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Federated Fire Territories
Nuclear program start date	1943 (1943)
First nuclear weapon test	May 6, 1951 (1951-05-06)
NPT party	Signatory of STAPNA

The Federated Fire Territories commonly known as Fyrland, was the # country after New Tyran and Sieuxerr to develop and test nuclear weapons, and is one of the signatories to the STAPNA agreement.

Although the Fyrish scientific community was aware of global discourse on the feasibility of an atomic bomb throughout the 1930s, plans to develop such a weapon existed only in passing proposals by 1940, and an assessment programme was only initiated by 1943; the assessment programme was initiated due to the conspicuous lack of scientific publications regarding the study of nuclear fission, by Anglian, Glasic, and Sieuxerrian scientists, as Fyrish physicists suspected that the Entente powers had secretly begun development of a "superweapon".

No practical effort was made to pursue the programme, until the aftermath of the first use of atomic weaponry on Dongrŭng and Anchŏn in Menghe on November 9, 1945 (1945-11-09), which gave the impetus to fully initiate a nuclear weapons programme, codenamed Fenix.^[1]

Early efforts

Accelerating feasibility

Physicist Eadgar Tafari Desta as he appeared in a 1941 newspaper column regarding his lobbying efforts.

With the steady stream of scientific publications regarding nuclear fission abruptly tailing off with the start of the Pan-Septentrion War, Fyrish physicist Eadgar Tafari Desta promptly took it upon himself to raise concern over the fact, as he suspected a conspiracy by the Entente powers to develop a "superweapon". Strong lobbying efforts by Fyrish physicists and scientists, lead by Eadgar Tafari Desta at the start of 1940, managed to convince the government to setup an assessment programme by 1943, which was to address the "uranium issue", Isotope separation, and investigate the possibility of a chain reaction weapon.

Early efforts centered around the issue of isotope seperation, as the properties of Uranium-235 (U-235) regarding its tendancy to release two neutrons when undergoing fission, were theorised since 1935, which made it a prime candidate for a chain reaction. The primary issue with U-235, was although it was naturally occuring, the abundance of U-235 in natural uranium was known to be approximately 0.7%, whilst being chemically identical to the main constituent of natural uranium, which was U-238; isotope-238 was known to be fissionable but not fissile, which made it incapable of supporting the slow neutron chain reaction bomb concept. With no progress being made on the seperative work process by 1945, due to the programme's strictly assessment nature, sufficient quantities of uranium isotopes were never made available to the assessment programme, which were required in order to conduct tests to ascertain data as to the true nature of a chain reaction bomb.

The situation changed dramatically when the Federated Fire Territories learned of the atomic bombings of Dongrŭng and Anchŏn in 1945. Immediately after the atomic bombing, the assessment programme was moved to live project status, under Desta's lead, with the codename Fenix, and given top priority to national defence. From this point, the work on the programme was carried out quickly, resulting in the first nuclear reactor, known as the Britræᵹ Atomfīn (Britræᵹ nuclear pile), being constructed near Britræᵹ on February 5, 1946 (1946-02-05).

Isotope separation

Theoretical physicist Oswald Uhtric.

Although the Britræᵹ nuclear pile was completed by the start of 1946, sufficient quantities of enriched uranium were still unavailable for weapons development, and the pile was far smaller than ideal. The Britræᵹ piles' primary purpose was to produce plutonium-239 from natural uranium, 10 micrograms (μg) of which had been produced via cyclotron, a recent Casaterran invention, previously under the assessment programme, and was discovered to have 1.7 times the thermal neutron capture cross section of uranium-235. The assessment programme panel presented these findings to Fyrish physicist Eadgar Tafari Desta towards the end of 1944, who then discussed with theoretical physicist Oswald Uhtric, how plutonium might be produced in a nuclear reactor. Desta submitted his report in December of the same year, which suggested the construction of a nuclear pile.

Diagram of uranium isotope separation in the calutron.

Continually bottlenecking the program however, was the lack of industrial capacity for the seperation of uranium isotopes, which was an issue that persisted through to 1947; at the time a process known as thermal diffusion was providing the program with uranium enriched to almost 2% in its entirety, with only one small research facility in operation at the time. Not until May 20th 1947, was further headway made into the process, when the Lārhūs of Fæstēah (LoF)^[2] Larstaþol for Atomfandian (Institute for Atomic Research)^[3], managed to successfully modify a cyclotron to overcome the space charge limitation; researchers had suspected that air molecules in the vacuum chamber would neutralise the ions, and create a focused beam to be separated into a collector. This modified mass spectrometer, coined calutron in Casaterran circles, proved capable of performing isotope separation far more effectively than previous attempts, such as the trials by the Lārhūs of Britræᵹ (LoB) Institute for Atomic Research's attempts using a klystron. When the LoB calutron was first operated on May 20th, a uranium beam intensity of 5 microamperes (μA) was received by the collector, thus proving the researchers correct about the effect air molecules had in the vacuum chamber. Later improvements led to a twelve-hour run on June 30th, with a 50 μA beam producing 24 μg of uranium enriched to 25% uranium-235, which was about ten times as much as the klystron at LoB had produced; by August, further improvements in technique refinement allowed it to generate a 1,500 μA beam, with 80 μg samples enriched to 30% being sent to project Fenix's team in the same month. Now in combination with the existing thermal diffusion process, the calutron process was able to enrich uranium from its natural 0.7% concentration of U-235, to the highest levels yet seen in Fyrland, upto 73.2% enrichment, albeit only in small quantities.

