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BIOS-3

BIOS-3 is a groundbreaking experimental closed ecological life support system (CELSS) developed by Soviet scientists to test the viability of sustaining human crews in self-contained environments for long-duration space missions. Constructed at the Institute of Biophysics of the Siberian Branch of the Russian Academy of Sciences in Krasnoyarsk, Siberia, between 1965 and 1972, the facility integrated biological processes involving microalgae and higher plants to recycle air, water, and waste while producing food and oxygen. It achieved high closure efficiencies, including nearly 100% regeneration of atmospheric gases, 85% for water, and about 50–55% for food, marking a significant advancement in bioregenerative technologies. The design of BIOS-3 featured a hermetically sealed, cylindrical structure with a total volume of 315 cubic meters, divided into four interconnected compartments consisting of a crew area (approximately 62 m³) equipped with living quarters, a kitchen, lavatory, and control room; two phytotrons (each about 84 m³) for higher plant cultivation employing hydroponic conveyor systems spanning 63 square meters of growing surface, illuminated by water-cooled xenon lamps delivering photosynthetic photon flux densities of 900–1,850 μmol·m⁻²·s⁻¹ to cultivate crops such as wheat, vegetables, and chufa nuts; and one algal compartment using Chlorella vulgaris in flat-panel cultivators covering 8 square meters per person to enhance gas exchange and provide supplemental nutrition. Air purification involved high-temperature (600°C) catalytic processing, while water and nutrient cycles relied on condensation, filtration, and ion-exchange methods to minimize external inputs. From 1972 to 1984, BIOS-3 hosted ten manned experiments with crews of one to three individuals isolated for periods ranging from 20 days to six months, including a landmark 180-day closure with three participants in 1972–1973. These trials verified the system's stability, with crews maintaining physiological health and performing scientific tasks without significant issues, while monitoring parameters like gas composition, microbial populations, and psychological factors. The experiments yielded critical insights into optimizing biological , reducing resource leakage to as low as 0.02–0.026% of volume per day, and addressing challenges such as oxygen fluctuations and variability, informing international efforts in space like NASA's CELSS program and the European Space Agency's project.

History

Development and Precursors

The , following the successful and Voskhod missions in the early 1960s, recognized the limitations of open-loop systems for long-duration spaceflights, prompting research into closed ecological systems to ensure sustainability of air, water, and food resources. This motivation was rooted in the broader vision of extending human presence beyond , including potential lunar and planetary missions, where resupply from would be impractical. Planning for advanced bioregenerative began in 1964 at of Biomedical Problems (IBMP) in , leading to the development of BIOS-1, a small-scale facility operational by 1965 that featured a 15-liter algal chamber using Chlorella vulgaris to regenerate oxygen from crew-generated in a two-compartment setup for one person. BIOS-1 conducted five experiments in the mid-1960s, achieving up to 90% atmospheric closure over 29- to 32-day periods, though metabolic imbalances required dietary adjustments to maintain stability. Building on these results, BIOS-2 was established in 1968 as a 90 m³ facility at the Institute of in , , under the leadership of I. Gitelson and his team, incorporating crew quarters, an algal cultivator, and initial integration of higher plants like in a compartment to enhance and food production. This hybrid algal-phytocenosis approach, influenced by parallel (CELSS) efforts but emphasizing Soviet expertise in , extended human experiments to 90 days while testing microbial waste oxidation. The primary objectives across BIOS-1 and BIOS-2 were to achieve 90-95% closure rates for air, water, and waste recycling, laying the groundwork for more comprehensive systems. These precursors directly informed BIOS-3's design, with planning initiated in the mid-1960s to scale up to support a three-person crew in a fully controllable , focusing on emergent properties for applications.

