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8. Thermographic Analysis of Green Wall and Green Roof Plant Types under Levels of Water Stress.

Author

Elkadi, Hisham, Seifhashemi, Mahsa, and Lauwerijssen, Rachel

Abstract

Urban green infrastructure (UGI) plays a vital role in mitigating climate change risks, including urban development-induced warming. The effective maintenance and monitoring of UGI are essential for detecting early signs of water stress and preventing potential fire hazards. Recent research shows that plants close their stomata under limited soil moisture availability, leading to an increase in leaf temperature. Multi-spectral cameras can detect thermal differentiation during periods of water stress and well-watered conditions. This paper examines the thermography of five characteristic green wall and green roof plant types (Pachysandra terminalis, Lonicera nit. Hohenheimer, Rubus tricolor, Liriope muscari Big Blue, and Hedera algeriensis Bellecour) under different levels of water stress compared to a well-watered reference group measured by thermal cameras. The experiment consists of a (1) pre-test experiment identifying the suitable number of days to create three different levels of water stress, and (2) the main experiment tested the suitability of thermal imaging with a drone to detect water stress in plants across three different dehydration stages. The thermal images were captured analyzed from three different types of green infrastructure. The method was suitable to detect temperature differences between plant types, between levels of water stress, and between GI types. The results show that leaf temperatures were approximately 1–3 °C warmer for water-stressed plants on the green walls, and around 3–6 °C warmer on the green roof compared to reference plants with differences among plant types. These insights are particularly relevant for UGI maintenance strategies and regulations, offering valuable information for sustainable urban planning. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Reconstructing Energy-Efficient Buildings after a Major Earthquake in Hatay, Türkiye.

Author

Saleh, Yousif Abed Saleh, Gokcen Akkurt, Gulden, and Turhan, Cihan

Subjects
ENERGY consumption of buildings, DISASTER resilience, VERTICAL gardening, SUSTAINABLE design, EARTHQUAKES
Abstract

Türkiye's earthquake zone, primarily located along the North Anatolian Fault, is one of the world's most seismically active regions, frequently experiencing devastating earthquakes, such as the one in Hatay in 2023. Therefore, reconstructing energy-efficient buildings after major earthquakes enhances disaster resilience and promotes energy efficiency through retrofitting, renovation, or demolition and reconstruction. To this end, this study proposes implementing energy-efficient design solutions in dwelling units to minimize energy consumption in new buildings in Hatay, Southern Turkiye, an area affected by the 2023 earthquake. This research focused on a five-story residential building in the district of Kurtlusarımazı, incorporating small-scale Vertical-Axis Wind Turbines (VAWTs) with thin-film photovoltaic (PV) panels, along with the application of a green wall surrounding the building. ANSYS Fluent v.R2 Software was used for a numerical investigation of the small-scale IceWind turbine, and DesignBuilder Software v.6.1.0.006 was employed to simulate the baseline model and three energy-efficient design strategies. The results demonstrated that small-scale VAWTs, PV panels, and the application of a green wall reduced overall energy use by 8.5%, 18%, and 4.1%, respectively. When all strategies were combined, total energy consumption was reduced by up to 28.5%. The results of this study could guide designers in constructing innovative energy-efficient buildings following extensive demolition such as during the 2023 earthquake in Hatay, Türkiye. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Advancing Methodologies for Investigating PM 2.5 Removal Using Green Wall System.

Author

Falzone, Claudia, Jupsin, Hugues, El Jarroudi, Moussa, and Romain, Anne-Claude

Subjects
VERTICAL gardening, INDUCTIVELY coupled plasma mass spectrometry, INDOOR air pollution
Abstract

Combustion processes are the primary source of fine particulate matter in indoor air. Since the 1970s, plants have been extensively studied for their potential to reduce indoor air pollution. Leaves can retain particles on their surfaces, influenced by factors such as wax content and the presence of hairs. This study introduces an innovative experimental approach using metal oxide particles in an office-like environment to evaluate the depolluting effect of plant walls. Two plant walls were installed in a controlled room, housing three plant species: Aglaonema commutatum 'Silver Bay', Dracaena fragrans, and Epipremnum aureum. Metal oxide particles were introduced via a compressed air blower positioned between the two walls. The concentration of these particles was monitored using PM2.5 sensors, and the deposition of iron (Fe) on the leaves was quantified through Inductively Coupled Plasma Mass Spectrometry (ICP-MS). This novel methodology effectively demonstrated the utility of both real-time sensors and ICP-MS in quantifying airborne particle concentrations and leaf deposition, respectively. The results revealed that Dracaena fragrans had a 44% higher Fe particle retention rate compared to the control (wallpaper). However, further validation through methodological replication is necessary to confirm the reproducibility of these findings. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Analysis of the impact of growing green walls based on the reduction of PM2.5 particles in the resilient central urban fabric

Author

Mohadese Borna and Mansour Yeganeh

Subjects
green wall, reduction of air pollution, urban wall, plants, pattern of greenery, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9
Abstract

The problems of today’s world, particularly climate change and air pollution, require the search for sustainable and green buildings in urban environments and the people who inhabit them. General population and construction industry has emitted pollutants such as carbon dioxide to the atmosphere due to urbanization and rise in vehicles. In addition to that, the products employed in construction express a caliber of polluting the air. Urban facades and the materials used for construction in cities can often have a significant impact on aggravating air pollution. The implementation of green walls on building’s facade and other structures can be considered as the proper substitute to utilizing the stone and cement as those materials minimize the emission of air pollutants and add the better aesthetics to the city environment. The main objectives of this research are to describe and introduce a new method of applying green facades for buildings and structures using plants which have even greater abilities at absorbing pollutants and are simpler in application and management in comparison with other systems of green walls. In the first stage, the known green wall systems and along with suitable plants were introduced and studied through library studies and accordingly the most compatible plants for the studied area, considering the climate of Iran, specially Tehran which is the most polluted city in Iran, were identified. The ENVI-met application was used subsequently to determine the most appropriate model or plant to combat the pollutants in the environment.

