Ordnance is a section of the Research and Development section of the ship. There was a time when being in this place was basically a dead giveaway that you were a bad guy, but with the advent of Research bombs and Ordnance Technicians, this is no longer the case. Instead, being a robust bomb-maker will get you praise and applause as the crew realizes you used all the bombmix to complete difficult research experiments and get a lot of credits for the department's research budget rather than using it to turn the ship into a crater-ridden deathtrap, or provided it to the Ordnance Technician so he can help make other ships into crater-ridden deathtraps! Hooray Science!

There are a few items that you will need to grab or at least keep track of.

Ordnance is located within the Research Division and is the home of bomb construction with the lab on the left, a passageway in the middle and the observation room on the right.

• Rapid Pipe Dispenser: The rapid pipe dispenser can be found in the ordnance lab. You will need it to retool the pipe setup.
• Analyzer: The analyzer will tell you what is going on with canisters, pipes, the environment, simply Left Click with it on your hand on things to examine them and Press Z or Click the analyzer itself to examine the air around you. Right click the analyzer icon to open the gas and reaction reference.
• Tablet or Modular Computer: We will need them to publish papers and read up on the experiments we are about to do. Make sure you have one nearby.
• Holofans: Some ships start with the luxury of having the Atmos Holofan in the ordnance lab. You can use it to retool the freezer chamber if you want. Simply Click on a tile with it in-hand to generate a barrier that will let you go through but not air and heat.
• Tools: Pipes are reconfigured using tools, you might want to keep a toolbox nearby or have the tools inside your backpack by Click-dragging the toolbox into your backpack. In particular you will use the Wrench.png wrench the most to unwrench and fasten pipes.
• Plasma Tanks: In ordnance, tanks are the objects that actually produce explosions from being overpressurized. However you cannot overpressurize a tank easily by pumping them with regular pumps, which is where ordnance comes in.
• Tank Transfer Valve (TTV): The TTV allows you to combine the contents of two tanks together. This will be the thing you need to make large bombs.

• Tank Compressor: The gas compressor is where you do the Gas shell experiments. They, unlike regular blue pumps, does not have a pressure limit and will allow you to overpressurize a tank very easily.
• Anomaly Refinery: Anomaly refinery allows you to insert Tank Transfer Valves into them to compress Anomaly Cores. They are also equipped with a simulation feature for you to test out bombs without actually losing them, but NovusCorp requires doppler array data to validate an experiment.
• Tachyon Doppler Array: The tachyon doppler array is a directional device that allows the recording of real explosions. If those explosions happen to be caused by tanks, they can provide insight on the possible causes.

• Portable scrubbers and portable pumps are often used to clean or fill a tank.
• Thermomachines are also used very often to cool down or heat up a gas.
• Lastly, canisters store gas and will also be used to contain exotic or very hot gas.

To complete experiments, as well as to acquire funding and scientific cooperation, you require the NC Frontier application. This can be downloaded on your department's civilian console, or a device like a laptop or tablet.

To do this, you need to:

• Grab your ID and insert them into a tablet or a modular computer.
• Open the NT Software Hub application and look for the program NC Frontier. It is in the Science tab if you didn't find it. Press download and wait for it to finish.
• The application will helpfully list all available experiments as well as their tier requirements. Do note that for experiments which unlock research nodes upon completion, it is not required to reach the maximum tier. However you should endeavor to do so, as you will otherwise earn less funding and cooperation. Do note that you can only publish one paper per experiment and tier. So you cannot re-do the same tier later on to gain more rewards if you publish a worse result early.

In order to publish papers, the relevant file must be on your phone's internal storage. To do this you will need to:

• Complete the appropriate experiment in the Tachyon-Doppler Array or Tank Gas Compressor.
• Grab a Portable Hard Drive.pngportable hard drive (data disk). These should by lying around near a computer or a doppler array.
• Insert the data disk into the Tachyon-Doppler Array or Tank Gas Compressor and print the experiment to the disk.
• Stick the disk into your phone or computer and use the File Manager software to copy the file from the disk to the phone.
• Now you will be able to select the experiment in NT Frontier and publish your paper!

