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Market Items

Image Name EM Exp Kin The Market Price
Caldari Navy Antimatter Charge S
Consists of two components: a shell of titanium and a core of antimatter atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced optimal range.

    8.1 5.8 442
Caldari Navy Iridium Charge S
Consists of two components: a shell of titanium and a core of iridium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

20% increased optimal range.
24% reduced capacitor need.

    4.6 3.5 508
Caldari Navy Iron Charge S
Consists of two components: a shell of titanium and a core of iron atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

60% increased optimal range.
30% reduced capacitor need.

    3.5 2.3 481
Caldari Navy Lead Charge S
Consists of two components: a shell of titanium and a core of lead atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced capacitor need.

    5.8 3.5 398
Caldari Navy Plutonium Charge S
Consists of two components: a shell of titanium and a core of plutonium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

37.5% reduced optimal range.
5% reduced capacitor need.

    6.9 5.8 366
Caldari Navy Thorium Charge S
Consists of two components: a shell of titanium and a core of thorium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

12.5% reduced optimal range.
40% reduced capacitor need.

    5.8 4.6 522
Caldari Navy Tungsten Charge S
Consists of two components: a shell of titanium and a core of tungsten atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

40% increased optimal range.
27% reduced capacitor need.

    4.6 2.3 369
Caldari Navy Uranium Charge S
Consists of two components: a shell of titanium and a core of uranium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

25% reduced optimal range.
8% reduced capacitor need.

    6.9 4.6 548
Dread Guristas Antimatter Charge S
Consists of two components: a shell of titanium and a core of antimatter atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced optimal range.

    8.4 6.0 35.052
Dread Guristas Iridium Charge S
Consists of two components: a shell of titanium and a core of iridium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

20% increased optimal range.
24% reduced capacitor need.

    4.8 3.6 136
Dread Guristas Iron Charge S
Consists of two components: a shell of titanium and a core of iron atoms suspended in a plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

60% increased optimal range.
30% reduced capacitor need.

    3.6 2.4 30
Dread Guristas Lead Charge S
Consists of two components: a shell of titanium and a core of lead atoms suspended in a plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced capacitor need.

    6.0 3.6 159
Dread Guristas Plutonium Charge S
Consists of two components: a shell of titanium and a core of plutonium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

37.5% reduced optimal range.
5% reduced capacitor need.

    7.2 6.0 6.537
Dread Guristas Thorium Charge S
Consists of two components: a shell of titanium and a core of thorium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

12.5% reduced optimal range.
40% reduced capacitor need.

    6.0 4.8 117
Dread Guristas Tungsten Charge S
Consists of two components: a shell of titanium and a core of tungsten atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

40% increased optimal range.
27% reduced capacitor need.

    4.8 2.4 32
Dread Guristas Uranium Charge S
Consists of two components: a shell of titanium and a core of uranium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

25% reduced optimal range.
8% reduced capacitor need.

    7.2 4.8 719
Federation Navy Antimatter Charge S
Consists of two components: a shell of titanium and a core of antimatter atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced optimal range.

    8.1 5.8 449
Federation Navy Iridium Charge S
Consists of two components: a shell of titanium and a core of iridium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

20% increased optimal range.
24% reduced capacitor need.

    4.6 3.5 201
Federation Navy Iron Charge S
Consists of two components: a shell of titanium and a core of iron atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

60% increased optimal range.
30% reduced capacitor need.

    3.5 2.3 321
Federation Navy Lead Charge S
Consists of two components: a shell of titanium and a core of lead atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced capacitor need.

    5.8 3.5 230
Federation Navy Plutonium Charge S
Consists of two components: a shell of titanium and a core of plutonium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

37.5% reduced optimal range.
5% reduced capacitor need.

    6.9 5.8 330
Federation Navy Thorium Charge S
Consists of two components: a shell of titanium and a core of thorium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

12.5% reduced optimal range.
40% reduced capacitor need.

    5.8 4.6 712
Federation Navy Tungsten Charge S
Consists of two components: a shell of titanium and a core of tungsten atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

40% increased optimal range.
27% reduced capacitor need.

    4.6 2.3 399
Federation Navy Uranium Charge S
Consists of two components: a shell of titanium and a core of uranium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

25% reduced optimal range.
8% reduced capacitor need.