Construction and Early Operations

The construction of BIOS-3 began in 1965 at the Institute of Biophysics of the Siberian Branch of the (then under the Soviet Academy of Sciences) in , , as part of the Soviet Union's efforts to develop closed ecological systems amid the . This project, shrouded in secrecy due to its ties to ambitions, involved significant budgetary allocations from the academy to advance bioregenerative technologies inspired by earlier prototypes like BIOS-1 and BIOS-2. By 1972, the facility was completed as a sealed, underground steel structure with a total volume of 315 m³, designed to sustain up to three individuals in a controlled . Engineering challenges during construction centered on integrating interdependent subsystems within the hermetically sealed compartments while ensuring reliability and minimal external inputs. The facility comprised four main sections: one dedicated to crew quarters including sleeping areas, a , lavatory, and ; one for algal mariculture using in stacked cultivators covering 8 m² per person to balance oxygen and ; and initially two phytotrons (later expanded to three) spanning 63 m² for cultivating edible plants like , chufa, and under artificial lighting. Key hurdles included achieving gas-tight seals to prevent leaks, managing circulation to avoid nutrient imbalances, and synchronizing biological processes with human needs, all while powering the system with 60 arc lamps (20 per phytotron, each 6 kW) that demanded a total electrical input of approximately 400 kW, cooled via water jackets to maintain thermal stability. Air purification relied on at 600°C, and water recycling incorporated and storage mechanisms to close the loops as much as possible. Early operations commenced in 1972 with unmanned tests to calibrate the integrated systems, verifying (achieving 99% ), water cycling (85% efficiency), and initial biological productivity before human involvement. These calibration runs focused on stabilizing the algal and plant components for oxygen production and waste processing, with handling primary air revitalization and higher contributing to food and supplementary gas regulation. By late 1972, the facility transitioned to manned use, launching the first extended experiment—a 180-day with three members from 1972 to 1973—that marked the onset of operational validation for the full cycle.

Design

Physical Structure

BIOS-3 is a cylindrical measuring 14 meters in length and 9 meters in , buried underground to enhance thermal and , with a total internal volume of 315 m³. The facility features insulated welded walls to maintain sealing and includes airlocks for crew entry and exit. Internally, it is divided into four airtight compartments: a central crew quarters of 60 m³ equipped with three individual cabins, a , lavatory, and ; an algal chamber of 80 m³ using flat-panel systems covering 8 m² per person for Chlorella vulgaris cultivation; and initially two phytotrons, each with a growing area of approximately 21 m² and 2.5 meters in height. The phytotrons employed hydroponic conveyor systems providing a total growing surface of 63 m², illuminated by a 20 kW system of lamps designed to simulate spectra and deliver photosynthetic photon flux densities of 900–1,850 μmol·m⁻²·s⁻¹. By 1972, the algal cultivator was repurposed, expanding the facility to three phytotrons to accommodate greater plant diversity while supporting a of up to three.

Life Support Systems

The life support systems in BIOS-3 integrated bioregenerative technologies to sustain air, water, and waste cycles in a sealed environment, emphasizing biological processes supplemented by physicochemical backups for reliability. This hybrid design aimed to mimic self-sustaining ecosystems for space missions, with biological components handling primary regeneration while physicochemical elements ensured redundancy during imbalances or failures. Air regeneration relied heavily on photosynthetic organisms, with Chlorella algae cultured in an 80 m³ cultivator that produced 60-70% of the required oxygen via CO₂ fixation. Higher plants, such as wheat and vegetables grown in dedicated phytotrons, contributed an additional 25% of O₂ through their transpiration and growth cycles. The remaining oxygen needs were met by physicochemical methods, including the catalytic decomposition of CO₂ and trace organics by heating air to 600°C over a nickel-chromium catalyst, which also helped control atmospheric impurities. Water recycling operated as a near-closed loop, recovering 85-95% of water through multi-stage processes that included of vapor from plant and algal , mechanical to remove particulates, and biological uptake followed by release. was specifically treated via , which not only extracted potable water but also generated supplemental oxygen as a , integrating with the air system. Waste management transformed human and plant residues into usable resources, with fecal and inedible undergoing composting to break down organics into nutrients for plant fertilization, while wastes were directed to algal assimilators for uptake and conversion. This process supported food production from hydroponically grown , vegetables like radishes and greens, and harvested , collectively providing up to 50% of the crew's caloric intake in the form of breads, salads, and protein supplements. The facility's operations demanded approximately 400 kW of electrical power, primarily for artificial in the phytotrons and cultivators, circulation pumps, and equipment. Continuous monitoring was enabled by an array of sensors tracking CO₂ concentrations, O₂ levels, humidity, and compositions, allowing adjustments to maintain ; the hybrid bio-physical framework provided , as biological elements could recover slowly while physicochemical systems offered immediate stabilization.