Published
2024
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12. Sustainable Design of Vertical Greenery Systems: A Comprehensive Framework.

Author

Manouchehri, Mitra, Santiago López, Joaquín, and Valiente López, Mercedes

Abstract

The greening of buildings' facades is not a new practice; it has been used since ancient times for protection and aesthetic purposes. Nowadays, the approach used towards the greening of facades has changed considerably. Vertical greenery systems (VGS) have been proposed as one of the innovative solutions to promote sustainable building functions. Present-day facade greenery not only offers traditional architectural potential but also incorporates advanced materials and technologies to adapt to the requirements of modern urban life. In recent years, the number of buildings that use this technology has increased considerably, and accordingly, the technology involved and the methods of application have changed to be in line with the new necessities. Various types of VGS have been introduced to provide users with a wider range of options that are applicable in different climates and conditions. As a result, different methods of VGS implementation have been adopted; however, there is no established standardization for VGS designs or their variations. Choosing the proper type of VGS is a crucial step in the decision-making process for VGS design. In this research, we provide an overview of the most significant existing classifications of vertical greenery systems and propose a comprehensive classification based on an analysis of their features and classification criteria. Moreover, influential factors in VGS design are investigated. This article presents a comprehensive framework for the sustainable design of vertical greenery systems by outlining the primary parameters that are crucial to identifying and selecting the most suitable type of VGS. The framework also incorporates design aspects, thus stressing the necessity of considering changes to attributes that could affect the overall functionality of a VGS and, as a result, impact the decision-making process. The results of this study provide a valuable resource to systematically study greenery systems, and their parameters, and also to make informed decisions that are aligned with current the sustainability objectives of future research in terms of cost, energy consumption, and maintenance. [ABSTRACT FROM AUTHOR]

Published
2024
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13. The Collapse of the Green Wall.

Author

Grant, Wyn

Subjects
*VERTICAL gardening, *AGRICULTURE, *FOOD security, *RURAL geography, *BRITISH withdrawal from the European Union, 2016-2020
Abstract

The Conservative Party has usually done well in rural areas, but its 'green wall' is now under threat from Labour more than the Liberal Democrats. Farmers did not support Brexit any more than the general population, and in income terms they are currently doing well, but fear for the future. In addition, food security issues are more complex than they are portrayed, as are the relations with the devolved governments. In Scotland, the government there is much more popular among Scottish farmers whilst the government in Wales is doing much worse among farming communities. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Managing the thermal impact of green walls on internal spaces of AQABA buildings.

Author

Al-Khlouf, Maryam and Tarawneh, Sultan

Subjects
VERTICAL gardening, THERMAL comfort, GLOBAL warming, THERMAL efficiency, FACADES, HOT weather conditions
Abstract

Green wall systems have been introduced all over the world as a sustainable solution to combat the hot environment inside buildings and provide thermal comfort by improving the thermal efficiency of the buildings. This study aims to find out whether green walls can be used to manage the inside thermal conditions of Aqaba buildings. It is intended to lessen the impact of Aqaba's harsh warm climate on internal building spaces and achieve a thermal comfort level. A physical live experiment was used to detect the thermal impact of green walls on internal spaces. The thermal performances of two identical real-scale test rooms, one of which had a fixed green facade, were compared. This study concludes that green facades have a significant potential to promote buildings' thermal behaviour in the hot summer of Aqaba and thermally similar regions. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Evaluation of Greywater as a Sustainable Source of Irrigation for Ornamental Crops in Green Walls—A Study of Plant and Soil Using Ruellia tuberosa.

Author

Anangadan, Shaheeda Marakkar, Pradhan, Snigdhendubala, Saththasivam, Jayaprakash, McKay, Gordon, and Mackey, Hamish Robert

Abstract

Green walls and roofs are sustainable building systems with several benefits. However, the irrigation requirements of these building systems conflict with water sustainability goals in water-scarce places. This study investigates using greywater directly to irrigate ornamental species for such situations by examining the effects of freshwater and greywater irrigation on Ruellia tuberosa growth, plant health and soil characteristics. Five replicates for each condition were grown for 91 days. Greywater irrigation led to a 15% higher plant growth height, a 31% higher plant biomass (p = 0.065), and a 71% increase in stem biomass (p < 0.001) compared to freshwater irrigation. However, greywater-irrigated plants had reduced chlorophyll content (10.7%, p < 0.001), and increased leaf chlorosis (p = 0.003), likely caused by stress from laundry and detergent chemicals. Greywater irrigation led to greater mineral content in greywater-irrigated plant biomass and soil for all minerals tested, most notably boron, which was deficient in the soil. Greywater-irrigated soil also had a higher organic content according to FTIR and electron dispersive spectroscopy. Greywater irrigation improved nutritional and soil conditions, including phosphate, which helped Ruellia tuberosa flourish. This study suggests raw greywater can replace freshwater in water-scarce climates for green wall irrigation instead of high-energy onsite greywater treatment systems. [ABSTRACT FROM AUTHOR]

