, shortly after the Americans tested a thermonuclear device in 1952, followed by the Soviets with Joe 4, [A 1] the Atomic Weapons Research Establishment (AWRE) at Aldermaston was asked about the possibilities for a very large pure fission bomb with a yield of one megaton. This study referred to the Zodiak Mk.3 bomb, but progressed no further than a rudimentary study. [1]

At this time studies were also started [2] that ultimately led to a decision in July 1954 to develop a thermonuclear weapon. The design studies were split into two tracks because the British at that time had not yet discovered the Teller–Ulam technique necessary to initiate fusion. One track led to an intermediate design, the so-called "Type A" thermonuclear design, similar to the US Alarm Clock and Soviet Sloika hybrid designs; these types of weapons are now regarded as large boosted fission weapons and no longer regarded as thermonuclear. A true thermonuclear design, one that would derive a large amount of its total energy from fusion reactions, was referred to as "Type B".

Development of the Type A design was carried out under Green Bamboo, which weighed about 4,500 lb (2,045 kg), and its spherical shape measured about 45 inches (115 cm) diameter, with a 72-point implosion system. [3] This was intended as the warhead for all projected British strategic delivery systems of the period; the Yellow Sun Stage 1 air-dropped bomb, and the Blue Steel air-launched stand-off missile. The large girth of these weapons was designed to accommodate the diameter of Green Bamboo's implosion sphere. [4]

Green Bamboo was too large to fit in the Blue Streak missile, whose design was already well advanced. This led to a reduced-size design, later known as Orange Herald, which was made smaller largely by reducing the size and complexity of the implosion system. This produced less compression of the core and less efficient use of the fissile fuel, so to make up for this loss of performance the amount of fuel was increased. Estimates computed from reliable sources of actual core cost [5] and cost per kilogram [6] of highly enriched uranium (HEU) put the core sizes of Green Bamboo and Orange Herald as 98 kg and 125 kg respectively, although some other published (and unverified) sources claim lower figures of 87 kg and 117 kg respectively. [7] This design was tested on 31 May 1957 on Malden Island, yielding 720  kt. [8]

Ultimately the decision was made to abandon Green Bamboo in favour of the true thermonuclear devices, being developed as the "Granite" series. The first Granite tests were carried out as part of Operation Grapple during May and June 1957. The first, Short Granite, was a failure, generating only 300 kt from an expected yield of around 1 Mt. Plans to test a second identical device, Green Granite, were cancelled as a result. Orange Herald was next, delivering 720 to 800 kt, as expected, making it the largest fission device ever tested. A slightly modified Short Granite was then tested as Purple Granite, but also failed, delivering the same 300 kt.

The abandonment of Green Bamboo and the Granite failures left a capability gap. An emergency capability weapon to fill that gap was devised from elements of both Green Bamboo and Orange Herald; being known as Knobkerry, [9] or Green Grass, and the Interim Megaton Weapon. [10] There were also other factors involved in the decision to build an Interim Megaton Weapon. One was that by 1957 the UK HEU production programme was producing more HEU than required. The Chiefs of Staff were reluctant to see it continue to languish in stores, unused for weapons, when it was being produced at great cost. [11]

The Green Grass warhead containing perhaps 70–86 kg of HEU (although there are no reliable declassified sources for this figure) was therefore hurriedly produced and installed in a modified Blue Danube casing, to be known as Violet Club, until a better solution based on the Yellow Sun casing could be produced, known then with Green Grass installed, as Yellow Sun Mk.1. [12] Only five Violet Club weapons were produced, known by the RAF description of Bomb, Aircraft, HE 9,000 lb HC, and they were stripped of their Green Grass warheads for transfer to the better casings when these became available.