Experiments

Manned Closure Experiments

The BIOS-3 facility conducted 10 manned closure experiments between 1972 and 1984 to test habitation in a , with crew sizes ranging from two to three individuals and experiment durations varying from short-term trials of about 10 days to extended isolations up to 180 days. These experiments simulated long-duration missions by maintaining crews in complete atmospheric and material closure, relying on the facility's integrated systems for survival. The trials progressively increased in complexity, focusing on adaptation to confined conditions while managing biological components like algal oxygen production and crop cultivation. The inaugural and longest manned experiment occurred from late 1972 to mid-1973, involving a three-person crew—two men and one woman—who remained sealed for 180 days during the Siberian winter. This trial, divided into three sequential phases of approximately two months each, tested the system's capacity to support human life with varying configurations of phytotrons and algal chambers, achieving high levels of air and water regeneration. A notable subsequent test in 1977 featured a three-person (all male) crew isolated for 120 days, though one member left during the experiment, emphasizing operational stability and resource management. In the 1980s, several three-person experiments further prioritized food self-sufficiency, with crews deriving up to 50% of their nutrition from onboard crops like wheat, vegetables, and greens grown in hydroponic setups. Crew selection emphasized candidates with prior involvement in the facility's and operations to foster deep familiarity and , drawing from Soviet cosmonauts, engineers, and ecologists trained in biological . included simulations of closed-environment tasks, psychological assessments for tolerance, and instruction in to handle phytotron maintenance. Later experiments incorporated gender-mixed teams to evaluate interpersonal dynamics in diverse groups. Protocols enforced strict , prohibiting physical contact with the exterior except for essential material inputs like supplemental protein sources, while allowing monitored communication. Daily routines structured around 8-10 hours of labor, including crop tending, system monitoring for gas exchanges and cycles, waste processing, and scheduled physical exercises to counteract microgravity-like effects on . Psychological support was facilitated through regular video conferences with ground control teams, helping mitigate from confinement and repetitive tasks. Crews reported high akin to full-time farming, with about 16 minutes of daily effort per square meter of growing area dedicated to maintenance activities.

Supporting Unmanned Tests

The supporting unmanned tests in BIOS-3 served to optimize the facility's bioregenerative systems for long-term stability, isolating variables associated with human presence to evaluate component performance independently. These experiments were conducted both prior to initial manned operations and intermittently afterward, allowing researchers to assess the reliability of closed-loop processes without the complexities of interactions. Key unmanned tests built on earlier work with the precursor BIOS-2 facility, where extensions from 1968 to 1972 involved automated evaluations of higher plant growth and gas exchange dynamics over durations up to four months, providing foundational data that informed BIOS-3's design. In the , stability trials focused on algal cultures, particularly in bioreactors, running for periods up to two months to test sustained oxygen production and absorption in sealed environments. By the , phytotron-based simulations examined crop yields from higher plants such as and , simulating multi-year cultivation cycles to identify optimal growth parameters under controlled conditions. These tests employed automated systems to track gas exchanges between photosynthetic organisms and the atmosphere, as well as cycles in hydroponic setups, ensuring precise on material balances. Researchers tested various strains for and , alongside adjustments to lighting regimes using xenon lamps to mimic spectra. Such methods enabled the isolation and refinement of individual subsystems, like algal photobioreactors and growth chambers, before scaling to integrated operations. Outcomes from these unmanned runs directly integrated into subsequent protocols, for instance, by fine-tuning lamp spectra to enhance efficiency in , thereby improving overall system performance for manned experiments. This data-driven approach ensured smoother transitions to crewed closures by validating long-term .

