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Integration of green roofs&walls in urban areas
Titolo Rivista: RIVISTA DI STUDI SULLA SOSTENIBILITA' 
Autori/Curatori: Noemi Caltabellotta, Felicia Cavaleri, Carlo Greco, Kestutis Navickas, Carlo Scibetta, Laura Giammanco 
Anno di pubblicazione:  2019 Fascicolo: 2 Suppl.  Lingua: Inglese 
Numero pagine:  18 P. 61-78 Dimensione file:  138 KB
DOI:  10.3280/RISS2019-002-S1005
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Growing urbanization is associated with the emergence of environmental problems, such as the reduction of natural resources, the atmosphere pollution and the increase of the heat islands phenomenon in cities. The integration of vegetation in the urban areas, through the creation of green hanging systems, represents a possible solution to improve the energy sustainability of buildings, to combat meteoric excesses, to improve stormwater management and to reduce pollutant levels. These energy and environmental benefits are related to the properties of evapotranspiration, shading and thermal insulation of the vegetation. The work reports the results of the main studies concerning the use of hanging systems to counter environmental impacts and improve the energy efficiency of buildings.


Keywords: Green systems, green roofs, vertical greenery, energy saving, energy efficiency, environmental sustainability

  1. Ascione F., Bianco N., De Rossi F., Turni G. and Vanoli G.P. (2013). Green roofs in European climates. Are effective solutions for the energy savings in air-conditioning? Applied Energy, 104: 845-859.
  2. Berardi U., GhaffarianHoseini A.H. and GhaffarianHoseini A. (2014). State-of-the-art analysis of the environmental benefits of green roofs. Applied Energy, 115: 411-428. Berardi U. (2016). The Benefits of green roofs retrofits as local intervention for mitigation the urban heat island effect in Toronto. Regenerative and Resilient Urban Environments.
  3. Berry R., Livesley S.J. and Aye L. (2013). Tree canopy shade impacts on solar irradiance received by building walls and their surface temperature. Build Environ, 69: 91-100.
  4. Besir A.B. and Cuce E. (2018). Green roofs and facades: A comprehensive review. Renewable and Sustainable Energy Reviews, 82: 915-939.
  5. Bevilacqua P. and Mazzeo D. (2016). Bruno R., Arcuri N. Experimental investigation of the thermal performances of an extensive green roof in the Mediterranean area. Energy Build, 122: 63-79.
  6. Brown P. (2014). Basics of evaporation and evapotranspiration. (Tucson, AZ): College of Agriculture and Life Sciences, University of Arizona.
  7. Cameron R.W.F., Taylor J.E. and Emmett M.R. (2014). What’s ‘cool’ in the world of green facades? How plant choice influences the cooling properties of green walls. Build Environ, 73: 198-207.
  8. Campiotti C.A., Schettini E., Bibbiani C., Alonzo G. and Viola C. (2013). Building green covering for a sustainable use of energy. J Agric Eng, 44 (2s).
  9. Campiotti C.A., Consorti L., Giagnacovo G., Nencini L. and Scoccianti M. (2018). Le coltri vegetali nel settore residenziale. Energia, ambiente e innovazione.
  10. Campiotti A., Caltabellotta N., Campiotti A. and Scibetta C. (2019). Green Walls for improving energy efficiency of buildings, Calitatea, 20(S2): 157-161.
  11. Charoenkit S. and Yiemwattana S. (2016). Living walls and their contribution to improved thermal comfort and carbon emission reduction: a review. Build Environ, 105: 82-94.
  12. Chen Q., Li B. and Liu X. (2013). An experimental evaluation of the living wall system in hot and humid climate. Energy Build, 61: 298- 307.
  13. Coma J., Pérez G., de Gracia A., Burés S., Urrestarazu M. and Cabeza L.F. (2017). Vertical greenery systems for energy savings in buildings: A comparative study between green walls and green facades. Build Environ, 111: 228-37.
  14. Cook-Patton S.C., McArt S.H., Parachnowitsch A.L., Thaler J.S. and Agrawal A.A. (2011). A direct comparison of the consequences of plant genotypic and species diversity on communities and ecosystem function. Ecology, 92: 915-923.
  15. Fang C.F. (2008). Evaluating the thermal reduction effect of plant layers on rooftops. Energy Build, 40: 1048-1052.
  16. Feng Y., Wang P. and Wu Z. (2013). Research on the ecological effects for different types of green roofs in Chongqing. China J South Agric, 7: 17-20.