Other than funding, publishing papers earns scientific cooperation with the partner you select when publishing the papers. In the partner's overview tab, you can see your relations with each partner. Good relations allow you to purchase discounts on research nodes, which will however degrade the relations.

The station is in chaos; a cruel wizard has kidnapped the captain and holds him hostage. He will accept bombs as ransom, and you are the only scientist on deck. We got you covered!

Ordnance is about making gas, either for bombs or for gas shells. You can read up on all the gas reactions in the game here.

If you are just starting out, you are recommended to make BZ first, then Tritium, before moving on to the harder gases like Hyper-Noblium.

BZ requires N2O and Plasma in a low pressure environment to produce. To use this you can use the freezer chamber to both cool down the reactants (drives the pressure down) and to give a larger area for the reaction to occur (also drives the pressure down).

Wrench the plasma canister in to the first mixer port. Set the first mixer to 100% Side Node.

Why: As stated above, one of the ingredients for BZ is Plasma. For the mixer, they are supposed to mix two inputs, but in this case we do not need the oxygen at all so we can route all of the plasma in.

Wrench the N2O canister in to the second mixer port. Set the second mixer to 66.67% Main Node 33.33% Side Node.

Why: As stated above, one of the ingredients for BZ is N2O. The ratio is 66.67% to 33.33% to keep the input and consumption the same. Other ratios might cause gas buildup inside the chamber.

Open the valve connecting the Mix Line with the Freezer line.

Why: This will redirect our mixed gas to the freezer chamber.

Wrench a plasma canister into the freezer port. Turn the thermomachine on and minimize the target temperature.

Why: The heat exchangers on the freezer turf will need gas to start exchanging heat; Plasma is an exceptional coolant since it absorbs a lot of heat.

Open the air alarm and look for the scrubber inside the freezer chamber (match the id). Set it to expanded mode and to scrub BZ.

Why: This will allow us to collect the BZ as they are formed in the chamber.

Wrench a canister or a portable pump in the output port.

Why: The BZ collected by the chamber will be deposited to the canister or portable pump. The former is more readily available while the latter allows you to do gas shells very precisely.

Look for the Chamber Monitor, navigate to the Freezer Chamber selection, and in this order: Lower the injector to 1 L/S, and turn it on.

Why: This will be the final step that allows our reactants to go inside the chamber. You might be able to optimize it even further by adjusting the input rate up and down as time passes. Aim for somewhere below 50 kPa.

If you overpressurized the gas inside the freeze chamber, you might want to:

• Disconnect the output canister.
• Set the scrubber to siphoning in the Air Alarm.
• Turn on the bypass volume pump.
• Though this may not always work, such as when the input line is already at maximum pressure. You can then change the normal gas pump to a volume pump.

Tritium is still relatively simple to grasp, but it is prone to failure which can render your workplace hazardous to work in. Don't lose hope if you fail, even experienced players make mistakes.

The production of tritium requires the combustion of plasma inside a heavily oxygenated environment. Tritium also combusts relatively rapidly with oxygen, which means you will need to upgrade the scrubber network to get sizable amounts of it. This guide will assume that you do not have the means to do that.

Set the first and second mixer to 100% Main Node.

Why: We require oxygen in the chamber, this setting will fully pump the oxygen in.

Open the valve connecting the Mix Line (yellow) with the Burn Line (black)

Why: This will route the oxygen into the chamber.

Open the air alarm and look for the scrubber inside the burn chamber. Set it to expanded mode and to scrub only Tritium.

Why: The first one will allow us to clear the yellow/black line quicker, while the second one will let less tritium burn.

Click the chamber control panel, and open the interior airlock. Wait for it to cycle. Then enter the outer part of the chamber and maximize the pump leading in and pump leading out.

Why: Maximizing the first pump will allow tritium to be produced more quickly, while the second one will let less tritium burn.