Industrial enrichment

Employees of project Fenix operating calutron control panels at Steall-B, around 1949.

By the start of 1948, the Britræᵹ nuclear pile had produced almost 60 kg of plutonium from natural uranium, the processing of which had initially been bottlenecked by lack of a dedicated site for the bismuth phosphate process; and the construction of a dedicated site for this process was nearly complete by this time. The ability of plutonium-239 to be chemically separated from irradiated natural uranium fuel used in the Britræᵹ pile, made its manufacture and enrichment process far easier than that for the enrichment process of uranium-235; as a result, project Fenix scientists had managed to have the chance to work with substantial quantities of the isotope, and had determined it to be unviable for the gun-type fission weapon concept. The scientists had discovered that the plutonium-239 was contaminated with plutonium-240 from the pile process, which caused a high rate of spontaneous fission due to the presence of isotope-240; this in turn meant that the speed at which the gun-type device would have to bring the two sub-critical masses together, would be far in excess of what was achievable in the dimension restrictions of a bomb bay; therefore the idea of a gun-type plutonium fuelled fission weapon, was shelved for the time being.

A dedicated thermal diffusion processing plant was completed by February of 1948 near Fæstēah, simply known as Steall-A (Site-A), which had been under construction since mid-1946. The site contained 2,500 columns, each approximately 15 meters long, and was the first truly industrial scale nuclear facility in Fyrland; this facility would then provide lightly enriched uranium, on the order of 1.8% U-235, to the still incomplete calutron facility. The calutron facility, known as Steall-B (Site-B), had been under construction since July of 1947, and sought to expand upon the LoF's methodology in scale drastically. Each facility at the time was the single most expensive project undertaken by any Fyrish government. Site-B was fully operational by May of 1949, and had provided enrichment of small quantities of uranium from Site-A as early as April of 1948, which would be the first uranium to make it into a Fyrish atomic weapon test.

The path to a weapon

Experiment apparatus for Glæs shot 78 in January of 1950. Each rectangular box contains eight cylindrical fast ionization chambers.

With Fæstēah Site-A and Site-B producing enriched uranium as early as mid-1948, weapon development began in earnest, with the intent to realise the now proven potential of the atom. A gun-type device was the most obvious candidate for a first weapons trial, as the critical mass of what was capable of being produced by Site-A and Site-B, was known through experimental trials; an ~80 kg cylindrical core of uranium enriched to 73.2% U-235, would be sufficient for a gun-type fission weapon. However, due to the less than ideal level of enrichment, and high quantity of enriched uranium required, production of the comparatively simple gun-type device would become rather laborious; with some 11.3 tonnes of natural uranium being processed to make the ~80 kg core. As such, the quantities for the most viable of the weapon concepts, was not available for immediate testing as of May of 1949.

Wilfrid Seble at the LoB Institute for Atomic Research in 1987.

Portrait of Berhane Osgar.

Because of the apparent dificulty in uranium enrichment, especially in comparison to plutonium production, as early as February of 1948 a second weapon concept was being explored; the concept called for a core made of plutonium, hollowed out, to be compressed into a state of criticality via an explosive compression wave. The plutonium produced by the Britræᵹ nuclear pile, contaminated with plutonium-240 which was prone to a high rate of spontaneous fission, could theoretically be kept sub-critical in this fashion. This concept was the brainchild of Fyrish theoretical physicist Berhane Osgar, who presented it to the team lead at the LoB Institute for Atomic Research towards the end of July of 1949; the team lead, Norsatiran theoretical physicist Wilfrid Seble, had taken the idea to the Þēodale Neringfandian Gemōt (ThNG)^[4], where he spoke to Reberiyan born Kazymir Karpowskyi and his team. Seble and Karpowskyi's efforts through August to November at imploding tubes to produce cylinders, tended to produce objects that resembled rocks; which severely damaged the credibility of Osgar's implosion concept. However, Osgar was still in belief that the implosion method was practical, and only his ardent determination kept the project alive. Seble proposed in November of 1949, that rather than a hollow core be used, a solid core should replace it instead, while Karpowskyi implied the use of shaped charges might offer more control to the explosion; Seble was convinced by the idea that, under such pressures, the plutonium core itself would be compressed, without the need for a hollow pit. Seble's knowledge of how dense metals behaved under heavy pressure was influenced by his pre-Pan-Septentrion war theoretical studies of Septentrion's core. The primary task for the compression of a solid core then, was the shaped charge driven compression, which Karpowskyi and his team began further experimenting with under project Glæs (Glas)^[5].

A recreation of the first sphere of plutonium, surrounded by neutron-reflecting tungsten carbide blocks.

Reberiyan born Kazymir Karpowskyi.

X-ray image sequence of a successful project Glæs lens array.