Published
2024
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16. A strategy for giving urban public green spaces a third dimension: A case study of Qasrodasht, Shiraz

Author

Elham Zarie, Borhan Sepehri, Mohammad Anvar Adibhesami, Mohammad Reza Pourjafar, and Hirou Karimi

Subjects
Green roof, Green wall, Third dimension, Urban public green space, Design framework, Qasrodasht, Environmental sciences, GE1-350
Abstract

With the increasing in urbanization and uncontrolled development of cities over the last decade, designing public urban green spaces as nature-based solutions has become imperative due to their positive health and economic impacts. The Qasrodasht neighborhood in Shiraz, Iran has suffered from haphazard construction and loss of public open space. This study demonstrates the potential for expanding and revitalizing urban public green spaces in Qasrodasht by proposing a framework for designing them in the vertical dimension. 25 experts in urban planning, design, and architecture were interviewed extensively. The interview questions were selected via literature review and SWOT analysis, with each interview lasting 20 min online. The data were analyzed and presented in a table. Ultimately, this study presents design alternatives, a framework for vertically-oriented public green space design, and policies and strategies for implementing such designs in Qasrodasht through expert interviews.

Published
2024
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17. Toward Precision Agriculture in Outdoor Vertical Greenery Systems (VGS): Monitoring and Early Detection of Stress Events.

Author

Zuckerman, Noa, Cohen, Yafit, Alchanatis, Victor, and Lensky, Itamar M.

Subjects
*VERTICAL farming, *URBAN heat islands, *DECISION support systems, *WATER distribution, *PRECISION farming, *IRRIGATION management, *CITIES & towns, *AGRICULTURE
Abstract

Vertical greenery systems (VGS) have been proposed as a nature-based solution to mitigate the adverse effects of urban heat islands and climate change in cities. However, large-scale VGS are costly and require ongoing maintenance, typically carried out manually through trial and error based on professional experience. Advanced management is essential for the sustainability of VGS due to its limited accessibility and associated costs. To address these challenges, we examined the use of remote sensing methods for outdoor VGS monitoring as a basis for a precision agriculture approach for VGS management and maintenance. This study presents the first ongoing monitoring of real-scale VGS using thermal, hyperspectral, and RGB vegetation indices. These indices were employed for the early detection of vegetation stress, focusing on two case studies exhibiting visible yellowing symptoms. Through the application of unsupervised classification techniques, stressed pixels were successfully detected 14–35 days before visual yellowing, achieving an accuracy of 0.85–0.91. Additionally, the thermal index provided valuable information regarding the spatial distribution of watering along the VGS. Stress maps based on noninvasive methods were demonstrated, forming the basis of a spatial decision support system capable of detecting issues related to plant vitality and VGS irrigation management. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Fuelling phytoremediation: gasoline degradation by green wall systems—a case study.

Author

Matheson, Stephen, Fleck, Robert, Lockwood, Thomas, Gill, Raissa L, Irga, Peter J, and Torpy, Fraser R

Subjects
VERTICAL gardening, BENZENE derivatives, PHYTOREMEDIATION, VOLATILE organic compounds, SERVICE stations, GASOLINE
Abstract

The capacity for indoor plants including green wall systems to remove specific volatile organic compounds (VOCs) is well documented in the literature; however under realistic settings, indoor occupants are exposed to a complex mixture of harmful compounds sourced from various emission sources. Gasoline vapour is one of the key sources of these emissions, with several studies demonstrating that indoor occupants in areas surrounding gasoline stations or with residentially attached garages are exposed to far higher concentrations of harmful VOCs. Here we assess the potential of a commercial small passive green wall system, commercially named the 'LivePicture Go' from Ambius P/L, Australia, to drawdown VOCs that comprise gasoline vapour, including total VOC (TVOC) removal and specific removal of individual speciated VOCs over time. An 8-h TVOC removal efficiency of 42.45% was achieved, along with the complete removal of eicosane, 1,2,3-trimethyl-benzene, and hexadecane. Further, the green wall also effectively reduced concentrations of a range of harmful benzene derivatives and other VOCs. These results demonstrate the potential of botanical systems to simultaneously remove a wide variety of VOCs, although future research is needed to improve upon and ensure efficiency of these systems over time and within practical applications. [ABSTRACT FROM AUTHOR]

Published
2023
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19. Enhancing Urban Microclimates: Potential Benefits of Greenery Strategies in a Semi-Arid Environment.