Open the Atmos Monitor, switch the chamber to the Burn Chamber if it isn't already set. turn on the injector and maximize it. Oxygen should be showing up in the sensor.

Why: The black line is where our oxygen is currently residing, but the injector starts off. So we need to turn it on first.

Head back down to the Oxygen Stationary Tanks, use your analyzer on them and turn the first mixer off (Ctrl-Click) once you are satisfied with how much oxygen is in the chamber.

Why: However much gas you leave in the tanks is completely optional. Keeping a reserve of around 2-3k (around 1-2 canisters) might be a good idea in case you decided to pursue another experiment that needs oxygen. Wait for the black and yellow line to empty out and turn the injector off with the Atmostankcontrol.png Atmos Monitor. The monitor should read around 1-2k moles of oxygen.

Why: We will need the plasma to be trickled in slowly, turning the injector off first will give us ample time to prepare the plasma.

Wrench a plasma canister in to the first mixer side port. Set the Side Node to 100% and turn it on.

Why: We are now ready to route the plasma into the chamber. The black and yellow line should be filling up with unadulterated plasma.

Activate the burn button. Make sure you don't press the vent button.

Why: This button will trigger the igniter in the chamber and allow the plasma to ignite.

Head back to the Atmos Monitor and start trickling the plasma. Start with a small number, turn the injector on, and keep adding the rate slowly until the temperature is above 1.7k Kelvins. You are free to increase or decrease the rate afterwards.

Why: Tritium is made when there are around 100x as much oxygen as plasma, we trickle the plasma slowly so this ratio is maintained. We also aim for the temperature to be above 1.7k Kelvins because the oxygen consumption is most efficient at that temperature. Higher rates mean more tritium made per second, but it also means a higher burden on your cooling system.

If all goes well, tritium should be made and collected by the scrubber. Go to the freezer and crank the temperature down. You should wait a bit and then wrench a canister or a portable pump to the output connector port when finished.

Why: The canister is withheld because wrenching it means a smaller volumetric share for the freezer. Rather than being (200L / Pipe volume), the gas that the freezer can cool directly becomes (200 L / (Pipe volume + Canister volume)).

In most cases, you will need to add more scrubbers to the chamber. You should do this before adding anything to the chamber. To do this simply:

• Grab a firesuit and fire helmet from a Fire Closet, wear them.
• Equip and activate internals.
• Use the door control and open the interior airlock. Wait for it to cycle and then enter it.
• Open the exterior airlock by interfacing with the same console again.
• Unwrench either the scrubber line pump or pipe and replace them with a layer manifold of a suitable color.
• Add four more scrubbers to the chamber. You will most likely need to do this in another layer, feel free to choose any.
• Go out by using the airlock panel once again. Wait for it to cycle.

For reactionless explosions and tritium bombs, we will need a heat mixture. Thermomachine does the job but not very well.

Collecting the results of a burn chamber is quicker more often than not, but is very time sensitive and tends to result in a mix with lower temperature than this method.

Prepare a gas mixer contraption.

Why: We are preparing a burn canister for the heat.

Wrench a plasma can on the main node.

Why: A burn mix needs plasma as the fuel.

Wrench an oxygen can on the side node.

Why: And oxygen as the oxidizer.

Wrench an empty canister on the output node.

Why: We will heat the plasma and oxygen up inside a canister so the heat is contained inside and not lost to environment like in chamber burns.

Pump in a 60-40 mix of plasma/oxygen with the mixer. Main node to 60, side node to 40.

Why: This is just one recipe, feel free to experiment and use another one.

Unwrench and hook the resulting canister up to a thermomachine. Turn shielding on.

Why: The heat will exceed the 10 K Kelvin limit allotted to canisters. Without shielding it will melt.

Set the thermomachine to maximum temperature and unwrench the canister once you are satisfied with the starting temperature (it will get hotter).

Why: Get a higher temperature for better starting efficiency if you can, but anything above 100 Celsius works fine.

Prepare a heat pump contraption.

