The process of advanced research in "Oxygen Not Included" revolves around unlocking new technologies and improving the efficiency of your colony. Through the research tree, players can access various tools and methods that aid in survival and colony expansion. These advancements require strategic planning, resource management, and attention to environmental factors. Understanding the full potential of research is key to long-term success in the game.

As you progress, certain research paths become vital for creating sustainable habitats. Below are some of the key stages and elements involved:

  • Basic Research: Unlocking early technologies to stabilize oxygen production and food sources.
  • Advanced Research: Focusing on complex systems like power generation, automation, and efficient waste management.
  • Space Exploration: Paving the way for exploring new environments and extracting resources from distant locations.

Each research category has its own prerequisites, such as access to certain resources or the completion of previous research. These elements create a layer of complexity, requiring players to adapt their strategies based on what they unlock.

Important: Research doesn’t just unlock new technologies; it also improves the overall efficiency of your colony's existing systems. This is especially crucial in later stages of the game.

To help with your research planning, here's an overview of the stages:

Research Stage Key Focus
Basic Survival essentials, such as oxygen production and basic food sources.
Intermediate Advanced production techniques and automation tools.
Advanced Space exploration, energy systems, and self-sustaining ecosystems.

Optimizing Oxygen Generation for Long-Term Survival

Efficient oxygen production is critical for sustaining a colony in the long term in Oxygen Not Included. As the game progresses, the demand for breathable air increases due to growing colony size and resource depletion. To ensure survival, players must implement advanced strategies for generating oxygen that are sustainable, efficient, and scalable. The selection of oxygen generation methods will depend on available resources, energy constraints, and environmental factors within the colony.

In the early stages, basic oxygen generation systems such as Algae Deoxydizers may suffice, but as the colony grows, players must consider more advanced technologies like Electrolyzers. These systems require careful planning to avoid excessive energy consumption and to ensure that by-products like polluted water or oxygen buildup are managed. Below are strategies and considerations for optimizing oxygen generation systems.

Key Considerations for Efficient Oxygen Production

  • Energy Efficiency: Ensure that the oxygen production system doesn't drain your colony’s energy supply. High-energy systems like Electrolyzers need to be paired with renewable energy sources such as Solar Panels or Hydrogen Generators.
  • Resource Management: Balance the consumption of resources like algae, water, or hydrogen, ensuring that you have enough to keep your oxygen systems running without depleting critical supplies.
  • Environmental Impact: Maintain proper ventilation to prevent oxygen buildup in high-traffic areas, which can affect the colony's efficiency and air quality.

Optimizing Oxygen Generation Systems

  1. Electrolyzer Setup: Set up Electrolyzers in a controlled environment, utilizing water to produce oxygen. Ensure that there is sufficient airflow and filtration systems to deal with the excess hydrogen and polluted water.
  2. Efficient Airflow: Use gas pumps and filters to direct oxygen to the right areas of the base and remove excess or dangerous gases like carbon dioxide.
  3. Algae Deoxydizers for Early-Game: For smaller colonies, consider using Algae Deoxydizers, but be aware of the high energy cost and limited supply of algae.

In the long term, players should aim for a balanced oxygen generation system that integrates renewable resources and sustainable energy solutions. Over-reliance on any single method may lead to resource depletion and jeopardize the colony’s survival.

Example Oxygen Generation System

System Advantages Disadvantages
Electrolyzer Produces a high amount of oxygen with water; efficient if properly set up Requires constant water supply; produces hydrogen as a by-product
Algae Deoxydizer Cheap to build and maintain, uses algae as input Consumes a lot of power; algae resources are limited
Oxylite Requires no power, produces oxygen naturally over time Limited in amount, not suitable for large colonies

Designing Stable Oxygen Systems in Oxygen Not Included

In "Oxygen Not Included," ensuring a consistent supply of breathable air is critical for the survival of your duplicants. The game offers a variety of mechanisms to create and maintain stable oxygen production systems. However, understanding the balance between oxygen production, consumption, and distribution is key to building a functional and long-lasting system. This requires careful planning, resource management, and regular adjustments to avoid contamination or depletion of oxygen supplies.

The key to a sustainable oxygen system lies in the proper management of air flow, resources, and generation methods. From simple algae terrariums to complex electrolysis setups, there are several strategies to keep your colony breathing easily. Below are some important aspects to consider when designing these systems.