Author

Brahimi, Mohamed, Benabbas, Moussadek, Altan, Hasim, Nocera, Francesco, and Costanzo, Vincenzo

Abstract

The emergence of sustainable development gives greenery an important role in urban planning, namely, by recognizing its environmental potential. However, the rapid urbanization that most cities have experienced in the absence of a sustainable urban policy has led to the establishment of urban realms dominated by manmade constructions. This research aims to evaluate the greening's effect on the urban climate within the semi-arid city of Djelfa (Algeria) during summertime by assigning the most appropriate greenery strategy to ensure optimal thermal conditions. Using a numerical model built with the ENVI-met tool and validated through measurements in situ, four different scenarios are simulated, starting with the existing area and then changing the greenery strategies. The outputs include meteorological parameters and thermal comfort indices (PET and UTCI). The results show that the green area generates a cool island within the urban fabric, with the peak daytime air temperature being reduced by about 4.75 °C. Vegetation densification in the urban space has a higher cooling performance than greening buildings during the daytime. In the evening, the canopy effect of trees is lower and the wind velocity is reduced, which is the main driver in cooling the city at nighttime. [ABSTRACT FROM AUTHOR]

Published
2023
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20. Reconstructing Energy-Efficient Buildings after a Major Earthquake in Hatay, Türkiye

Author

Yousif Abed Saleh Saleh, Gulden Gokcen Akkurt, and Cihan Turhan

Subjects
residential buildings, vertical-axis wind turbine, PV panels, green wall, earthquake, energy-efficient design, Building construction, TH1-9745
Abstract

Türkiye’s earthquake zone, primarily located along the North Anatolian Fault, is one of the world’s most seismically active regions, frequently experiencing devastating earthquakes, such as the one in Hatay in 2023. Therefore, reconstructing energy-efficient buildings after major earthquakes enhances disaster resilience and promotes energy efficiency through retrofitting, renovation, or demolition and reconstruction. To this end, this study proposes implementing energy-efficient design solutions in dwelling units to minimize energy consumption in new buildings in Hatay, Southern Turkiye, an area affected by the 2023 earthquake. This research focused on a five-story residential building in the district of Kurtlusarımazı, incorporating small-scale Vertical-Axis Wind Turbines (VAWTs) with thin-film photovoltaic (PV) panels, along with the application of a green wall surrounding the building. ANSYS Fluent v.R2 Software was used for a numerical investigation of the small-scale IceWind turbine, and DesignBuilder Software v.6.1.0.006 was employed to simulate the baseline model and three energy-efficient design strategies. The results demonstrated that small-scale VAWTs, PV panels, and the application of a green wall reduced overall energy use by 8.5%, 18%, and 4.1%, respectively. When all strategies were combined, total energy consumption was reduced by up to 28.5%. The results of this study could guide designers in constructing innovative energy-efficient buildings following extensive demolition such as during the 2023 earthquake in Hatay, Türkiye.

Published
2024
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21. Advancing Methodologies for Investigating PM2.5 Removal Using Green Wall System

Author

Claudia Falzone, Hugues Jupsin, Moussa El Jarroudi, and Anne-Claude Romain

Subjects
climatic chamber, dry deposition, green wall, indoor air quality, PM2.5, Botany, QK1-989
Abstract

Combustion processes are the primary source of fine particulate matter in indoor air. Since the 1970s, plants have been extensively studied for their potential to reduce indoor air pollution. Leaves can retain particles on their surfaces, influenced by factors such as wax content and the presence of hairs. This study introduces an innovative experimental approach using metal oxide particles in an office-like environment to evaluate the depolluting effect of plant walls. Two plant walls were installed in a controlled room, housing three plant species: Aglaonema commutatum ‘Silver Bay’, Dracaena fragrans, and Epipremnum aureum. Metal oxide particles were introduced via a compressed air blower positioned between the two walls. The concentration of these particles was monitored using PM2.5 sensors, and the deposition of iron (Fe) on the leaves was quantified through Inductively Coupled Plasma Mass Spectrometry (ICP-MS). This novel methodology effectively demonstrated the utility of both real-time sensors and ICP-MS in quantifying airborne particle concentrations and leaf deposition, respectively. The results revealed that Dracaena fragrans had a 44% higher Fe particle retention rate compared to the control (wallpaper). However, further validation through methodological replication is necessary to confirm the reproducibility of these findings.

Published
2024
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22. Preliminary Experimental Laboratory Methods to Analyse the Insulation Capacity of Vertical Greening on Temperature and Relative Humidity.

Author

De Groeve, Marie, Kale, Eda, Orr, Scott Allan, and De Kock, Tim

Abstract

Ground-based vertical greening is one of the well-known nature-based solutions that is widely used in city centres due to its small footprint and the large surface area of vegetation. Although the impact of vertical greening on the local microclimate has already been extensively researched, there is a poor understanding of the impact of vertical greening on historic building fabrics. The impact of vertical greening on microclimate environments has primarily been researched through in situ case-study monitoring; as such, there are currently no standard protocols for investigating this impact in laboratory studies. By performing simulations in controlled laboratory conditions, the influence of vertical greening on specific environmental conditions can be assessed as well as the significance for key mechanisms, such as the insulation capacity of a vegetation layer. Experimental results on the insulation capacity of vertical greening illustrate that the presence of vertical greening reduces the rate of heat exchange between the wall and the surrounding environment compared to the bare wall, resulting in a delayed temperature response of the wall. This delay varies across the seasons or its intensity, which is represented, for instance, by a more pronounced delay in the wall's surface temperature response in summer than in winter. However, the magnitude of the insulation capacity is more pronounced in winter (up to +2.1 °C) compared to summertime. The insulation capacity of vertical greening is more likely to have a significant impact on façades with a lack of solar irradiation, such as façades facing north or shaded by built surroundings. This experimental investigation can help build an understanding of these processes more fundamentally and support the interpretation of in situ case-study monitoring as well as provide a standardized approach to investigate the environmental performance of vertical greening across climatic regions and seasons. [ABSTRACT FROM AUTHOR]

Published
2023
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23. A Novel Strategy for Converting Conventional Structures into Net-Zero-Energy Buildings without Destruction.