Why: Simple heat is not enough, we need to have the heat stored in a very dense format (plasma).

Wrench a plasma canister to the output node, unwrench it.

Why: A whole plasma canister is too much! We only need a few moles to fully fill a tank. Less plasma also means less heat capacity which means higher temperature.

Wrench a new canister at the output node. Turn shielding on.

Why: This will allow us to only heat the moles left in the heat pump instead of the whole plasma canister. Shielding once again for temperature protection.

Wrench the previous burn canister into the input node of the temperature pump once you are satisfied with the temperature.

Why: Canisters stop reacting when wrenched. So make sure the temperature is high enough before you transfer the heat from the burn mix to the plasma mix.

Turn on the heat pump. Maximize it.

Why: This will actually transfer the heat from the old canister to the new one, compacting the energy stored to a higher specific heat.

Grab a plasma tank from a tank dispenser, empty it with a portable scrubber.

Why: We will put the hot plasma into this tank so it can be attached to the TTV. Best make sure its empty first so cold plasma doesn't equalize with the hot one, making an at best lukewarm tank.

Insert the tank into the canister, crank the pressure up, open the valve. In that order.

Why: This will fill the tank with the necessary plasma. We are finally done.

Do a last check on the tank using an analyzer. There should be a hot (20k Kelvins +) mixture of pure plasma in the tank, with the pressure reading 2533 kPa.

Why: If you mess up, best know why and where exactly.

Before playing with bombs directly, you are recommended to try out gas shells first. They are far less punishing and final than a proper bomb test.

To do gas shell experiments, you will need to visit the tank compressor. The tank compressor in essence is an overgrown pump. It is mainly used to burst tanks with exotic contents inside, letting it spew into the collection chamber to be evaluated.

The tank will then either spring a leak or explode, both of which will be contained by the machine. In case of a leak, it's advised to wait for the tank to empty before removing it from the machine. In case of an explosion, all of the gas content will be outputted to the collection chamber.

Upon a succesful ejection or detonation, the collection chamber's gas data will be finalized and recorded into an experiment file. A printable experiment is then available to be printed into a data disk. Gas in the chamber will also be flushed into the output port.

To properly use this contraption, there are two courses of action you can take:

Overpressurize a tank with the experiment gas

Pros: Very quick to do.

Cons: Difficult to clean the input port up, less control.

Prefill a tank with the experiment gas, overpressurize it with another gas in the compressor.

Pros: Easier to clean the input port up, more control over the number of moles.

Cons: Takes a bit more time, requires a portable pump in most cases.

To do the former, simply:

Prepare an empty (or default) tank from the tank dispenser. Insert it into the Tank Compressor.png tank compressor.

Wrench the portable pump / canister filled with the experiment gas (preferably cooled) to the input port (green pipe) connector of the tank compressor.

Maximize the input rate and activate the compressor using the UI (left click the machine)

Set the filter to filter only the experiment gas and turn it on.

Move the original canister/pump with the experiment gas to the side node of the filter.

To do the latter,

Prepare an empty (has to be empty) tank from the Tank Dispenser.png tank dispenser. Empty it with the portable scrubber.

Prepare a portable pump (canister is not recommended here) filled with the experiment gas (preferably cooled).

Put the empty tank in the portable pump, pump until the mole number you want is reached.

P = nRT/V

n being the mole that you want (preferably the target mole in the NT Frontier), R being the ideal gas constant (8.31), T being the temperature of the portable pump, V being tank volume (70L), and P being the pressure that you want to set in the portable pump. Eyeballing this however, is also perfectly fine.

Insert the filled tank into the tank compressor.

Grab a canister of gas that doesn't react with the experiment gas from the gas storage (Nitrogen tends to be rather stable and thus is recommended).

Wrench the new canister into the input port, turn on the compressor and maximize it.

Set the filter to filter only the experiment gas and turn it on.

Move the original pump with the experiment gas to the side node of the filter.

Try and pay attention to the pressure at which tanks leaks or explodes, we might revisit this concept again later.