Basic Elements of Oxygen Generation

  • Oxygen Production: Using various machines like algae terrariums, electrolyzers, and algae distillers to generate oxygen.
  • Oxygen Storage: Storing oxygen in tanks or using breathable gas vents to ensure consistent supply in different parts of the base.
  • Airflow Management: Maintaining good airflow to ensure oxygen is evenly distributed throughout the base. This can involve careful use of ventilation systems and pumps.

Common Oxygen Generation Methods

  1. Algae Terrariums: Early game solution that produces oxygen at the cost of algae, which can be limited.
  2. Electrolyzers: Provides a continuous supply of oxygen by splitting water into hydrogen and oxygen, though it requires power and water.
  3. Oxygen Diffusers: Simple and effective in smaller spaces, but consume algae and can increase the risk of CO2 buildup.

To achieve an optimal setup, try to balance the production and consumption rates. Too many oxygen producers in a small space can create high levels of pressure, which will interfere with gas movement and could suffocate your duplicants.

Efficient Oxygen Distribution

Once oxygen is generated, distributing it effectively is the next challenge. Using gas pipes, pumps, and vents strategically ensures that oxygen is supplied to high-demand areas like living quarters or farms, while also maintaining a proper balance between other gases like carbon dioxide (CO2).

Method Pros Cons
Gas Pumps Efficient transfer of gases over long distances. Requires power and maintenance, can cause unwanted mixing of gases.
Oxygen Vents Simple and easy to install. Can cause oxygen leakage or imbalance in different rooms.
Gas Reservoirs Effective for storing large amounts of oxygen for emergencies. Requires space and resources for construction.

Key Technologies for Boosting Oxygen Output in Early Game

In the early stages of survival in *Oxygen Not Included*, managing oxygen production is crucial for the colony's sustainability. At this point, the key to success lies in efficiently utilizing the resources available to maintain a breathable atmosphere. Technologies that increase oxygen output are essential to avoid suffocation and ensure the colony’s basic needs are met.

Several core technologies, when researched and implemented, significantly enhance oxygen generation during the first few cycles. These technologies enable players to build systems that produce oxygen continuously while maintaining the balance of resources in a manageable way. Below are the critical advancements to prioritize for maximum efficiency.

1. Algae Deoxidizer

The Algae Deoxidizer is one of the first solutions available to produce oxygen in the early game. It works by converting algae into oxygen and is a reliable, low-maintenance device. However, it requires a continuous supply of algae, which is limited in the starting biomes.

Key Information: While the Algae Deoxidizer is effective, it is essential to monitor the availability of algae and manage its use wisely to avoid shortages.

  • Requires Algae as input
  • Consumes power
  • Produces oxygen passively

2. Electrolyzer

The Electrolyzer is unlocked later but offers a much more sustainable and scalable solution. It splits water into oxygen and hydrogen, providing a continuous and abundant source of oxygen if you have access to water. However, it does require substantial power to operate efficiently.

Key Information: Be cautious with hydrogen production as it can accumulate and pose a danger if not vented properly.

  1. Requires water as input
  2. Generates hydrogen as a byproduct
  3. High power consumption

Comparison of Oxygen Technologies

Technology Oxygen Output Resource Requirements Power Consumption
Algae Deoxidizer Low Algae Moderate
Electrolyzer High Water High

Prioritizing these technologies based on available resources and colony needs will ensure you maintain a steady oxygen supply early on, preventing any fatal risks to your duplicants.

Managing Oxygen Distribution and Avoiding Contamination

In Oxygen Not Included, oxygen management is a crucial aspect of survival. Proper distribution ensures that all your duplicants have access to breathable air, especially in large bases with multiple rooms and complex layouts. However, there are several risks involved, including oxygen contamination from pollutants like carbon dioxide and chlorine. Careful planning of air flow and filtration systems is necessary to maintain a breathable environment while avoiding harmful gases from spreading.

To effectively manage oxygen, you need to balance the oxygen production with proper ventilation and gas filtration. Oxygen sources such as Electrolyzers, Oxygen Diffusers, and Algae Terrariums must be placed in strategic locations to maintain airflow and avoid dead zones. Additionally, preventing the spread of contaminants requires a mix of automation, gas pumps, and airlocks to control gas movement and segregate polluted areas.