Author

Alghamdi, Hisham and Alviz-Meza, Aníbal

Abstract

The majority of energy consumption is attributed to buildings. Buildings designed with environmentally sustainable features have the potential to reduce energy consumption. The demolition of ecologically detrimental structures incurs expenses and damages the natural environment. The act of constructing models for the purpose of destruction was deemed superfluous. The replication of the structural model was accompanied by a modification of the design, and a variety of tactics were employed. The proposed upgrades for the building include the installation of new windows, incorporation of greenery on the walls and roof, implementation of insulation, and integration of solar panels in a four-story residential building in Najran, Saudi Arabia. Simultaneously installing insulation prior to changing windows will ensure that the energy consumption of the building, green wall, or green roof will remain unaffected. The installation of solar panels on the walls and top roof of a structure has the potential to generate a monthly electricity output up to two times greater than the structure's consumption. The spas can be heated on a daily basis by substituting the heating system with solar collectors. The implementation of sustainable building practices has resulted in a significant reduction in energy consumption. Specifically, electricity, gas, heating, and cooling consumption decreased by 11%, 85%, 28%, and 83%, respectively. [ABSTRACT FROM AUTHOR]

Published
2023
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24. Analysis of the Microclimatic and Biodiversity-Enhancing Functions of a Living Wall Prototype for More-than-Human Conviviality in Cities.

Author

Bornschlegl, Sebastian, Krause, Pia, Kropp, Cordula, and Leistner, Philip

Subjects
VERTICAL gardening, CITIES & towns, GREEN infrastructure, URBAN biodiversity, PROTOTYPES, BUILDING-integrated photovoltaic systems
Abstract

This study analyzes the growing trend of urban green infrastructures, particularly green façade systems, in terms of their infrastructural relationships between nature and culture and their potential to act as bioclimatic layers mediating between the needs of flora, fauna and human habitation. An interdisciplinary approach is taken by combining the perspectives of social and engineering sciences to discuss the contribution of green façade systems for more-than-human conviviality in cities. Green infrastructures can support this endeavor by enabling functions that help to integrate the heterogeneity typical for semi-natural structures into urban ones, especially regarding microclimatic and biodiversity-enhancing functions. The theoretical distinction between "gray", "green", and "revolutionary" infrastructure is used to differentiate between conventional and posthumanist conceptualizations of urban naturecultures. The performance of the UNA TERRA living wall prototype as a green and revolutionary infrastructure is evaluated. The results show that the living wall has beneficial microclimatic effects and adds a heterogeneous habitat structure that supports biodiversity in the urban context. By adhering to "egalitarian humility" in design, the uncertainty and openness of more-than-human conviviality are acknowledged. The study finds that green infrastructures such as green façade systems can fulfill the criteria of revolutionary infrastructure if the contribution to local biodiversity and structural complexity is prioritized and the heterogeneous interrelations between human and non-human actors are taken into account. [ABSTRACT FROM AUTHOR]

Published
2023
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25. Quantifying the impact of meteorological factors and green infrastructure location on particulate matter (PM) mitigation in Republic of North Macedonia using sensor collected data

Author

Mare Srbinovska, Vesna Andova, Aleksandra Krkoleva Mateska, Maja Celeska Krstevska, Marija Cundeva-Blajer, Matej Kutirov, and Martin Majstoroski

Subjects
Sensor data, Air pollution reduction, Green wall, Particulate matter, Meteorological factors, Sensor network, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4
Abstract

Low quality of the air is becoming a major concern in urban areas. High values of particulate matter (PM) concentrations and various pollutants may be very dangerous for human health and the global environment. The challenge to overcome the problem with the air quality includes efforts to improve healthy air not only by reducing emissions, but also by modifying the urban morphology to reduce the exposure of the population to air pollution.The aim of this contribution is to analyse the influence of the green zones on air quality mitigation through sensor measurements, and to identify the correlation with the meteorological factors. Actually, the objective focuses on identifying the most significant correlation between PM2.5 and PM10 concentrations and the wind speed, as well as a negative correlation between the PM concentrations and wind speed across different measurement locations. Additionally, the estimation of slight correlation between the PM concentrations and the real feel temperature is detected, while insignificant correlations are found between the PM concentrations and the actual temperature, pressure, and humidity.In this paper the effect of the pandemic restriction rules COVID-19 lockdowns and the period without restriction are investigated. The sensor data collected before the pandemic (summer months in 2018), during the global pandemic (summer months 2020), and after the period with restriction measures (2022) are analysed.

Published
2023
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26. Vertical Greening Systems: A Perspective on Existing Technologies and New Design Recommendation.

Author

Irga, Peter J., Torpy, Fraser R., Griffin, Daniel, and Wilkinson, Sara J.