Design features

Schematic of the steel ball bearing arrangement common to Green Grass, Green Bamboo and Orange Herald warheads. The internal and external diameters can be computed from the 450 kg weight of the steel balls. First published in Synergy Magazine, published Southampton, UK, No3, 2003 Steel balls.png
Schematic of the steel ball bearing arrangement common to Green Grass, Green Bamboo and Orange Herald warheads. The internal and external diameters can be computed from the 450 kg weight of the steel balls. First published in Synergy Magazine, published Southampton, UK, No3, 2003

Violet Club (and to a lesser degree Yellow Sun Mk.1) was not considered a satisfactory design and suffered from numerous design defects. An implosion design, the fissile core of the weapon was a hollow sphere of highly enriched uranium (HEU) which was surrounded by a high-explosive supercharge and 72-lens implosion system. [13] The HEU core was greater than one uncompressed critical mass and to maintain it in a sub-critical condition AWRE fashioned it into a hollow thin-walled sphere. The HEU sphere was collapsed inwards by the supercharge and 72 explosive lenses. However, a fire in the bomb store or a traffic collision on the airfield could easily lead to a partial crushing or collapse of the unremovable uranium shell, and in turn a spontaneous nuclear chain reaction. AWRE responded by inserting (through a hole in the shell) a rubber bag, and filled this with 20,000 steel ball bearings of 0.375 inches (9.5 mm), weighing around 70 kilograms (150 lb). [14] Subsequently, the number of these steel balls was increased to 133,000, [15] with a reduction in size to approx 5 millimetres (0.20 in) diameter. The balls were retained in the device by sealing the hole with a plastic bung.

The steel balls were intended to prevent a nuclear detonation even if the explosives fired accidentally, or in any conceivable accident. [A 2] The ball bearings had to be removed through the hole in the bomb casing during flight preparation, and after the bomb was winched into the aircraft. The ball bearings then had to be re-inserted into the lowered and upturned bomb before transport back to the bomb store. Without the ball bearings installed, these weapons were armed and live, and too dangerous to be allowed to fly on exercises. Bomber Command exercises demonstrated that flight preparation followed by a scramble take-off could not be reduced below thirty minutes, [16] and on exercises in bad weather and at night a ninety-minute scramble was the norm. [17] At least one accident, dated 1960, was reported in the press when the plastic bung was removed and 133,000 steel ball bearings spilled onto the aircraft hangar floor, leaving the bomb armed and vulnerable. [18] The Royal Air Force were so nervous of the outcome of a fire in storage that permission was sought to store the bombs inverted, so that a loss of the plastic bung could not end with the steel balls on the floor, leaving the HEU unprotected against a subsequent explosion. [19] Even without the partial nuclear detonation feared by the RAF, there was "a risk of catastrophe". [20]

AWRE's trickery with the steel balls had other unintended outcomes. Even an event as inconsequential as early morning frost was an issue. Violet Club could be loaded into a bomber for up to thirty days on standby while parked overnight on a remote base where the bomb could get very cold. If the steel balls froze together inside the bomb cavity and could not be removed, the bomb was useless. AWRE's solution was to fit the bomb with an electric blanket. Because the bombs were armed before flight, the take-off was hazardous; the bombs could not be jettisoned, and landing with an armed bomb on return to base was too hazardous to contemplate. As a consequence, Violet Club could not be used on an airborne alert, [21] or even flown to a remote dispersal base.

Other design flaws centred on a requirement for a strip-down and inspection at six-monthly intervals, this took three weeks per weapon using AWRE civilian staff. The unstable nature of the bomb required that the work be done in-situ at RAF facilities, causing considerable disruption to operational duties. There were three main reasons for the strip-down and these were deterioration of the rubber bag, corrosion of the steel balls, and deterioration of the HE, which was prone to cracking. Replacement of a weapon's HE would cost the RAF in excess of £90,000 adjusted to 2006 prices. [22]

