I love Yellowcake

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 2; An Additional Order of 20kt has been placed, at low priority and will be manufactured at 75-76.6% at a slow rate to keep it cheap. Blind River will take this order.
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 90%
Candle Lake;
Order 1; An Additional Order of 50kt/TNT of 85-90% U²³⁵ has been placed, Candle Lake and Port Hope will both complete 25kt Each.
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 60%
Port Hope;
Order 1; An Additional Order of 50kt/TNT of 85-90% U²³⁵ has been placed, Candle Lake and Port Hope will both complete 25kt Each.
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 60%

Pickering; 40kt/TNT of Pu²³⁹have been ordered by the AWC - Approved by the IAUE
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 100%

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 10%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 0%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 10%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 0%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 10%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 0%

Pickering; Second Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 20%

Current Stockpile;
U²³⁵ Enrichment Levels;
75-76.6% = 20kt
85-90% = 50kt

Pu²³⁹ Enrichment Levels;
3.5% = 40kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 15%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 0%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 20%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 5%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 20%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 5%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering; Second Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 40%

Current Stockpile;
U²³⁵ Enrichment Levels;
75-76.6% = 20kt
85-90% = 50kt

Pu²³⁹ Enrichment Levels;
3.5% = 40kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 20%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 5%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 30%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 10%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 30%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 10%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering; Second Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 50%

Current Stockpile;
U²³⁵ Enrichment Levels;
75-76.6% = 20kt
85-90% = 50kt

Pu²³⁹ Enrichment Levels;
3.5% = 40kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 30%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 10%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 40%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 20%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 40%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 20%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering; Second Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 70%

Current Stockpile;
U²³⁵ Enrichment Levels;
75-76.6% = 20kt
85-90% = 50kt

Pu²³⁹ Enrichment Levels;
3.5% = 40kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 40%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 20%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 50%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 30%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 50%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 30%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering; Second Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 80%

Current Stockpile;
U²³⁵ Enrichment Levels;
75-76.6% = 0kt/ 20kt (Exported)
85-90% = 50kt

Pu²³⁹ Enrichment Levels;
3.5% = 40kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 70%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 55%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 80%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 60%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 80%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 60%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering; Second Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 100%

Third Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 10%

Current Stockpile;
U²³⁵ Enrichment Levels;
75-76.6% = 0kt/ 20kt (Exported)
85-90% = 50kt

Pu²³⁹ Enrichment Levels;
3.5% = 80kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 90%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 60%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 80%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 80%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering;Third Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 25%

Current Stockpile;
U²³⁵ Enrichment Levels;
85-90% = 50kt

Pu²³⁹ Enrichment Levels;
3.5% = 80kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 80%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 100%
Order 2; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 10%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 0%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 100%
Order 2; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 10%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 0%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering;Third Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 50%

Current Stockpile;
U²³⁵ Enrichment Levels;
85-90% = 100kt

Pu²³⁹ Enrichment Levels;
3.5% = 80kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 100%
Order 2; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 10%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 0%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 30%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 10%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 30%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 10%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering;Third Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 75%

Current Stockpile;
U²³⁵ Enrichment Levels;
90-95% = 25kt
85-90% = 100kt

Pu²³⁹ Enrichment Levels;
3.5% = 80kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 60%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 50%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 70%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 60%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 70%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 60%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering;Third Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 100%
Fourth Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 30%

Current Stockpile;
U²³⁵ Enrichment Levels;
90-95% = 25kt
85-90% = 100kt

Pu²³⁹ Enrichment Levels;
3.5% = 120kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 90%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 80%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 90%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 90%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering;
Fourth Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 90%

Current Stockpile;
U²³⁵ Enrichment Levels;
90-95% = 25kt
85-90% = 100kt

Pu²³⁹ Enrichment Levels;
3.5% = 120kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 1; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 100%
Order 2; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 20%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 10%
Candle Lake;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 100%
Order 2; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 40%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 20%
Port Hope;
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 100%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 100%
Order 2; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 40%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 20%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering;
Fourth Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 100%
Fifth Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 20%

Current Stockpile;
U²³⁵ Enrichment Levels;
90-95% = 50kt
85-90% = 150kt

Pu²³⁹ Enrichment Levels;
3.5% = 160kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River;
Order 2; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 40%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 20%
Candle Lake;
Order 2; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 60%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 40%
Port Hope;
Order 2; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 60%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 40%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering;
Fifth Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 40%

Current Stockpile;
U²³⁵ Enrichment Levels;
90-95% = 50kt
85-90% = 150kt

Pu²³⁹ Enrichment Levels;
3.5% = 160kt

[English Channel Union]

Work will continue at all three plants, first they will take the U₃O₈ "Yellowcake" and dissolve it into Nitric Acid, this would result in a Uranyl Nitrate UO₂(NO₃)₂. This step is followed by extracting pure uranyl nitrate by solvent extraction with a treatment of ammonia to produce Ammonium Diuranate (NH₄)₂U₂O₇, followed by a reduction by hydrogen, producing UO₂, this is converted with Hydrofluoric Acid to make Uranium Tetrafluoride UF₄. Finally, through an Oxidation process, they will produce the UF₆ Uranium Hexafluoride which will be used in the Enrichment Process to obtain U²³⁵.

The plant will continue to cycle the completed UF₆ through the Gas Centrifuge, and the UF₆ will be placed into a cylinder amongst others that will rotate with a heat applied to the cylinder. Through the centrifugal force the heavier gas molecules containing U²³⁸ will move toward the outside of the cylinder while the lighter gasses enriched with U²³⁵ will collect closer to the center, of the addition of Heat will also cause some of the Heavier gasses to sink while the Lighter U²³⁵ will rise to the top allowing for easier extraction, once completed teams will extract the U²³⁵ from the center while the waste U²³⁸ is sent for processing to be used in Nuclear Facilities to create Pu²³⁹.

Blind River:
Order 2; An Additional Order of 25kt/TNT of 90-95% U²³⁵
U₃O₈ > UF₆ = 60%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 35%
Candle Lake:
Order 2; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 80%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 60%
Port Hope:
Order 2; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 80%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 60%
Cobourg: NEW
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 20%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 0%
Little Black River: NEW
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 20%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 0%
Silver Harbour: NEW
Order 1; An Additional Order of 25kt/TNT of 85-90% U²³⁵
U₃O₈ > UF₆ = 20%
UF₆ > Gas Extraction Process > 90% U²³⁵ = 0%

The Pickering Nuclear Station will continue refining the specified amount of Pu²³⁹ by placing Natural Uranium into its reactor core and allowing the neutrons to interact, once a U²³⁵ atom is fissioned it will release 3 neutrons which can be absorbed by U²³⁸ to produce Pu²³⁹. Reactor rods will be changed frequently to extract the 3.5% WG Pu²³⁹.

Pickering;
Fifth Order of 40kt/TNT of Pu²³⁹
Fission Process U²³⁵ > U²³⁸ > Pu²³⁹ = 60%

Current Stockpile;
U²³⁵ Enrichment Levels;
90-95% = 50kt
85-90% = 150kt

Pu²³⁹ Enrichment Levels;
3.5% = 160kt