Abstract

Vertical greening systems (VGSs) represent an emerging technology within the field of building-integrated horticulture that have been used to help counteract the global issues of urbanisation and climate change. Research and development within the field of building-integrated horticulture, despite being in the infancy stage, is steadily progressing, highlighting a broad range of achievable social, environmental, and economic benefits this sustainable development technology could provide. However, as VGS technology is relatively new, an array of different designs and technologies have been categorized collectively as VGSs, each having various performances towards the proposed and desired benefits. The purpose of this paper is to review existing VGS technologies and analyse the impact of implementation on sustainable development, and subsequently to propose a new VGS design that theoretically achieves the best possible outcomes when aiming to obtain the maximum benefits of installing a VGS. The resultant design creates new opportunities for VGS environmental amenities and maintenance, increases the scope of applications, and improves the environmental performance of the host building. The proposed design has the potential to transform VGSs beyond conventional functions of aesthetic greening to create novel ecosystems, which enhances the formation of habitats for a more diverse range of flora and fauna. [ABSTRACT FROM AUTHOR]

Published
2023
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27. Health and Well-Being Benefits of Outdoor and Indoor Vertical Greening Systems: A Review.

Author

Fonseca, Fernando, Paschoalino, Marina, and Silva, Lígia

Abstract

Green spaces have become the most threatened by urban growth, and the decline in these areas is a main cause of environmental and social problems with implications for human health and well-being. Vertical greenery systems have been proposed as a solution to restore the connection between the city and nature, particularly in compact and dense cities, where horizontal space is limited. This paper provides a literature review to examine the influence of outdoor and indoor vertical greenery systems on human health and well-being. The Web of Science and Scopus databases were chosen to survey peer-reviewed documents published until October 2022. A total of 73 documents were selected by the search. Over 71% of the documents were published over the last four years, and most of them focused on the environmental and thermal benefits of vertical greenery systems. Although these benefits could bring health and well-being outcomes, they were not objectively measured and quantified. Other additional gaps and guidelines for future research were also identified and discussed. This review could be helpful for researchers and urban planners in developing vertical greenery to create healthy and more sustainable cities. [ABSTRACT FROM AUTHOR]

Published
2023
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28. Experimental Assessment of the Thermal Influence of a Continuous Living Wall in a Subtropical Climate in Brazil.

Author

Cruciol-Barbosa, Murilo, Fontes, Maria Solange Gurgel de Castro, and Azambuja, Maximiliano dos Anjos

Abstract

A continuous living wall is a vertical garden that allows the cultivation of a wide variety of species on vertical surfaces, consisting of a sequence of layers that shade and add thermal resistance to the external façades of buildings. Thus, the living wall can be an alternative to increase the thermal efficiency of the building and reduce the use of air conditioning for cooling the indoor environment. This work experimentally investigated the thermal influence of a continuous living wall on the surface temperatures of an east façade in a subtropical climate with hot summers (Cfa), during the summer period. The experiment included the implementation of a real living wall in a seasonally used building and the delimitation of two sample plots (i.e., protected and bare wall). Campaigns were carried out to measure the external and internal surface temperatures of the protected plot, the living wall, and the bare wall, as well as the cavity air temperature, from 08:00 to 17:45, at 15-min intervals. The results show the efficiency of the living wall in reducing the external (up to 10.6 °C) and internal (up to 2.9 °C) surface temperatures of the protected plot compared to the bare wall, along with a reduction in thermal variation (average reduction of 6.5 °C externally and 3.6 °C internally) and an increase in thermal delay (up to 6 h for external and 1 h for internal), in addition to a reduction in temperature and greater thermal stability of the cavity between the garden and the protected land in comparison to the external space. [ABSTRACT FROM AUTHOR]

Published
2023
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29. The Influence of Plant Type, Substrate and Irrigation Regime on Living Wall Performance in a Semi-Arid Climate.

Author

Bustami, Rosmina A., Beecham, Simon, and Hopeward, James

Subjects
VERTICAL gardening, IRRIGATION, MUNICIPAL water supply, URBAN planning, IRRIGATION water, GREENHOUSES
Abstract

Living walls are fast becoming a ubiquitous feature of modern living and are widely implemented in commercial buildings in both internal and external environments. However, there are several challenges associated with maintaining healthy plant growth on these water sensitive urban design systems. This experimental study of an instrumented prototype-scale living wall has found that there is a close relationship between the plants, substrates and adopted irrigation regimes. In this study, plant selection was found to be more critical than either substrate or irrigation regime selection. This research also found that both the location of the plants on the wall and irrigation volume significantly affected the plants' ultimate total dry weight. In particular, plants were found to grow taller on the upper section of the living wall compared to the middle and lower sections. It is recommended that particular attention should be given to plant location and the amount of irrigation water supplied at different positions on the living wall. [ABSTRACT FROM AUTHOR]

Published
2023
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30. Simulation of the Energy Performance of a Building with Green Roofs and Green Walls in a Tropical Climate.

Author

Pragati, Saranathan, Shanthi Priya, Radhakrishnan, Pradeepa, Chandramouli, and Senthil, Ramalingam

Abstract

Global temperatures have continued to rise for decades, partly due to human-caused greenhouse gas emissions and subsequent urban heat island (UHI) effects. This current research examines the benefits of urban greenery by studying the impact of green roofs and walls of a building on thermal behavior and heat transfer in a warm and humid climate. This simulation study discusses the importance of greening systems in improving thermal comfort and minimizing the causes of UHI by assessing an integrated green building design. Using the simulation software DesignBuilder, the significance of greening systems, green roofs, and walls in enhancing thermal comfort and reducing the factors that contribute to UHI is investigated. The simulation results are based on the building's energy usage in hot and humid regions while featuring green roofs and walls. The simulation results indicate a considerable positive impact of greening systems in improving the urban environment in hot and humid tropical climates. Air temperature, radiant temperature, humidity, and solar gain are decreased by urban greening. The total energy consumption and district cooling demand of buildings with green roofs and walls are reduced by 10.5% and 13%, respectively. The greening systems substantially improve air quality and building's energy efficiency. Thus, the present study's findings can benefit urban designers and dwellers in devising strategies for establishing green spaces in congested urban environments by integrating green technologies and systems into built environments. [ABSTRACT FROM AUTHOR]

Published
2023
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31. vertECO® vertical green wall system demonstration for domestic wastewater treatment and on-site reuse in an Austrian eco-village.