Green Grass/Violet Club was the first UK-deployed weapon to dispense with the crude polonium and beryllium impact or crush type initiators used in Fat Man and other early US weapons together with the British Blue Danube and Red Beard. Instead it used an electronic neutron initiator (ENI) known as Blue Stone. This had the great advantage of being adjustable, allowing the neutron burst to be triggered at precisely the right moment. The burst heights of Green Grass were optimized for either maximum overpressure without allowing fireball contact with the ground, or to maximise the ground area subjected to a 6 psi overpressure; respectively 3,500 feet (1,100 m) and 6,200 feet (1,900 m) above ground level [23] A barometric fuze was used, backed-up by an adjustable clockwork timer fuze [24] with impact fuses as a final fail-safe. Most of these mechanisms originated from Blue Danube although the radar altimeter fuze was omitted. [25] The electrical power for these fuzing mechanisms and the firing mechanisms of the 72-lens, 45-inch (110 cm) implosion device came from lead-acid accumulators located in the tail of the Blue Danube casing. These were commercially sourced six-volt motorcycle batteries.

Controversy

Green Grass struggled to meet the Chiefs of Staff requirement for an Interim Megaton [yield] Weapon. It was never tested, and initially, AWRE estimated its yield at 500 kt based on the Orange Herald test of 720kt, and non-nuclear tests of the HE implosion sphere fitted with non-fissile cores. A Mr Challens of AWRE who later became the Director of AWRE then claimed to the Air Staff that

A weapon of one half megaton was considered to be in the megaton range. [26] [27]

A play-on-words that later returned to haunt AWRE when later estimates revised the yield to 400kt. Challens also stated on behalf of AWRE that

AWRE were almost completely sure that a nuclear explosion would not occur if the balls are in, - but in the absence of trial proof, he could not guarantee it. [A 3]

The Royal Air Force was not amused, with Bomber Command Staff officers minuting their seniors with remarks like this one. [28]

This [minute] means that Violet Club and Yellow Sun Mk.1 are not "in the megaton range" at all, notwithstanding the extraordinary measures taken, and costs involved for what we had thought to be a megaton capability. This ... lead me to the belief that production of Green Grass be curtailed. I cannot imagine any commercial organisation continuing to buy a device that so patently fails to meet the requirement, or to be misled without protest as the Air Ministry has so consistently been [misled] by AWRE.

Senior levels of the RAF believed they had been sold a lemon. Further, the weapon was of uncertain safety in the hands of the inexperienced RAF.

Aircraft engines must not be run with Violet Club loaded on the aircraft with the safety device [of steel balls] in place. The engines must not be started until the weapon is prepared for an actual operational sortie [to prevent the steel balls vibrating like a bag of jellybeans]. [29]

... uncertainty exists about the effects of movement with the balls inserted. [30]

The fifth and last Violet Club weapon was due for delivery to the RAF by the end of May 1959 [31] and all were withdrawn by 1960, but in their Yellow Sun Mk.1 form they survived until 1963, when all had been replaced with Yellow Sun Mk.2 with Red Snow warheads installed. They were only used by the Avro Vulcan bomber. [32]

Conclusion

These very large and dirty fission bombs were the largest pure-fission bombs deployed [A 4] by any state, and unlike their predecessors, Blue Danube and Red Beard, they used HEU as a fissile material rather than plutonium, the reason being primarily economic. The cost of HEU to the Royal Air Force[ clarification needed ] was (at 1958 to 1959 prices) £19,200 per kg, with plutonium priced at £143,000 per kg. [6] Although a HEU weapon needed more fissile material for a given yield than a plutonium weapon, [33] a saving per weapon was of the order of £22.7M at 2006 prices. Thirty-seven Green Grass warheads were built (twelve as Violet Club) saving the Treasury £840M. The influence of the Treasury on weapons procurement should not be underestimated: it reaches even into weapons design. Clearly, there were economic benefits in building large and dirty U-235 fission bombs, rather than cleaner, but more expensive plutonium weapons, especially given the shortage of plutonium. By 1958 Britain's accumulated production of plutonium was only 472.2 kg [34] and a proportion of that was bartered to the United States in exchange for HEU and other items. Up to 1958, British output of HEU was only 860 kg, [35] while the United States supplied the UK with approximately seven tons of HEU from their less costly production process. So HEU used for Green Grass was purchased cheaply from the U.S. while selling to the U.S. the unwanted and high-priced weapons-grade plutonium.