Useful knowledge: Heat capacity, pressure

A TTV does not explode on its own: it only connects two tanks. The tanks themselves explode.

The explosion depends entirely on how high the pressure is able to rise inside a tank before it destroys itself or leaks out. There are two main ways to do this:

Reactionless explosions are more often than not the easiest to produce. They work by letting a hot gas mixture heat up another gas mixture.

In order to do this effectively, we need to do two things:

• Put as much energy as possible to the system.
• The more energy we can fit into the first tank, the bigger the explosion.
• Make the resultant gas mixture extremely easy to heat up while packing as many moles as possible, I.E. low resultant specific heat capacity.
• The lower we can push the resultant gas mixture down, the bigger the explosion.

We need a hot gas with high specific heat capacity, and a cold gas with low heat capacity. The former will give more energy, while the latter will drive the resultant heat capacity down and allow more moles to be involved.

The easiest gas to obtain with a reasonably high heat capacity is Plasma. The easiest gas to obtain with a reasonably low heat capacity is Nitrogen or Oxygen. Oxygen also burns with plasma, further adding to its pressure.

Procure both canisters and heat the plasma and cool the nitrogen/oxygen using a thermomachine. Simply wrench the canisters to the connector port and adjust the thermomachine directly.

If a thermomachine is not available. you may relocate a thermomachine from the ordnance chambers or build a new one.

To do the former, screwdriver the thermomachine, and right-click with a wrench to unwrench it. Left-click with a wrench to rotate it if necessary.

To do the latter, build a machine frame, procure the circuit and necessary components, and build the thermomachine.

You can flush a thermomachine's air contents by reconstructing it too!

After you procured the thermomachine, connect a connector port to its input node using a RPD.

Another method to make explosions is to have exothermic reactions occur inside them. The reactions will drive the temperature up, which in turn drives the pressure up, causing an explosion.

To generate very big theoretical explosions, you will need reactions, especially the very energetic ones like Tritium Combustion and Hyper-Noblium Formation. Both requires tritium which you should already have; if you don't, read up.

Tritium combustion have several main properties. Upon the opening of a valve, the tanks will allow exactly two reaction ticks before exploding. We also know that tritium combustion:

• Needs to happen above 100 Celsius.
• Needs more oxygen than tritium to be energetic.
• Consumes ten times as much oxygen than tritium burnt.
• Burns 10% of the tritium every tick.

Factor three and four means the number of oxygen burnt each tick is the same as the number of tritium available. All of these factors have led the 67-33 mix to be extremely popular, due to the unique interaction between the reaction ticks and the properties of the tritium burn itself.

In essence, the 67-33 mix is a mix which contains twice as much Oxygen as Tritium, allowing the energetic burn to happen twice, with as high reaction rate as one can get.

The first tick will consume half of the oxygen and ten percent of the tritium. Paving the way for the second tick to also be energetic.

The second tick will consume the rest of the oxygen, ending the energetic phase but also hitting the threshold for reactions available. Letting us make the biggest, baddest bomb possible.

A lower temperature for the tritium-oxygen mix means a higher reaction rate for the two ticks that are allotted to us, but also means a higher energy requirement to exceed the 100 Celsius threshold for the reaction to occur. Keep this in mind when you are upgrading your mix.

We want a 66.67 - 33.33 mix of Oxygen and Tritium (in that order) in the payload tank. Always err in the side of oxygen. More oxygen will just mean a lower payload but more tritium will mean the second tick never occurs, gimping your mix.

A very common temperature to aim for is 43 Kelvins at 2533 kPa, which requires a hot plasma mix of around 800 Kelvins to heat the resultant up to 373.15 Kelvins. A hotter plasma mix is very often desirable here, since hotter plasma means a lower resultant heat capacity, which means a larger temperature increase, which means a larger explosion.