Results and Achievements

Resource Recycling Outcomes

The BIOS-3 experiments demonstrated high efficiency in air recycling, achieving up to 99% closure by 1968 through the use of cultivators that absorbed CO₂ and produced O₂ via , supplemented by physicochemical purification of complex organics via catalytic heating at 600°C. In later manned closure tests, including the 180-day experiment with a three-person from 1972–1973, air regeneration reached 91% overall closure, with algae output providing approximately 0.8–1.0 kg of O₂ per day per person equivalent, meeting the physiological needs of the while maintaining stable atmospheric composition. These improvements over initial unmanned tests reflected optimizations in algal density and integration with plant compartments, reducing reliance on external inputs. The experiments achieved an overall material closure of 91%. Water recovery in BIOS-3 progressed from 85% efficiency in early operations by , primarily through storage and recirculation of transpired and condensed moisture, to 90–99% in subsequent experiments. In the 180-day manned , water reached 91%, with recycling via algal condensate and plant transpiration. Degree of was calculated as \text{Closure} = \frac{\text{Input} - \text{Losses}}{\text{Input}} \times 100\%, highlighting progressive enhancements from physicochemical and biological uptake in hydroponic systems across tests. Food production and waste recycling achieved 40–57% caloric self-sufficiency in manned experiments, with phytotrons cultivating , , and greens to supply the vegetable component of the , while was imported for protein. Waste conversion via composting and direct nutrient return from to hydroponic solutions enabled approximately 80% recycling, minimizing nutrient losses and supporting yields that increased from 40% in early phases to 57% in optimized later runs like the 180-day test. Overall material closure for and improved over time, from about 50% in 1968 unmanned configurations to higher rates in integrated crewed operations, demonstrating the system's potential for partial bioregenerative sustenance.

Biological and Human Factors

In BIOS-3, higher plants such as wheat, chufa, beets, and carrots were cultivated hydroponically in two phytotrons totaling approximately 40 m², contributing significantly to food production and atmospheric regeneration. Wheat, occupying the majority of the growing area, yielded 186.7 g of dry edible biomass per day from 17.53 m², while overall edible plant yields reached 681.1 g dry mass per day across 39.4 m² in the 180-day test. Chlorella vulgaris algae, grown in an 18 L bioreactor spanning 8 m², supported gas exchange for one to three crew members by absorbing CO₂ and producing O₂, achieving initial contributions of 20% to system closure that increased to 80-85% with integrated water recycling, and providing 5-10% protein yields. These biological components supplied approximately 227 g of daily edible biomass per crew member, covering 26% of carbohydrates, 14% of proteins, and 2.3% of fats in the diet. Challenges in plant and algal productivity included and accumulation, addressed through additives like to the water supply to prevent deficiencies. Volatile organic compounds from occasionally stunted growth and caused sterility in heads, while sodium buildup from recycled reached 0.90-1.65 g/L, necessitating careful monitoring to avoid . was minimized in the closed hydroponic setup, with no major infestations reported, though potential for plant diseases was mitigated by stable microbial communities that enhanced resistance. Microbiological stability was maintained through continuous monitoring of bacterial loads in air and water, with no spontaneous biological catastrophes or pathogenic outbreaks occurring during operations. Adaptations such as preventing external species invasion in the closed environment ensured equilibrium, while internal microbial processes controlled trace contaminants and supported atmospheric dynamics without toxic effects. Bacterial populations in water and air remained balanced, contributing to overall system resilience. Human factors during BIOS-3's 180-day manned experiments involved crews of three experiencing in a confined 315 m³ volume, yet no significant psychological disturbances, such as anxiety or conflicts in group dynamics, were reported, with participants maintaining positive enhanced by fresh plant-based foods like and . Health monitoring revealed no deviations in overall condition, including stable levels supplemented via water (e.g., for iodine and salts), absence of allergies, and no notable due to physical activities like system maintenance. The diet, approximately 50% regenerated from grown sources, supported normal physiological function without onset, though minor gaps were resolved with external supplements. Key findings highlighted the successful maintenance of microbial diversity, which prevented imbalances and supported plant health without catastrophic shifts. Human crews exhibited resilient adaptation to , with minor health issues like potential excesses proactively managed through supplements, demonstrating the viability of bioregenerative systems for long-term habitation.