  17. Fernandez-Cañero R., Emilsson T., Fernandez-Barba C. and Herrera Machuca M.A. (2013). Green roof systems: A study of public attitudes and preferences in southern Spain. J Environ Manage, 128: 106-115.
  18. Francis, R.A. and Lorimer, J. (2011). Urban reconciliation ecology: the potential of living roofs and walls. J Environ Manage, 92: 1429-1437.
  19. Getter K.L., Rowe D.B., Andresen J.A. and Wichman I.S. (2011). Seasonal heat flux properties of an extensive green roof in a Midwestern US climate. Energy Build, 43: 3548-3557.
  20. Gibbs D. and O’Neill K. (2015). Building a green economy. Sustainability transitions in the UK building sector. Geoforum, 59: 133-141.
  21. Haggag M., Hassan A. and Elmasry S. (2014). Experimental study on reduced heat gain through green facades in a high heat load climate. Energy Build, 82: 668-674.
  22. Ip K., Lam M. and Miller A. (2010). Shading performance of a vertical deciduous climbing plant canopy. Build Environ, 45: 81-87.
  23. Jim C.Y. (2015). Thermal performance of climber greenwalls: effects of solar irradiance and orientation. Appl Energy, 154: 631-643.
  24. Koyama T., Yoshinaga M., Hayashi H., Maeda K. and Yamauchi A. (2013). Identification of key plant traits contributing to the cooling effects of green facades using freestanding walls. Build Environ, 66: 96-103.
  25. Kontoleon K.J. and Eumorfopoulou E.A. (2010). The effect of the orientation and proportion of a plant-covered wall layer on the thermal performance of a building zone. Build Environ, 45: 1287-1303.
  26. Lazzarin R.M., Castellotti F. and Busato F. (2005). Experimental measurements and numerical modelling of a green roof. Energy Build, 37: 1260-1267.
  27. Lin Y.J. and Lin H.T. (2011). Thermal performance of different planting substrates and irrigation frequencies in extensive tropical rooftop greeneries. Build Environ, 46: 345-355.
  28. Luo H., Liu X., Anderson B.C., Zhang K., Li X. and Huang B. (2015). Carbon sequestration potential of green roofs using mixed-sewage-sludge substrate in Chengdu World Modern Garden City. Ecol Indic, 49: 247-259.
  29. Marchi M., Pulselli R.M., Marchettini N., Pulselli F.M. and Bastianoni S. (2015). Carbon dioxide sequestration model of a vertical greenery system. Ecol Model, 306: 46-56.
  30. Mazzali U., Peron F., Romagnoni P., Pulselli R.M. and Bastianoni S. (2013). Experimental investigation on the energy performance of Living Walls in a temperate climate. Build Environ, 64: 57-66.
  31. McPherson E.G., Herringtonn L.P. and Heisler G.M. (1988). Impacts of vegetation on residential heating and cooling. Energy Build, 12: 41-51.
  32. Morau D., Libelle T. and Garde F. (2012). Performance evaluation of green roof for thermal protection of buildings in Reunion Island. Energy Procedia, 14: 1008-1016.
  33. Nori C., Olivieri F., Grifoni R.C. and Bedoya C. (2013). Testing the performance of a green wall system on an experimental building in the summer. PLEA-29th conference. Sustainable architecture for a renewable future, Munich, Germany.
  34. Olivieri F., Olivieri L. and Neila J. (2014). Experimental study of the thermal-energy performance of an insulated vegetal facade under summer conditions in a continental mediterranean climate. Build Environ, 77: 61-76.
  35. Othman A.R. and Sahidin N. (2016). Vertical greening facade as passive approach in sustainable design. Procedia – Soc Behav Sci, 222: 845-854.
  36. Ouldboukhitine S.E., Belarbi R., Jaffal I. and Trabelsi A. (2011). Assessment of green roof thermal behavior: a coupled heat and mass transfer model. Build Environ, 46: 2624-2631.
  37. Papadakis G., Tsamis P. and Kyritsis S. (2001). An experimental investigation of the effect of shading with plants for solar control of buildings. Energy Build, 33: 831-836.
  38. Payne S.R. (2013). The production of a perceived restorativeness soundscape scale. Appl Acoust, 74: 255-263.
  39. Peng L.L.H. and Jim C.Y. (2013). Green-roof Effects on Neighborhood Microclimate and Human Thermal Sensation. Energies, 6: 598-618.
  40. Pérez G., Rincón L., Vila A., González J.M. and Cabeza L.F. (2011). Behaviour of green facades in Mediterranean Continental climate. Energy Convers Manage, 52: 1861-1867.
  41. Pérez G., Coma J., Sol S. and Cabeza L.F. (2017). Green facade for energy savings in buildings: The influence of leaf area index and facade orientation on the shadow effect. Appl Energy, 187: 424-437.
  42. Perini K., Ottelé M., Fraaij A.L.A., Haas E.M. and Raiteri R. (2011). Vertical greening systems and the effect on air flow and temperature on the building envelope. Build Environ, 46: 2287-2294.