If you wish to follow this recipe, for the cold tank simply:

• Pump up to 850 kPa of 43.15 Kelvin tritium into a tank.
• Pump up to 2533 kPa of 43.15 Kelvin oxygen into a tank.
• Analyze the resulting tank and make sure oxygen is above 65.52%
• (Note that those of you who did the math might notice that 850 kPa is more than 1/3rd of 2533kPa, well, this is because after accounting for the 10% of the tritium that is burnt off in the first tick, the actual limiting ratio is 10:19 tritium to oxygen, which corresponds to 34.48% tritium and 65.52% oxygen, so the 850:2533 mix works)

Hyper-Noblium bombs are made using their formation reaction, which when unmoderated by BZ releases a lot of energy. This formation involves Nitrogen and also Tritium.

There are a few notable properties about this reaction:

• Can only occur below 15 Kelvins
• Consumes nitrogen at twice the rate of tritium. Moderated by BZ but we will not include BZ in this mix at all so it's safe to ignore.
• The consumption rate for Nitrogen is equal to 10% of the pooled Nitrogen + Tritium mole count. Tritium consumption is half of this.
• Since this reaction occurs on very low temperatures and is incredibly exothermic, it will only happen on one tick. This means we will need to make the first tick occur with as much reaction rate as we can.

If we pay attention to how the reaction rate works with the mole consumption, we can see that we will not need to fill the payload with 50% Tritium as this is incredibly wasteful. It is possible to pad out the reaction with Nitrogen to drive the reaction rate high enough so that all of our tritium is consumed, netting us the most tritium-efficient Hyper-Nob burn possible.

This ratio works out to be 95-5 Nitrogen-Tritium. The burn will consume Nitrogen equal to 10% of the total mole count and more importantly Tritium equal to 5% of the total mole count, leaving us with a full Tritium consumption. Most of the Nitrogen will be left unreacted, but the station has an abundance of Nitrogen so it should be relatively easy to replenish it.

For this, we will need a significant amount of cooled Nitrogen and also Tritium.png Tritium.

Nitrogen is already available, so grab a canister from the gas storage and cool it down to below 15 Kelvins on an upgraded freezer (Tier 3 parts or better).

Tritium on the other hand needs to be made first, so read up on Tritium Synthesis if you haven't. You will also need to cool it down to below 15 Kelvin using an upgraded freezer.

Optional: A padding gas like Carbon Dioxide or Oxygen can also be used to have more moles in the mix and thus more pressure once the bomb reacts, producing a bigger explosion. Just make sure they are also cooled to below 15 Kelvins or else they might make the resultant gas mixture too hot to react.

The target mixture is 95-5 Nitrogen-Tritium, we cannot combine both of them inside a tank like in the tritium bomb cold mix, since they will start reacting and explode. So we need to put them in separate tanks. To do this simply:

Pump up to 2533 kPa of 13 Kelvin Nitrogen to a tank.

Pump up to 127 kPa of 13 Kelvin Tritium to another tank.

(Optional) Brim the Tritium tank with 13 Kelvin Carbon Dioxide or Oxygen.

Analyzer both of the tanks and make sure both of them are below 15 Kelvins and the Nitrogen mole count is about 19 times the Tritium.

Extra note: Unlike the tritium burn reaction, messing up the mole count and the ratio of this mixture is not as debilitating. Your bomb might still be able to explode even if you have a little too much Nitrogen or Tritium, as long as the temperature is below 15 Kelvins.

So you made your mix and are here to test it? Great. Lets get you started.

Screwdriver your desired assembly to loosen it, and with it in hand hit the TTV. If you need to adjust it afterwards simply use the TTV in hand and press the gear button in the UI.

There are two primary methods for detonating bombs remotely and safely, namely the timer and the remote signaling device.

The timer is self explanatory. It will detonate the TTV after a certain time has passed. You can start the countdown by using the aforementioned gear button.

The remote signaling device will open the valve once a signal with a matching frequency and code is sent. Attach one to your TTV, adjust the frequency and/or code, send the bomb to the Testing Area, and with another signaler send the matching combination.

Some jokers like to randomly signal the default frequencies of these devices so before you attach one to a bomb you'll want to change the frequency and/or code so that you don't get a nasty surprise.

