This method was chosen for the Arzaville neighborhood stormwater runoff because it is simpler to implement, less expensive, and environmentally acceptable. It was taken into account because it provides greater imperiousness, where the rising development of Arzaville community structures and roadways disrupts the local water cycle and floods bays and guts with significant amounts of stormwater and associated toxins. In addition to preventing the runoff of stormwater, rain gardens provide a habitat and food for wildlife, which include insects such as butterflies, enhancing the beautification of Arzaville yards (Sheffield et al., 2018). Generally, rain gardens were fit for implementation as they would enhance soil moisture, prevent flooding, and beautify the Arzaville area.
This design element was picked because it does not produce “heat islands,” areas of pavement that appear to be significantly warmer than the surrounding regions. The concept was accounted for because it allows for using recycled materials in its construction, reducing the need for the external landscape to produce resources to build roadways and pavements. Some benefits of the permeable pavement system include catching precipitation and surface runoff, allowing the water to slowly infiltrate the soil through drain tiles (Sheffield et al., 2018). This system can be integrated into Arzaville parking lots, sidewalks, traffic roads, and driveways as it promotes water storage in reservoirs.
This solution was chosen because it is a practical and popular water recycling system for the expanding Arzaville community. Additionally, it provides advantages like cost savings because installation is less expensive, a reduction in snowfall, and proof of industrial expansion. Moreover, gray water is essential as it contains vital nutrients which can be channeled to the plants that grow in Arzaville (Sheffield et al., 2018). Some of the gray water might be from fertilizer industries, which might boost the soil quality in Arzaville if the water’s runoff is maintained within environmental standards, such as the 2-inch-height-above-the-ground runoff trench construction.
Reference
Sheffield, J., Wood, E. F., Pan, M., Beck, H., Coccia, G., Serrat‐Capdevila, A., & Verbist, K. (2018). Satellite remote sensing for water resources management: Potential for supporting sustainable development in data‐poor regions. Water Resources Research, 54(12), 9724-9758. Web.