Key Steps in Oxygen Management

  • Plan the layout: Separate oxygen-rich areas from contaminated zones using gas permeability and airlocks.
  • Use pumps and ducts: Automate gas distribution to ensure optimal airflow and prevent CO2 buildup in living spaces.
  • Install filtration systems: Use Carbon Skimmers and Gas Filters to remove contaminants from the air.

Key Contaminants to Watch Out For

  1. Carbon Dioxide: A byproduct of respiration and power generation, it can displace oxygen and suffocate duplicants.
  2. Chlorine: Dangerous to duplicants, it can also corrode machinery and structures.
  3. Hydrogen: Flammable gas that can cause explosions when mixed with oxygen.

Tip: Use airlocks and automated gas pumps to control the flow of gases between rooms, keeping oxygen and contaminants separated.

Example Layout for Oxygen Distribution

Room Type Oxygen Source Gas Filter
Living Area Oxygen Diffuser Carbon Skimmer
Power Generation Electrolyzer Gas Filter (CO2)
Storage Area Algae Terrarium Gas Filter (Chlorine)

Effective Strategies for Oxygen Management During Critical Events

During times of oxygen shortage in *Oxygen Not Included*, having a robust strategy for managing your oxygen supply is crucial for the survival of your colony. Whether caused by malfunctioning systems, limited resources, or external environmental factors, a well-structured response can mitigate the risks associated with low oxygen levels. The key to effective crisis management lies in preparation, quick adaptation, and optimal resource allocation. Below are some essential practices to implement when dealing with oxygen shortages.

In these situations, ensuring your duplicants' access to breathable air is a top priority. This involves prioritizing oxygen production, utilizing backup systems, and considering alternative strategies such as scrubbing existing oxygen from polluted air. Understanding the dynamics of each oxygen-producing system and knowing when to activate or deactivate them can be the difference between recovery and disaster.

Best Practices for Oxygen Supply Management

  • Activate Oxygen Generation Early: Ensure oxygen generation systems like Electrolyzers and Algae Deoxidizers are turned on as soon as a shortage is detected. The sooner you react, the less risk your duplicants face.
  • Utilize Reserve Systems: In cases where primary oxygen systems fail, rely on stored supplies like Bottled Oxygen or Liquid Oxygen, which can provide temporary relief.
  • Maximize Airflow Efficiency: Optimize ventilation systems to improve airflow, directing breathable air towards high-traffic areas or critical zones, ensuring duplicants can reach oxygen more efficiently.
  • Monitor Carbon Dioxide Levels: Prevent carbon dioxide from accumulating in critical areas, as it displaces oxygen. Use air scrubbers and set up gas pumps to manage CO2 concentration.

Action Plan for Oxygen Crisis

  1. Step 1: Assess the oxygen levels across the colony, pinpointing areas of deficiency.
  2. Step 2: Activate backup oxygen generation systems such as Oxygen Diffusers or deploy Bottled Oxygen to critical zones.
  3. Step 3: Set up temporary scrubbers or pumps to manage CO2 levels and ensure it doesn't displace available oxygen.
  4. Step 4: Ration oxygen usage among duplicants by prioritizing critical tasks like farming, resource gathering, and repairing malfunctioning systems.
  5. Step 5: Once oxygen levels stabilize, gradually switch to more sustainable systems such as Electrolyzers or Algae Deoxidizers.

Remember, early detection and swift action are key to preventing a full-blown oxygen crisis. Always maintain a contingency plan for oxygen production and reserve supplies for emergencies.

System Efficiency Comparison

System Energy Usage Oxygen Output Resource Requirements
Electrolyzer High High Water, Power
Algae Deoxidizer Low Medium Algae
Oxygen Diffuser Medium Medium Water
Air Scrubber Medium None Polluted Water

Dealing with Oxygen Shortages: Troubleshooting and Solutions

In Oxygen Not Included, managing oxygen production is a critical aspect of colony survival. A lack of breathable air can lead to severe consequences, including the suffocation of your duplicants. Understanding the causes of oxygen shortages and knowing how to address them promptly is essential for maintaining a stable environment for your colony. Whether you're dealing with inefficient oxygen production or uncontrollable leaks, it's important to have effective solutions at hand to avoid disasters.