The metallurgists task, was to work out how to construct the plutonium from the Britræᵹ pile into a sphere, the difficulties of which became apparent when attempts to measure the density of the plutonium gave inconsistent results. Contamination was originally believed to be the culprit, but it was soon determined that there were multiple allotropes of plutonium. Alloying the plutonium with aluminium was tried, and found to be stable at room temperature, although aluminium emits neutrons when bombarded with alpha particles, which would increase the spontaneous fission problem; it was found that a plutonium–gallium alloy would stabilise the pit, and could be hot pressed into the desired spherical shape. The first plutonium core was manufactured this way at Britræᵹ Efnefandian Larstaþol (BEfL) Steall-Æ (Site-AE)^[6], originally constructed for the bismuth phosphate process, in February of 1950; coming in at 6.2 kg and 3.5 inches in diameter.

By March of 1951, Karpowskyi and his team under project Glæs, had managed to successfully and symmetrically compress a metal sphere using a form of shaped charge, known as an explosive lens; the experiment measured changes in the absorption of gamma rays by the metal of the sphere as it underwent compression, and had through extensive iteration managed to produce the desired results. Karpowskyi's team, in order to control the precise detonation of the array of explosive lenses, had created what was simply known as the Arc (Ark)^[7], which weighed some 300 kg and contained everything needed to control the sequence; the Arc would send signals to the 32 exploding-bridgewire detonators arranged around the truncated icosahedron explosive lens array. The results of the project were handed back to Seble and his team, which managed to convince both Seble and Osgar as to its viability; this was then presented to the head of project Fenix, Desta, in a meeting at Site-B on April 2nd, 1951.

The first weapon

The culmination of years of development, and billions in taxpayer funds, was represented by the first viable nuclear device produced in the Federated Fire Territories; the weapon code name given by Desta, Ælf (Elf)^[8], was used to refer to the construction and testing of the device; which began on April 14th 1951. The core for the device was 6.2 kg of 93% plutonium-239, the third such core produced from the Britræᵹ pile, and was delivered to the test site known as Steall-1 (Site-1)^[9], on April 29th. Under the watch of Desta and Seble's team, the core was loaded into the Glæs array, sealed shut, and transported to the test stand at Steall-0 (Site-0). The test stand was a wooden tower, 30 meters (98 feet) tall, where the device was hoisted to the top and suspended above the ground for detonation; the Arc was atop the tower, where Karpowskyi's team connected it with the Elf to complete the device. Upon completing the setup, Desta, Uhtric, Seble, Osgar, and Karpowskyi, shared a bottle of whiskey in celebration; the day after, May 6th 1951, they would test the device.

Ælf-1

The projected yield of the device was 5 kilotons of TNT (21 TJ), which weighed 3,810 kg (8,400 lbs) and was 1.29 meters (51 inch) in diameter. The core was 8.9 cm (3.5 inch) in diameter, and was warm to the touch, emitting about 15 Watts of heat. The tamper, serving as a neutron reflector to capture stray neutrons from the reaction, and as mass to provide inertia to contain the reaction for longer, was made of depleted uranium and 20.6 cm (8.1 inch) in diameter; the tamper had a removable 10 cm (4 inch) cylinder section in which the pit was located, which enabled the transport of the device without a core. This was surrounded by a 0.7 cm (0.27 inch) thick shell of boron-impregnated plastic, also with a removable section 11.4 cm (4.5 inch) in size. The aluminium pusher then encased these assemblies, which was 41.1 cm (16.2 inch) in diameter, with a 13 cm (5.1 inch) plug to allow access to the removable components.

Section diagram of Ælf-1

The Glæs array of explosive lenses then surrounded this assembly, and the explosion generated would symmetrically compress the plutonium to over twice its normal density; initiating a fission chain reaction.

•   The exploding-bridgewire detonators simultaneously initiate a detonation wave in each segment of the truncated icosahedron.
•   The resulting detonation waves are intially convex in the faster explosives, Cyclonite, where the wavefronts are rearranged to become concave in the...
•   ...slower explosives, 31% TNT and 69% barium nitrate. The rearranged waves then converge into the...
•   ...inner layer of explosives, Cyclonite, forming a single spherical implosive shock-wave.
•   The unified wavefront then transfers the imploding shock-wave to the aluminium pusher and onto the depleted uranium tamper, which minimizes turbulence. The shock-wave then compresses the components within, passing through a...
•   ...boron-plastic shield intended to prevent stray neutrons causing a pre-detonation. The shock-wave then reaches the center of the device, where the...
•   ...pit of plutonium-239 (93%) and gallium alloy is compressed. A fission chain reaction then begins, where the fissioning pit starts to blow itself apart prematurely, which is curtailed by the inward momentum of the...
•   ...depleted uranium tamper. The tamper also reflects neutrons back into the pit, accelerating the unfolding chain reaction.

The device managed to achieve the fission of around 0.66 kg of the plutonium in the core, which equated to an efficiency of 10.6%. This would exceeded the projected yield considerably, as later radiochemical analysis of the site would indicate that the yield had been around 12 kilotons of TNT.

Subsequent tests

Weapons production complexes

Notes