  43. Perini K. and Rosasco P. (2013). Cost-benefit analysis for green facades and living wall systems. Build Environ, 70: 110-121.
  44. Perini K., Bazzocchi F., Croci L., Magliocco A. and Cattaneo E. (2017). The use of vertical greening systems to reduce the energy demand for air conditioning. Field monitoring in Mediterranean climate. Energy Build, 143: 35-42.
  45. Permpituck S.and Namprakai P. (2012). The energy consumption performance of roof lawn gardens in Thailand. Renewable Energy, 40: 98-103.
  46. Pompeii I. (2010). Assessing urban heat island mitigation using green roofs: a hard ware scale modeling approach. Pennysylvania, USA: Shippensburg University.
  47. Raji B., Tenpierik M.J. and van den Dobbelsteen A. (2016). An assessment of energy-saving solutions for the envelope design of high-rise buildings in temperate climates: a case study in the Netherlands. Energy Build, 124: 210-221.
  48. Rowe D.B. (2011). Green roofs as a means of pollution abatement. Environmental Pollution, 159: 2100-2110.
  49. Saadatian O., Sopian K., Salleh E., Lim C.H., Riffat S., Saadatian E., Toudeshki A.
  50. and Sulaiman M.Y. (2013). A review of energy aspects of green roofs. Renew Sustain Energy Rev, 23: 155-168.
  51. Santamouris M. (2014). Cooling the cities – a review of reflective and green roof mitigation technologies to fight heat island and improve comfort in urban environments. Sol Energy, 103: 682-703.
  52. Schumann L. (2007). Ecologically inspired design of green roof retrofit. M.S. thesis, Biological Resources Engineering, University of Maryland, College Park.
  53. Shafique M., Kim R. and Rafiq M. (2018). Green roof benefits, opportunities and challenges - A review. Renew Sustain Energy Rev, 90: 757-773.
  54. Silva C.M., Gomes M.G., Silva M. (2016). Green roofs energy performance in Mediterranean climate. Energy Build, 116: 318-325.
  55. Sunakorn P. and Yimprayoon C. (2011). Thermal performance of biofacade with natural ventilation in the tropical climate. Procedia Eng, 21: 34-41.
  56. Susca T., Gaffin S.R. and Dell’Osso G. (2011). Positive effects of vegetation: Urban heat island and green roofs. Environmental Pollution, 159: 2119-2126.
  57. Susorova I., Angulo M., Bahrami P. and Brent S. (2013). A model of vegetated exterior facades for evaluation of wall thermal performance. Build Environ, 67: 1-13.
  58. Tarran J., Torpy F. and Burchett M. (2007). Use of living pot-plants to cleanse indoor air - Research review. Sixth international conference on indoor air quality, Ventilation & Energy Conservation in Buildings, III: 249-256.
  59. Tian Y. and Jim C.Y. (2011). Factors influencing the spatial pattern of sky gardens in the compact city of Hong Kong. Landscape Urban Plann, 101: 299-309.
  60. Tilley D., Price J., Matt S. and Marrow B. (2012). Vegetated walls: thermal and growth properties of structured green facades. Final report to green roofs for healthy cities-green walls group.
  61. Vijayaraghavan K. (2016). Green roofs: a critical review on the role of components, benefits, limitations and trends. Renew Sustain Energy Rev, 57: 740-752.
  62. Wong N.H., Kwang Tan A.Y., Tan P.Y., Chiang K. and Wong N.C. (2010). Acoustics evaluation of vertical greenery systems for building walls. Build Environ, 45: 411-420.
  63. Xiao M., Lin Y., Han J. and Zhang G. (2014). A review of green roof research and development in China. Renew Sustain Energy Rev, 40: 633-648.
  64. Yin H., Kong F., Middel A., Dronova I., Xu H. and James P. (2017). Cooling effect of direct green facades during hot summer days: an observational study in Nanjing, China using TIR and 3DPC data. Build Environ, 116: 195-206.
  65. Zhang Q., Miao L., Wang X., Liu D., Zhu L., Zhou B. and Liu J. (2015). The capacity of greening roof to reduce stormwater runoff and pollution. Lands Urban Plan, 144: 142-150.
  66. Zinzi M. and Agnoli S. (2012). Cool and green roofs. An energy and comfort comparison between passive cooling and mitigation urban heat island techniques for residential buildings in the Mediterranean region. Energy Build, 55: 66-76.



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Noemi Caltabellotta, Felicia Cavaleri, Carlo Greco, Kestutis Navickas, Carlo Scibetta, Laura Giammanco, in "RIVISTA DI STUDI SULLA SOSTENIBILITA'" 2 Suppl./2019, pp. 61-78, DOI:10.3280/RISS2019-002-S1005

   

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