Knobkerry, alias Green Grass, alias Interim Megaton Weapon, alias Violet Club and Yellow Sun Mk.1, had one other distinction. It was the last entirely British nuclear weapon deployed with the UK Armed Services. The British Operation Grapple thermonuclear weapon tests at Christmas Island in 1957–58 were the end of this evolution. There were no more wholly home-grown designs. Britain never deployed a true thermonuclear weapon of wholly home-grown design. All the weapons tested at Operation Grapple were abandoned, because AWRE no longer needed them, although some of their features were undoubtedly incorporated into later weapons. These Granite-type devices were all experimental devices, needing to be developed further into reliable Service-engineered warheads at considerable cost in time and money. The U.S. designs offered after 1958 were fully tested and engineered, and cheap to produce. [36] They were manufactured in Britain from British materials and U.S. blueprints. They were British property and there were no American political constraints on their use, they were a favourable deal for the Treasury, and Violet Club and Yellow Sun Mk.1 bridged the gap until the American designs could be manufactured.

See also

Ivy King, the largest pure-fission nuclear bomb ever tested by the United States.

Related Research Articles

<span class="mw-page-title-main">Nuclear weapon design</span> Process by which nuclear WMDs are designed and produced

Nuclear weapon designs are physical, chemical, and engineering arrangements that cause the physics package of a nuclear weapon to detonate. There are three existing basic design types:

<span class="mw-page-title-main">Yellow Sun (nuclear weapon)</span> First British operational high-yield strategic nuclear weapon warhead

Yellow Sun was the first British operational high-yield strategic nuclear weapon warhead. The name refers only to the outer casing; the warhead was known as "Green Grass" in Yellow Sun Mk.1 and "Red Snow" in Yellow Sun Mk.2.

Red Snow was a British thermonuclear weapon, based on the US W28 design used in the B28 thermonuclear bomb and AGM-28 Hound Dog missile. The US W28 had yields of 70, 350, 1,100 and 1,450 kilotonnes of TNT and while Red Snow yields are still classified, declassified British documents indicate the existence of "kiloton Red Snow" and "megaton Red Snow" variants of the weapon, suggesting similar yield options, while other sources have suggested a yield of approximately 1 megatonne of TNT (4.2 PJ).

<span class="mw-page-title-main">Ivy King</span> Largest pure-fission US nuclear bomb test

Ivy King was the largest pure-fission nuclear bomb ever tested by the United States. The bomb was tested during the Truman administration as part of Operation Ivy. This series of tests involved the development of very powerful nuclear weapons in response to the nuclear weapons program of the Soviet Union.

<span class="mw-page-title-main">B41 nuclear bomb</span> American high-yield thermonuclear weapon

The B-41 was a thermonuclear weapon deployed by the United States Strategic Air Command in the early 1960s. It was the most powerful nuclear bomb ever developed by the United States, with a maximum yield of 25 megatons of TNT. A top secret document, states “The US has stockpiled bombs of 9 MT and 23 MT...” which would likely be referring to the B-41's actual yield(s). The B-41 was the only three-stage thermonuclear weapon fielded by the U.S.

<span class="mw-page-title-main">Boosted fission weapon</span> Type of nuclear weapon

A boosted fission weapon usually refers to a type of nuclear bomb that uses a small amount of fusion fuel to increase the rate, and thus yield, of a fission reaction. The neutrons released by the fusion reactions add to the neutrons released due to fission, allowing for more neutron-induced fission reactions to take place. The rate of fission is thereby greatly increased such that much more of the fissile material is able to undergo fission before the core explosively disassembles. The fusion process itself adds only a small amount of energy to the process, perhaps 1%.