Author

Vobruba, Tamara, Hartl, Marco, Langergraber, Guenter, Pucher, Bernhard, Gattringer, Heinz, Bertino, Gaetano, Panzenböck, Franz, and Kisser, Johannes

Subjects
*SEWAGE purification, *ESCHERICHIA coli, *VERTICAL gardening, *SEWAGE, *WASTEWATER treatment, *WATER reuse, *GRAYWATER (Domestic wastewater)
Abstract

In recent years, various green wall systems for on-site wastewater treatment have been developed and investigated. One of them, the vertECO®, was created by alchemia-nova and consists of aerated basins aligned stepwise vertically in series having a subsurface horizontal flow hydraulic regime. The system has proven effective for treatment of greywater and the liquid fraction of blackwater in previous studies. To the authors knowledge this study is the first to demonstrate the treatment efficiency of a full-scale green wall system receiving all fractions of domestic wastewater. Four parallel vertECO® system modules were used, with 2 m long basins, receiving a total of 500 L/d of mechanically pre-treated wastewater from an eco-village in Austria. vertECO® purified water is stored in integrated tanks underneath the system and ozonated three times per day while being recirculated in the treated water tanks, aiming at water and nutrient reuse in the local agriculture. Wastewater feeding started in May 2022 and the sampling period extends from November 2022 till July 2023. The organic loading rate based on the cross-sectional surface area (OLR cs) of the systems amounts to 57 g BOD 5 /m2d and 48 g TN/m2d. vertECO® effluent results show that average values are already below EU water reuse regulation thresholds for reclaimed water quality class C (only drip irrigation), and the average effluent values after vertECO® and ozonation combined are below thresholds for class B (BOD 5 ≤ 25 mg/L, TSS ≤ 35 mg/L Legionella <1000 CFU/L and E. coli ≤ 100 CFU/100 mL) and meet Austrian local permit requirements with an average of BOD 5 < 3 mg/L, TSS 1.3 mg/L, Legionella <1 CFU/L and E. coli result of 65 CFU/100 mL, whereas singular sampling event results even reach EU reuse class A (e.g., additional raw eaten vegetables and more can be irrigated). • The vertECO® green wall system was successfully implemnted for treating primary treated domestic wastewater. • With vertECO® and ozonation combined, average effluent values could reach EU water reuse class B. • Already after the vertECO® alone, i.e., without ozonation, the EU water reuse class C could be achieved. [ABSTRACT FROM AUTHOR]

Published
2025
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32. Fuel fumes and foliage: The fate of speciated gasoline VOCs during phytoremediation and their impact on the bacterial phenotype.

Author

Matheson, Stephen, Fleck, Robert, Lockwood, Thomas, Gill, Raissa L., Lyu, Luowen, Irga, Peter J., and Torpy, Fraser R.

Subjects
SOLID phase extraction, VOLATILE organic compounds, INDOOR air quality, VERTICAL gardening, CARBONIC acid
Abstract

The capacity of indoor plants including green walls to capture, deposit and remediate individual volatile organic compounds (VOCs) has been well documented. However, in realistic settings, plant systems are exposed to a complex mixture of VOCs from highly varied various emission sources. Gasoline vapour is one of the major sources of these emissions, containing high concentrations of the carcinogens benzene, toluene, ethylbenzene and xylene (BTEX). Using both solid phase micro extraction (SPME) and quick, easy, cheap, effective, rugged and safe (QuEChERS) sampling techniques, we assessed the dynamics of individual speciated gasoline VOC phytoremediation from the air and uptake within green wall plant species and growth substrates within a small passive green wall system, along with quantifying the phenotypic changes within the plant-associated bacterial communities resulting from gasoline exposure. Over 8 h the green wall system achieved 100% removal of atmospheric benzene, 1,2,3-trimethyl, eicosane and hexadecane, benzene 1,3-diethyl-; 1,3,5 cycloheptatriene,7- ethyl and carbonic acid eicosyl vinyl ester. All plant species tested demonstrated the accumulation 45 petrochemical VOCs (pVOCs) with Spathiphyllum wallisii successfully accumulating the majority of pVOC functional groups after 24 h of gasoline exposure. Within the plants phyllospheric bacterial communities, changes in both cellular complexity and granularity appeared to increase as a result of gasoline exposure, while cell size diminished. This work provides novel findings on the VOC removal processes of botanical systems for realistic and highly toxic VOC profiles. [Display omitted] • All plant species demonstrated an accumulation of a number of petrochemical VOC's. • S. wallisi was observed as the most efficient accumulating the majority of pVOC functional groups after 24 h of gasoline exposure. • Gasoline exposure appeared to favour shifts to smaller less complex and lower DNA active microbial communities within soil and rhizosphere regions. [ABSTRACT FROM AUTHOR]

Published
2024
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33. Research on effects of reducing temperature and CO2 emissions by green wall: Case study of G city.