To attach the tanks, hit the TTV with it in hand. If you need to detach it afterwards simply use the TTV in hand and press the eject button in the UI.

It might be a good idea to deal with the assemblies first before attaching the tanks to prevent accidental detonations.

It is possible to test your bomb without actually losing it by fitting a finished bomb inside an implosion compressor / anomaly refinery and using the Run Simulations tab in that machine.

If you are new or unsure about a particular bomb mix, it is recommended to always use an analyzer on the cold and hot tanks before blowing them up. If you are asking for help from other people the information here will be crucial, and if you are already experienced you will immediately know why a bomb went dud.

The doppler array is able to capture explosions directly in front of it (indicated by the red light). If the source of the explosion is a tank, it will provide possible causes. These causal data are used to publish papers.

To safely detonate a tank and capture it, you will need to head to the Ordnance Launch Site, put the TTV in the Mass Driver chamber and interface with the control button.

It might be useful to double check your doppler array to make sure it is on. Explosions that occur when the doppler array is off will not be recorded and will be wasted!

You can initiate a launch or open the door and test fire immediately for faster payload delivery. Once the TTV is in the bomb range and fully detonated (read the previous section for information on how to detonate your bomb), insert the data disk into the doppler array and print it.

The requirement for the experiments can be read on NC Frontier, complete with available tiers and the target amount for them. Remember that the target amount only refers to the optimal explosion range for the experiment, not the minimum amount! If your range is too low from the target amount however, the experiment may not be published.

That funny-looking box in the ordnance launch room does more than just sit around. It's the main way of getting anomaly cores.

What's an anomaly core?

Anomaly cores are essentially an item used to give functionality to several high-end research items, and can be obtained in one of two ways:

Defusing Anomalies with an analyzer and signaler, or with an Anomaly Neutralizer.

Buying raw cores from Cargo or using the random ones ordnance spawns with, and activating them in the Anomaly Refinery.

The refinery will first take the raw core, then accept a TTV with two tanks attached. If the mixture of the two tanks would have provoked a blast that fulfills its requirements, the refinery will rock the station with an equivalent effect of the actual blast, and the raw core will be spit out as a proper, activated core. You'll also get your TTV back, likely with one of the tanks gone. It's that easy!

Refining more cores will increase the needed blast radius, from 4 light tiles up to 20 light tiles, with increments of 2 per core.

Seriously, don't go and randomly set bombs onboard the ship if you aren't a syndicate or otherwise an antagonistic character; you WILL get job-banned or even permabanned.

If you manage to accidentally blow up or burn down ordnance and maybe even the surrounding Research department once or twice as a beginner, don't panic and just explain what happened to the admins who will likely contact you. They're usually an understanding bunch and know that mistakes happen. Just make sure to learn from them!

On the other hand, if you DO know what you're doing, the potential damage you can cause to the station can be extreme and sometimes irreversible, very likely changing the course of the round. There are VERY few instances where you can use these bombs as a weapon while being a normal non-antagonist crew member, and even when faced with a situation where it could be used to save the station, use it only as a last resort.

As an Ordnance Technician you have the necessary skills for crafting custom demolitions (chembombs) to improve the ship's arsenal, in addition to access to the Ordnance Research area for tank payloads to load into missiles and TTV payloads to load into torpedoes. The types of bombs you can make range from small / large grenades, mines, plastic explosives, warheads for rockets / mortar shells, and payloads for missiles and torpedoes. All of these follow a similar pattern of construction: printing the necessary casing from the armylathe, adding a detonator assembly, adding containers with chemicals up to the casing's volume, and locking the bomb to finish. With the right combination of chemicals, they can all be made significantly stronger than their standard issue counterparts. Alt-clicking an explosive casing or a warhead toggles the blast dampening. Clicking on a reagent container or a assembly with a casing or warhead will insert it.

Chemical explosives all have a minimum falloff of 25.

