From Living Building Science
The Kendeda Building at Georgia Tech is one of the most sustainable buildings in the world because of its certification as a living building. Under the guidelines of the Living Building Challenge, there are 7 petals that buildings must fulfill: Beauty, Equity, Materials, Place, Water, Energy, and Health and Happiness. Of these 7, the Hydroponics team is primarily focused on Place, with an interest in Water. The Place petal focuses on urban agriculture; the process of growing food in a city environment. Given the unique qualities of a hydroponic system - soilless and water efficient - it is an excellent way to fulfill the Place petal.
Hydroponic systems are classified as two types: open and closed. For the scope of this project, a closed wick system, which is both convenient and cost-effective, will be used. A simple wick system consists of a tank with a tray of pots resting on the lid. The tank is filled with a nutrient solution that contains the essential macro and micro nutrients that plants need to survive. Holes are cut into the tank lid so synthetic wicks can run from the pots to the nutrient solution below. The pots are filled with a soilless growing medium; typically coconut fiber or vermiculite, a type of mineral. Additionally, an air pump and air stone are used to oxygenate the nutrient solution so the plants do not suffocate. Plants receive nutrients via capillary action as the nutrient solution travels up the wick.
Place multiple hydroponics systems in different areas of the building to determine how much light availability affects growth. Additionally, observe and compare nutrient requirements for hydroponics systems using greywater or potable tap water.
We plan to use pre-built hydroponic wick systems as it is easier to control variables with them. Using these systems, we will compare greywater and potable tap water with nutrient solutions added by conducting a nutrient panel on the fully-grown lettuce plants. We will also measure light changes to see if that has a significant effect on lettuce growth. Furthermore, using the light sensors, we will determine where the most optimal location is for a hydroponics system in the Kendeda Building.
Charts and Figures
Greywater data taken from: Greywater Wetland
1. Zhou, J., Li, P., Wang, J., & Fu, W. (2019). Growth, Photosynthesis, and Nutrient Uptake at Different Light Intensities and Temperatures in Lettuce, HortScience horts, 54(11), 1925-1933. Retrieved Dec 6, 2021, from https://journals.ashs.org/hortsci/view/journals/hortsci/54/11/article-p1925.xml
- For medium temperatures (23 °C/18 °C), light intensities of 350 to 600 μmol·m−2·s−1 are recommended, and 500 μmol·m−2·s−1 is the optimal value during the middle of spring and autumn.
2. Schumann, T., Paul, S., Melzer, M., Dörmann, P., & Jahns, P. (2017). Plant Growth under Natural Light Conditions Provides Highly Flexible Short-Term Acclimation Properties toward High Light Stress. Frontiers in plant science, 8, 681. https://doi.org/10.3389/fpls.2017.00681
- Tested properties of plants under different light conditions, found that naturally fluctuating light produced plants that were more able to acclimate to different light conditions.
3. Shirly Tentile Magwaza, Lembe Samukelo Magwaza, Alfred Oduor Odindo, Asanda Mditshwa, Hydroponic technology as decentralised system for domestic wastewater treatment and vegetable production in urban agriculture: A review, Science of The Total Environment, Volume 698, 2020, 134154, ISSN 0048-9697, https://doi.org/10.1016/j.scitotenv.2019.134154. (https://www.sciencedirect.com/science/article/pii/S0048969719341312)
- Use of a hydroponics system as a tool for wastewater treatment: indicates that using wastewater/greywater for hydroponically growing crops is cost-effective and potentially more beneficial.
|Pallavi Natarajan||Chemical Engineering||Fall 2021 - Present|
|Cecil Hash||Biology||Fall 2021 - Present|
|Zohir Khawaja||Civil Engineering||Fall 2021|
|Aidan Blackshire||Environmental Engineering||Spring 2022|