    6.9 4.6 89
Guardian Antimatter Charge S
Consists of two components: a shell of titanium and a core of antimatter atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced optimal range.

    8.4 6.0 27.600
Guardian Iridium Charge S
Consists of two components: a shell of titanium and a core of iridium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

20% increased optimal range.
24% reduced capacitor need.

    4.8 3.6 108
Guardian Iron Charge S
Consists of two components: a shell of titanium and a core of iron atoms suspended in a plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

60% increased optimal range.
30% reduced capacitor need.

    3.6 2.4 31
Guardian Lead Charge S
Consists of two components: a shell of titanium and a core of lead atoms suspended in a plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced capacitor need.

    6.0 3.6 349
Guardian Plutonium Charge S
Consists of two components: a shell of titanium and a core of plutonium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

37.5% reduced optimal range.
5% reduced capacitor need.

    7.2 6.0 793
Guardian Thorium Charge S
Consists of two components: a shell of titanium and a core of thorium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

12.5% reduced optimal range.
40% reduced capacitor need.

    6.0 4.8 604
Guardian Tungsten Charge S
Consists of two components: a shell of titanium and a core of tungsten atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

40% increased optimal range.
27% reduced capacitor need.

    4.8 2.4 38
Guardian Uranium Charge S
Consists of two components: a shell of titanium and a core of uranium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

25% reduced optimal range.
8% reduced capacitor need.

    7.2 4.8 1.134
Guristas Antimatter Charge S
Consists of two components: a shell of titanium and a core of antimatter atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced optimal range.

    7.7 5.5 928
Guristas Iridium Charge S
Consists of two components: a shell of titanium and a core of iridium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

20% increased optimal range.
24% reduced capacitor need.

    4.4 3.3 16
Guristas Iron Charge S
Consists of two components: a shell of titanium and a core of iron atoms suspended in a plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

60% increased optimal range.
30% reduced capacitor need.

    3.3 2.2 16
Guristas Lead Charge S
Consists of two components: a shell of titanium and a core of lead atoms suspended in a plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced capacitor need.

    5.5 3.3 6
Guristas Plutonium Charge S
Consists of two components: a shell of titanium and a core of plutonium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

37.5% reduced optimal range.
5% reduced capacitor need.

    6.6 5.5 133
Guristas Thorium Charge S
Consists of two components: a shell of titanium and a core of thorium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

12.5% reduced optimal range.
40% reduced capacitor need.

    5.5 4.4 0
Guristas Tungsten Charge S
Consists of two components: a shell of titanium and a core of tungsten atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

40% increased optimal range.
27% reduced capacitor need.

    4.4 2.2 4
Guristas Uranium Charge S
Consists of two components: a shell of titanium and a core of uranium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

25% reduced optimal range.
8% reduced capacitor need.

    6.6 4.4 29
Shadow Antimatter Charge S
Consists of two components: a shell of titanium and a core of antimatter atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced optimal range.

    7.7 5.5 1.738
Shadow Iridium Charge S
Consists of two components: a shell of titanium and a core of iridium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

20% increased optimal range.
24% reduced capacitor need.

    4.4 3.3 20
Shadow Iron Charge S
Consists of two components: a shell of titanium and a core of iron atoms suspended in a plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

60% increased optimal range.
30% reduced capacitor need.

    3.3 2.2 3
Shadow Lead Charge S
Consists of two components: a shell of titanium and a core of lead atoms suspended in a plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

50% reduced capacitor need.

    5.5 3.3 50
Shadow Plutonium Charge S
Consists of two components: a shell of titanium and a core of plutonium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

37.5% reduced optimal range.
5% reduced capacitor need.

    6.6 5.5 11
Shadow Thorium Charge S
Consists of two components: a shell of titanium and a core of thorium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

12.5% reduced optimal range.
40% reduced capacitor need.

    5.5 4.4 21
Shadow Tungsten Charge S
Consists of two components: a shell of titanium and a core of tungsten atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

40% increased optimal range.
27% reduced capacitor need.

    4.4 2.2 3
Shadow Uranium Charge S
Consists of two components: a shell of titanium and a core of uranium atoms suspended in plasma state. Railguns launch the shell directly, while particle blasters pump the plasma into a cyclotron and process the plasma into a bolt that is then fired.

25% reduced optimal range.
8% reduced capacitor need.

    6.6 4.4 19


Database: Invasion 2 (2019-11-26)

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