<span class="mw-page-title-main">Castle Romeo</span> Codename for one of the first thermonuclear bomb tests

Castle Romeo was the code name given to one of the tests in the Operation Castle series of U.S. nuclear tests. It was the first test of the TX-17 thermonuclear weapon, the first deployed thermonuclear bomb.

<span class="mw-page-title-main">Thermonuclear weapon</span> 2-stage nuclear weapon

A thermonuclear weapon, fusion weapon or hydrogen bomb (H bomb) is a second-generation nuclear weapon design. Its greater sophistication affords it vastly greater destructive power than first-generation nuclear bombs, a more compact size, a lower mass, or a combination of these benefits. Characteristics of nuclear fusion reactions make possible the use of non-fissile depleted uranium as the weapon's main fuel, thus allowing more efficient use of scarce fissile material such as uranium-235 or plutonium-239. The first full-scale thermonuclear test was carried out by the United States in 1952 and the concept has since been employed by most of the world's nuclear powers in the design of their weapons.

<span class="mw-page-title-main">Gun-type fission weapon</span> Fission-based nuclear weapon

Gun-type fission weapons are fission-based nuclear weapons whose design assembles their fissile material into a supercritical mass by the use of the "gun" method: shooting one piece of sub-critical material into another. Although this is sometimes pictured as two sub-critical hemispheres driven together to make a supercritical sphere, typically a hollow projectile is shot onto a spike, which fills the hole in its center. Its name is a reference to the fact that it is shooting the material through an artillery barrel as if it were a projectile.

According to researcher Chuck Hansen, the W34 Python was a gas-boosted fission primary used in several designs of American thermonuclear weapons.

<span class="mw-page-title-main">Mark 5 nuclear bomb</span> Nuclear weapon design

The Mark 5 nuclear bomb and W5 nuclear warhead were a common core American nuclear weapon design, designed in the early 1950s and which saw service from 1952 to 1963.

<span class="mw-page-title-main">Mark 18 nuclear bomb</span> American nuclear bomb design

The Mark 18 nuclear bomb, also known as the SOB or Super Oralloy Bomb, was an American nuclear bomb design which was the highest yield fission bomb produced by the US. The Mark 18 had a design yield of 500 kilotons. Nuclear weapon designer Ted Taylor was the lead designer for the Mark 18.

<span class="mw-page-title-main">Mark 6 nuclear bomb</span> Type of bomb

The Mark 6 nuclear bomb was an American nuclear bomb based on the earlier Mark 4 nuclear bomb and its predecessor, the Mark 3 Fat Man nuclear bomb design.

<span class="mw-page-title-main">Mark 24 nuclear bomb</span> American thermonuclear bomb design

The Mark 24 nuclear bomb was an American thermonuclear bomb design, based on the third American thermonuclear bomb test, Castle Yankee. The Mark 24 bomb was tied as the largest weight and size nuclear bomb ever deployed by the United States, with the same size and weight as the Mark 17 nuclear bomb which used a very similar design concept but unenriched Lithium.

<span class="mw-page-title-main">Mark 15 nuclear bomb</span> American thermonuclear bomb

The Mark 15 nuclear bomb, or Mk-15, was a 1950s American thermonuclear bomb, the first relatively lightweight thermonuclear bomb created by the United States.

<span class="mw-page-title-main">Orange Herald</span> British nuclear weapons

Orange Herald was a British nuclear weapon, tested on 31 May 1957. At the time it was reported as an H-bomb, although in fact it was a large boosted fission weapon and remains to date, the largest fission device ever detonated.