Oxygen shortages often stem from several factors such as the depletion of oxygen reserves, malfunctioning systems, or poor environmental conditions. Troubleshooting these issues requires a systematic approach to identify the root cause and apply targeted fixes. Below are some common problems and their corresponding solutions to keep your duplicants breathing easy.

Common Causes and Fixes for Oxygen Shortages

  • Insufficient Oxygen Production: Your colony might not be generating enough oxygen to meet the needs of all duplicants. Check the efficiency of oxygen-producing machines like Electrolyzers and Algae Deoxydizers. Make sure they are running continuously and are not obstructed.
  • Leaks in the Atmosphere: Leaks can occur in your oxygen piping or ventilation systems. Inspect the pipes and ensure that there are no ruptures or blockages. Sealing these leaks is essential for maintaining consistent airflow.
  • Depletion of Oxygen Resources: If you're relying on resources like algae, ensure that they are not running low. Algae can be depleted over time, and switching to more sustainable options like Water Electrolysis might be necessary.

Effective Solutions to Ensure Oxygen Availability

  1. Upgrade Oxygen Production Units: Consider improving the capacity of your Electrolyzers by providing them with more water and better access to power. If using Algae Deoxydizers, ensure they are positioned near algae deposits and have a continuous power supply.
  2. Implement Automated Systems: Set up automation to control the activation of oxygen generators. This will help ensure that oxygen production is optimal and that your duplicants are not deprived of air during critical moments.
  3. Increase Oxygen Storage: Create large reservoirs to store excess oxygen. This ensures that even if your production slows down temporarily, there will be a buffer of breathable air available.

Tip: Regularly check for oxygen pockets in your base, especially in high-demand areas. Creating proper ventilation paths can greatly improve airflow throughout your base.

Important Considerations

Issue Solution
Lack of Power for Oxygen Machines Ensure a reliable power source, such as using renewable energy like solar panels or backup generators.
Contaminated Air Use air scrubbers and filter the air to remove pollutants such as carbon dioxide or chlorine.
Oxygen Production Stalled Check if there are any blockages in the machines or pipes, and ensure they have a steady supply of water or resources.

Building a Sustainable Oxygen Production Loop for Advanced Stages

As colonies in "Oxygen Not Included" progress into later stages, ensuring a reliable and sustainable oxygen supply becomes increasingly complex. At this point, managing resources efficiently is crucial for survival, requiring a careful integration of oxygen production technologies and renewable processes. In this phase, various systems, such as electrolyzers and oxygen diffusers, must be optimized to maintain a constant oxygen output without depleting critical resources like water and power.

Advanced oxygen production loops depend on both renewable energy sources and closed-loop recycling mechanisms. By connecting oxygen production systems with resource regeneration processes, players can achieve a balance that minimizes the need for external inputs. This approach not only ensures oxygen availability but also supports other life-sustaining elements like temperature regulation and waste management.

Key Components of a Sustainable Oxygen System

  • Electrolyzers: Key for converting water into oxygen and hydrogen. These require constant water supply and power, but can be paired with a hydrogen power system to reduce energy consumption.
  • Oxygen Diffusers: Use algae to generate oxygen, but require constant access to algae resources, which can be challenging in late-game scenarios.
  • Air Scrubbers: Vital for reducing carbon dioxide, making the environment habitable for longer periods.
  • Water Purifiers: Ensure the sustainability of water supplies, essential for running electrolyzers.

Building the Loop

  1. Start by establishing an electrolyzer setup in a hydrogen-rich environment. The electrolyzers will convert water into oxygen and hydrogen. Ensure the hydrogen is safely redirected to a power station.
  2. Next, set up oxygen diffusers near algae sources to produce additional oxygen, using algae harvested from natural resources.
  3. Integrate air scrubbers to remove excess carbon dioxide produced by the colony. These systems should be placed in areas with high CO2 concentration.
  4. Use water purifiers to recycle water, feeding it back into the electrolyzers to close the loop and minimize water consumption.

Considerations for Efficiency

Proper power management is essential for maintaining a sustainable oxygen production loop. Utilizing solar panels or other renewable energy sources helps to reduce the reliance on manual power generation, which can be taxing in advanced stages of the game.

System Optimization Table

Component Energy Consumption Resource Use Output
Electrolyzer High Water Oxygen, Hydrogen
Oxygen Diffuser Medium Algae Oxygen
Air Scrubber Low None CO2 Reduction
Water Purifier Low Polluted Water Clean Water