Legacy

Influence on Space Research

BIOS-3's experiments significantly shaped the development of systems within Soviet and subsequent Russian space programs, providing foundational data on hybrid bioregenerative technologies for prolonged . The facility's demonstrations of integrated plant-algal systems for oxygen and waste recycling informed the incorporation of biological components into the designs of Salyut and space stations, enabling more sustainable environmental controls during extended orbital missions. These insights extended to planning for interplanetary travel, including Mars missions, where BIOS-3's hybrid bio-systems highlighted the potential for closed-loop to reduce resupply dependencies. On the international front, BIOS-3 fostered key collaborations that advanced global bioregenerative research. In 1991, the facility was integrated into the newly formed International Center for Closed Ecosystems at the Institute of Biophysics, Siberian Branch of the , which promoted cooperative studies on closed ecological systems among international scientists. This center built on earlier exchanges, including influences on the U.S. project, where BIOS-3 served as a pioneering model for large-scale closed habitats tested in the early . The legacy of BIOS-3 extended to major Western space agencies, influencing their bioregenerative life support initiatives. NASA's (CELSS) program, initiated in the late , incorporated lessons from the Russian BIOS projects, particularly the use of higher plants for food and air regeneration in space habitats. Similarly, the European Space Agency's MELiSSA project recognized BIOS-3 as a critical antecedent, drawing on its microbial and photosynthetic approaches to develop closed-loop systems for future deep-space exploration. Central to BIOS-3's impact were seminal publications documenting its outcomes, such as the comprehensive review by , Gitelson, and Lisovsky (1997) in BioScience, which analyzed the 180-day manned experiment's results on , , and crew productivity, thereby establishing benchmarks for bioregenerative technologies in space research.

Current Status and Modern Applications

Following the in 1991, the BIOS-3 facility was integrated into the International Center for Closed Ecosystems, a subdivision of the Institute of of the Siberian Branch of the in . Economic challenges and funding shortages in during the led to a period of limited activity at the site, with research largely pausing until the mid-2000s. Research activities resumed in 2005, shifting focus toward plant cultivation and waste recycling processes, in collaboration with the (ESA) on bioregenerative technologies for closed ecosystems. Unmanned tests have continued sporadically, such as those under the EU-funded BIOSMHARS project (2010–2012), which utilized BIOS-3 to model bioaerosol transport and biocontamination using calibrated and fungi, validating simulations for closed-space environments analogous to the . In modern applications, historical BIOS-3 data informs contemporary space agriculture planning, including estimates of crew time required for greenhouse maintenance—approximately 16 minutes per day per square meter of growing area based on trials—which supports of systems for the and future missions. The facility's recycling efficiencies, such as 95% water closure and near-complete atmospheric regeneration, also contribute to ongoing unmanned simulations for lunar and Martian habitat analogs, as highlighted in 2021 proposals for advanced closed systems like BIOS-4 to underpin Russian lunar base concepts. Beyond space, BIOS-3 technologies demonstrate potential for terrestrial closed-loop , enabling reduced environmental through full processing and nutrient in controlled environments, though remains a focus. Current challenges include maintaining the aging infrastructure, originally built in the 1970s, amid limited funding, which constrains full-scale manned operations and necessitates reliance on data from past experiments for 2020s deep-space habitat modeling.