<span class="mw-page-title-main">Uranium hydride bomb</span> Type of atomic bomb

The uranium hydride bomb was a variant design of the atomic bomb first suggested by Robert Oppenheimer in 1939 and advocated and tested by Edward Teller. It used deuterium, an isotope of hydrogen, as a neutron moderator in a uranium-deuterium ceramic compact. Unlike all other fission-bomb types, the concept relies on a chain reaction of slow nuclear fission. Bomb efficiency was harmed by the slowing of neutrons since the latter delays the reaction, as delineated by Rob Serber in his 1992 extension of the original Los Alamos Primer.

ET.317 was a thermonuclear weapon of the British Royal Navy, developed for the UK version of the UGM-27 Polaris missile.

References

Citations

  1. Public Record Office, London. AIR 2/13759 E8A. (PRO).
  2. PRO AIR 2/13759 E18B.
  3. PRO. AVIA 65/1193 E10A. Tech Note GW375 p2 para 2.
  4. Humphrey Wynn, RAF Strategic Nuclear Forces: their origins, roles and deployment 1946–69. Published HMSO London 1994. ISBN   978-0-11-772833-2, p. 193. (Wynn).
  5. PRO. AB 16/1888 E111.
  6. 1 2 PRO. AB 16/3878 Appendix 4.
  7. "Veterans Disability Guide". Veterans Disability Guide. Dec 2, 2017. Retrieved May 7, 2020.
  8. Lorna Arnold, Britain and the H-Bomb, the official history, p. 147, 236. Published Palgrave, 2001. ISBN   978-0-312-23518-5 in North America, ISBN   978-0-333-94742-5 elsewhere.
  9. PRO. AVIA 65/1116 E18.
  10. PRO. AIR 2/13680 E11A.
  11. PRO. AIR 2/13680 E11A and E46B.
  12. Wynn. pp. 248–251.
  13. PRO. AVIA 65/1218 E183 (a)
  14. PRO. AVIA 65/777 E38 Section 5.
  15. David J.Hawkins, Keeping the Peace, The Aldermaston Story, p52. Published Pen and Sword in association with AWE, 2000. ISBN   978-0-85052-775-9
  16. PRO. AIR 2/13705 E36A (c).
  17. PRO. AIR 2/13705 E62A page 1.
  18. Sunday Telegraph, London, 28 June 1998, p13.
  19. PRO. AVIA 65/1218 E181, E193.
  20. PRO. AIR 2/13705 E62A page 2, E47A page 3, and PRO. AIR 2/13718 E249 page 2.
  21. PRO. AIR 2/13705 E36A.
  22. PRO. AVIA 65/1155 E194 para 11.
  23. PRO. AIR 2/13705 E58A.
  24. PRO. AIR 2/13718 E7A (4)
  25. PRO. AIR 2/13718 E21B (3)
  26. At a conference recorded in PRO. AVIA 65/1218
  27. Talk:Ivy King
  28. PRO. AIR 2/13705 E59A
  29. PRO. AIR 2/13718 E15A (3)(d)
  30. PRO. AIR 2/13718 E21B (14)
  31. PRO AVIA 65/1116 E20.
  32. Donald, David (2008). "Handley Page Victor". International Air Power Review. 25: 131.
  33. Charles S.Grace, Nuclear Weapons: Principles, Effects and Survivability. Published: Royal College of Military Science, Shrivenham, Wilts, and Brasseys, 1994. ISBN   978-0-08-040992-4
  34. PRO AB 16/3878 various enclosures.
  35. PRO. AB 16/3878 various enclosures.
  36. PRO. AVIA 65/1771 E24 page 1 para 3, and PRO. AVIA 65/1792.

Footnotes

  1. Joe 4, aka the Sloika design / RDS-6s test, while demonstrating thermonuclear reactions was not a true thermonuclear device
  2. The US Mk-18 uranium bomb tested at Ivy King with a yield of 500 kt had a similar safety design: the hollow center was filled with a chain made from aluminum and boron which was pulled out to arm the bomb.
  3. The Americans had the resources to perform such safety trials, see Nuclear weapon design § One-point safety
  4. The comparable US Mk-18 / Ivy King device was never deployed.

References

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.