Warhead 14062 metal (3.7 sheets)
Tube 9375 metal (2.5 sheets) | 180 | Power: 300
Base Falloff: 120
Shards: 64 | Intensity: 4-30
Radius: 2-7
Duration: 5-36 |

(Add missile and torpedo assemblies.)

Detonation assemblies can be made by mixing the components below in various ways. The components has two possible states: locked or ready for attachment. Use a screwdriver to switch between the states. When locked, you can use the assembly to change the settings of any sensors inside. The assembly must be locked to attach it to a bomb.

Most assemblies have a blast dampening feature which, when activated causes the explosion's falloff to become exponentially higher the further away it is from the explosion. This is used for example, When you have a rocket with high explosive power, You would want the explosion to be devastating but don't want it to kill the user, so enabling wave dampening will cause the explosion to completely disappear or be negligible if fired from even a relatively close distance.

Ordnance Technicians are not chemists and can not make medicine. But they are familiar enough with chemistry to know how to make things go bang. Beware that some chemicals can be sensitive, spontaneously igniting when more than a certain amount is mixed at the same time (! = 60u, !! = 5u, !!! 0u). If research has been making custom explosive chemicals for you, then they will always have some sensitivity. Make sure they tell you about this. Below is a chart for all the chemical reactions you need to know. And a list of all chemicals that can be used in explosions and fire, and how they modify said explosions and fire. Additionally, iron can be used to make shrapnel and phoron can be used to make incendiary shrapnel.

Code Name Rarity Effect OD Crit OD EXP Explosive COMMON <POTENCY> explosion power mod. -3/<POTENCY> explosion falloff mod.

N/A N/A FLW Flowing COMMON -0,05*<POTENCY> fire intensity mod. -0,05*<POTENCY> fire duration mod. 0,05*<POTENCY> fire radius mod.

N/A N/A FUL Fueling COMMON -0,1*<POTENCY> fire intensity mod. 0,2*<POTENCY> fire duration mod. 0,01*<POTENCY> fire radius mod.

N/A N/A OXI Oxidizing COMMON 0,2*<POTENCY> fire intensity mod. -0,1*<POTENCY> fire duration mod. -0,01*<POTENCY> fire radius mod.

N/A N/A Name Power Mod Falloff Mod Intensity Mod Radius Mod Duration Mod Burn Color Mod Ammonium Nitrate 0.4 1.5 0.5 0 -0.2 Orange ANFO 1 -0.6 0 0 0 None Carbon 0 0 0 0 1 Gold Chlorine Trifluoride 0 0 1.6 -0.08 -0.8 Dark Orange Copper 0 0 0 0 0 Green Cyclonite 1.5 -0.4 0 0 0 None Ethanol 0 0 0.2 0.1 0.2 Blue Hexamine 0 0 0 0 0.5 Orange Hydrogen 0.15 0 -0.5 0.2 -0.5 Light cyan Lithium 0 0 0.15 0 0 Deep pink Methane 0.15 0 -0.35 0.1 0.25 Dark blue Napalm 0 0 0.45 0.06 0.75 Light orange Nitroglycerin 1 -0.5 0 0 0 None Octogen 2 -0.2 0.4 -0.02 -0.2 Orange Oxygen 0 0 0.75 -0.08 0 Light Blue Phoron 0 0 0.4 0.05 -0.75 Dark red Phosphorus 0 0 1 -0.12 0.1 Peach Potassium-chloride 0 0 0.1 0 0 Purple Potassium-hydroxide 0.5 0 0 0 0 None Sodium-chloride 0 0 0.1 0 0 Yellow Thermite 0.5 1 0.3 -0.08 0.9 Light orange Water 0 0 -3 0 0 None Welding Fuel 0.12 -0.1 0.1 -0.08 0.7 Orange

Maintaining the Orbital Cannons Orbital Cannon: Description: Orbital Cannon.png Used for firing warheads at any currently orbited planets or nearby stations. It accelerates its payload with solid fuel for devastating results upon impact.

Loading/Reloading: Ammunition: Troubleshooting: