Share:


Performance analysis of different geotextile materials in extensive roof garden designs

    Ozlem Akat Saracoglu Affiliation
    ; Handan Cakar Affiliation
    ; Hulya Akat Affiliation
    ; Hakan Adanacioglu Affiliation

Abstract

Roof garden arrangements, which have emerged in recent years based on environmentally friendly approaches, not only increase urban aesthetics but are also a design approach that contributes to the solution of problems caused by climate change. In this study, the filtration performance of different geotextile materials was investigated based on the extensive roof garden model. The studies related to the research were carried out as an open field pot experiment in Ege University Bayindir Vocational School. Crassula ovata from succulent group plants was used as plant material. 3 filtration materials were tested as filter layers, namely glass fibre, raw cotton, and polypropylene fabric. Various statistical analyses were applied to determine the effectiveness of the filtration materials in extensive roof garden applications. According to statistical significance levels it can be said that the use of polypropylene fabric as filtration material would be more advantageous compared to alternative geotextile materials.

Keyword : glass fibre, filter material, landscape management, raw cotton fabric, polypropylene fabric, green roof

How to Cite
Akat Saracoglu, O., Cakar, H., Akat, H., & Adanacioglu, H. (2022). Performance analysis of different geotextile materials in extensive roof garden designs. Journal of Environmental Engineering and Landscape Management, 30(4), 484–492. https://doi.org/10.3846/jeelm.2022.18057
Published in Issue
Dec 2, 2022
Abstract Views
467
PDF Downloads
343
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

References

Akat Saraçoğlu, Ö., Meriç, M. K., Tüzel, İ. H., & Kukul Kurttaş, Y. S. (2019). Responses of gerbera jamesonii plants to different salinity levels and leaching ratios when grown in soilless culture. In M. Hasanuzzaman, K. R. Hakeem, K. Nahar, & H. F. Alharby (Eds.), Plant abiotic stress toler-ance (pp. 357–379). Springer Nature. https://doi.org/10.1007/978-3-030-06118-0_15

Akın, F., & Kahraman, Ö. (2018). The availability of sewage sludge in ornamental kale cultivation. Anadolu Journal of Agricultural Science, 33(2), 177–183. https://doi.org/10.7161/omuanajas.347626

Akpınar Külekçi, E. (2017). Green roof systems from past to today and study on the determination of quality standards in the green roof. Journal of ATA Planning and Design, 1(1), 35–53. http://ataptd.atauni.edu.tr/

Ampim, P. A. Y., Sloan, J. J., Cabrera, R. I., Harp, D. A., & Jaber, F. H. (2010). Green roof growing substrates: Types, ingredients, composition and properties. Journal of Environmental Horticulture, 28(4), 244–252. https://doi.org/10.24266/0738-2898-28.4.244

Aras, B. B. (2019). Green roof practices in the context of urban sustainability. MANAS Journal of Social Studies, 8(1), 469–504. https://doi.org/10.33206/mjss.474314

Aslanboğa, İ. (1988). Studies on the selection of structural and herbal materials to be used in roof garden construction in Aegean Region climate conditions. Bilgehan Press.

Başar, H. (2000). Comparision of various soilless cultivation methods. Anadolu Ege Tarımsal Araştırma Enstitüsü Dergisi, 10(2), 169–182.

Calheiros, C. S. C., & Stefanakis, A. (2021). Green roofs towards circular and resilient cities. Circular Economy and Sustainability Journal, 1, 395–411. https://doi.org/10.1007/s43615-021-00033-0

Cascone, S. (2019). Green roof design: State of the art on technology and materials. Sustainability, 11(11), 3020. https://doi.org/10.3390/su11113020

Cunningham, N. R. (2001). Rethinking the urban epidermis: A study of the viability of extense green roof systems in the Manitoba capital with an em-phasis on regional case studies and stormwater management [Master’s thesis]. University of Manitoba, Landscape of Architect.

Daryaei, A. (2019). A study on the measurement on the of the effectiveness of energy efficiency of green roof systems: Tehran examnination [Master’s thesis]. Akdeniz University, Antalya, Turkey.

Ding, W., Clode P. L., & Lambersbul, H. (2019). Is pH the key reason why some Lupinus species are sensitive to calcareous soil? Plant and Soil, 434, 185–201. https://doi.org/10.1007/s11104-018-3763-x

Dunnett, N., & Kingsbury, N. (2008). Planting green roofs and living walls (2nd printing). Timber Press.

Ekşi, M. (2006). The use of construction elements in roof and terrace gardens and the new dimensions [Master’s thesis]. University of Istanbul.

Ekşi, M. (2012). Assessment of major roof gardens in Istanbul in terms of construction principle. Journal of the Faculty of Forestry Istanbul University, 62(1), 149–157.

Ekşi, M. (2014). The concept of roof garden and an assessment into the its use of the term. Eurasia Term Journal, 2(2), 26–35.

Eksi, M., & Rowe, D. B. (2019). Effect of substrate depth and type on plant growth for extensive green roofs in a mediterranean climate. Journal of Green Building, 14(2), 29–44. https://doi.org/10.3992/1943-4618.14.2.29

Erdoğan, E., & Kemaloğlu, A. (1991). Grass use on building surfaces. Landscape Art Journal Publication, 1, 14–15.

Erkul, E., & Sönmez, A. (2014). Environmentally conscious architecture: Environmental effects of green roof systems. Architecture Journal 375. http://www.mimarlikdergisi.com/index.cfm?sayfa=mimarlik&DergiSayi=389&RecID=3305

Farrell, C., Mitchell, R. E., Szota, C., Rayner J. P., & Williams, N. S. G. (2012). Green roofs for hot and dry climates: Interacting effects of plant water use, succulence and substrate. Ecological Engineering, 49, 270–276. https://doi.org/10.1016/j.ecoleng.2012.08.036

Johnston, J., & Newton, J. (1993). Building green: A guide to using plants on roofs, walls & pavements. London Ecology Unit.

Kader, S. A., Karunaratne, S., Lizny M. J. M. F., Asmath, A. M. M., & Zainudeen, U. L. (2022). Analysis of physical and chemical properties of alter-native substrate material for sustainable green roofs. Research Square. https://doi.org/10.21203/rs.3.rs-1224124/v1

Koç, N., & Güneş, G. (1998a). Technical considerations for the planning of roof gardens. Pamukkale University Journal of Engineering Sciences, 4(1), 501–512. http://pajes.pau.edu.tr/jvi.aspx?un=PAJES-58159&volume=4&issue=1

Koç, N., & Güneş, G. (1998b). Planting principles of roof gardens. Pamukkale University Journal of Engineering Sciences, 4(2), 625–633. https://dergipark.org.tr/tr/download/article-file/191503

Kolb, W., & Schwartz, T. (1988). Roof planting from a constructional viewpoint. Garten und Landschaft, 10(88), 54.

Küçükerbaş, E. V. (1991). Investigations on low-maintenance (extensive) planting possibilities on low soils depth in Aegean region conditions in a roof garden example [Doctoral dissertation]. Ege University Graduate School of Natural and Applied Sciences, Department of Landscape Architecture, Izmir, Turkey.

Lanham, J. K. (2007). Thermal performance of green roofs in cold climates [Master’s thesis]. Queen’s University, Department of Civil Engineering Canada, Kingston, Ontario, Canada.

Oberndorfer, E., Lundholm, J., Bass, B., Coffman, R. R., Doshi, H., Dunnett, N., Gaffin, S., Köhler, M., Liu K. K. Y., & Rowe, B. (2007). Green roofs as urban ecosystems: Ecological structures, functions and services. BioScience, 57(10), 823–833. https://doi.org/10.1641/B571005

Özdemir, E., & Altun, M. C. (2010, April). A checklist recommendation for greenroof system design. In 5th National Roof and Facade Symposium. Dokuz Eylül University, Faculty of Architecture, Izmir, Turkey.

Paraskevopoulou, A. T., Karantzi A. K., Liakopoulos, G., Londra, P. A., & Bertsouklis, K. (2020). The effect of salinity on the growth of lavender species. Water, 12(3), 618. https://doi.org/10.3390/w12030618

Pehlevan, A., Yaşar, Y., & Maçka, S. (2010). Vegetated roofs: Green roofs, roof gardens. Journal of Arredamento Architecture, 236, 114–124.

Sailor, D. J., Hutchinson, D., & Bokovoy, L. (2008). Thermal property measurements for ecoroof soils common in the western US. Energy and Build-ings, 40(7), 1246–1251. https://doi.org/10.1016/j.enbuild.2007.11.004

Salachna, P., Piechocki, R., & Byczynska, A. (2017). Plant growth of curly kale under salinity stress. Journal of Ecological Engineering, 18(1), 119–124. https://doi.org/10.12911/22998993/66247

Seçkin, Y. P., & Seçkin Y. Ç. (2016, June). The development of green roofs in architectural desing. In 8th National Roof & Facade Symposium. Mimar Sinan University, Departmant of Fine Arts, Istanbul, Turkey.

Sonneveld, C. (2001). Effects of salinity on substrate grown vegetables and ornamentals in greenhouse horticulture [Doctoral dissertation]. Wa-geningen University, The Netherlands.

Sönmez, S. (2013). Basic elements of plant nutrition: Water, soil, nutrient elements. Hasad Publishing.

Sun, Y., Chen J. J., Xing, H., Paudel, A., Niu, G., & Chappell, M. (2020). Growth, visual quality and morphological responses of 12 viburnum taxa to saline water irrigation. HortScience, 55(8), 1233–1241. https://doi.org/10.21273/HORTSCI14940-20

Veatch-Blohm, M. E., Sawch, D., Elia, N., & Pinciotti, D. (2014). Salinity tolerance of three commonly planted Narcissus cultivars. HortScience, 49(9), 1158–1164. https://doi.org/10.21273/HORTSCI.49.9.1158

Voyde, E., Fassman, E., & Simcock, R. (2010). Hydrology of an extensive living roof under subtropical climate conditions in Auckland, New Zealand. Journal of Hydrology, 394(3), 384–395. https://doi.org/10.1016/j.jhydrol.2010.09.013

Yücel, Ç. (2009, Mart). Sürdürülebilirlik ve Yeşil Çatılar. In 21. Uluslararası Yapı ve Yaşam Kongresi “Doğa, Kent ve Sürdürülebilirlik” (pp. 145–151). TMMOB Mimarlar Odası Bursa Şubesi, Bursa.