Recent studies have shown exposure to concentrations of carbon dioxide above a threshold ranging from 600 and 1000 parts per million (ppm) impairs human cognitive performance. Upon passing this threshold, a 400ppm increase is correlated with a 21% decline in cognitive performance. Classrooms and offices, two spaces where cognitive performance should be optimized, often exceed 1000 ppm, with one study of classrooms in Texas showing that over 20% exhibit peak CO2 concentrations well above 3000 ppm. While one solution to this problem is increasing the rate of ventilation, this results in greater energy expenditure. The BioArchos project proposes the deployment of modular, wall-mounted, easily operated carbon sequestration devices. The apparatus utilizes the photosynthetic and metabolic processes of Chlorella vulgaris, a species of algae, as a means of addressing the cognitive, environmental, and cost issues that surround elevated CO2 levels. We started this investigation with the design and assembly of a closed-loop bioreactor testbed, which tested the impact of CO2 concentration, gas pressure, and light intensity on overall performance. Our initial tests seek to optimize the response time of the system to an increase in carbon concentration and the energy consumption of the device. Our findings from these tests, as well as the findings from other studies inform the development of an open-loop prototype, which is the first iteration of our proposed solution. We predict this prototype will remove approximately 350g of CO2 every day, using approximately 0.5 kW of energy. That is about the average CO2 output of one person’s 8-hour work day, with an energy usage less than half of a conventional microwave. Once the proof of concept is established, the focus of the BioArchos project will be to increase the volumetric efficiency of our device while reducing operational costs to make the final product more accessible and effective.