Author

Im, Jiyeol and Gil, Kyungik

Subjects
*GREENHOUSE gas mitigation, *CARBON dioxide mitigation, *VERTICAL gardening, *CARBON emissions, *SURFACE temperature
Abstract

Climate change is currently the most crucial environmental problem, and policies on responses to climate change are actively being promoted worldwide. Particularly, greenhouse gas emissions in the city have been a continuous reminder of the need to reduce the effects of climate change. There has been interest in reducing greenhouse gas emissions using the green wall. Therefore, this research analyzed the temperature reduction characteristics and performance evaluation of the green wall system based on monitored data. The target area selected was public building. The monitoring point of the wall was the front of the wall with the installation point (glass and behind the green wall), and readings were taken for 10 min. The results of the analysis showed that the surface temperature of the building was affected by the performance of the green wall point during working hours (09:00 to 18:00). Finally, the data and greenhouse gas emissions were analyzed the data and greenhouse gas emissions of 45 to 72 %. • In this research, the effects of the green wall system on the reduction of the temperature of the building surface were analyzed, and performance of the green wall system was evaluated. • Analyzing the change in the temperature of the building's surface over time, the temperature between 12:00 and 17:00 tended to change considerably during the dry period. It was determined that this was affected by sunlight time, and the temperature was lower than that at the point where green wall was applied. • The temperature changes during working hours(09:00–18:00), the performance of the green wall introduction point is distinctly observed. Moreover, in the case of green wall points seems to have the advantage of maintaining the building surface temperature at a stable value. • Cooling energy savings can be expected due to the difference in surface temperature between the green wall installation point and the non-installation point. According to the simulation results of this research, the introduction of the green wall surface will result in a total required power of 104,583 KW/month, CO 2 emission reduction of 48.0 tCO 2 eq/month. • Therefore, the results show that the green wall system can be used as an efficient energy-independence technology for buildings in urban areas. In the future, it is necessary to conduct a long-term data-based performance evaluation through additional research. [ABSTRACT FROM AUTHOR]

Published
2024
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34. Experimental and numerical analysis to assess the substrate hydraulic properties and the retention capacity of a green wall module.

Author

Turco, Michele, Palermo, Stefania Anna, Maiolo, Mario, Pirouz, Behrouz, and Piro, Patrizia

Subjects
*VERTICAL gardening, *NUMERICAL analysis, *URBAN hydrology, *MEDITERRANEAN climate, *GREEN infrastructure
Abstract

Green Wall systems (GW) can be considered suitable solutions to mitigate the adverse effects of urbanisation and climate change. However, although they present similar hydrological processes to other green infrastructure solutions, only a few studies have evaluated their hydrological efficiency. In this regard, the proper evaluation of the growing media's unsaturated hydraulic properties, which are directly linked to the retention capacity, is crucial. Based on this background, the analysis of the green wall systems' hydrological processes is a key aspect of urban hydrology, and it represents a gap to be solved. Thus, we present several experimental investigations on different substrates used as construction materials for a GW coupled with a physically based approach applying the HYDRUS-1D model to identify good growing media to be used in the GW construction under the Mediterranean climate. [ABSTRACT FROM AUTHOR]

Published
2023
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35. Impact of Biochar and Graphene as Additives on the Treatment Performances of a Green Wall Fed with Greywater.

Author

Costamagna, Elisa, Caruso, Alice, Galvão, Ana, Rizzo, Anacleto, Masi, Fabio, Fiore, Silvia, and Boano, Fulvio

Subjects
VERTICAL gardening, GRAYWATER (Domestic wastewater), GRAPHENE, BIOCHAR, DRINKING water, WATER consumption
Abstract

The treatment of greywater (GW, wastewater share excluding toilet flush) through green walls can be beneficial for urban areas, favouring the diffusion of urban vegetation and reducing potable water consumption. Multiple challenges hinder the treatment performance of green walls, including the composition of the filtering material, the number of levels—i.e., rows—and the age of the system. This study investigated graphene as an additive (5%v) to a filtering medium made of coconut fibre, perlite and biochar in an open-air green wall with pots arranged into three levels. The performance of GW treatment was quantified by comparing the physicochemical features of inflow and outflow samples collected weekly over two months. Samples were also collected at each level of the green wall, and the performance of two analogous systems different by age for three months were compared. The results showed that graphene did not significantly improve treatment performance, except for the first level (e.g., 48% vs. 15% for COD, 72% vs. 51% for TSS, with and without graphene respectively). Moreover, GW treatment mostly happened along the first two levels of the green wall, with marginal depletion (e.g., 15% vs. 7% for NH4+-N) after three months of operational time. [ABSTRACT FROM AUTHOR]

Published
2023
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36. THERMAL INFLUENCE OF LIVING WALL IN THE WINTER OF SUBTROPICAL CLIMATE IN BRAZIL.

Author

Cruciol-Barbosa, Murilo, Gurgel de Castro Fontes, Maria Solange, and dos Anjos Azambuja, Maximiliano

Subjects
VERTICAL gardening, SURFACE temperature, GREEN infrastructure
Abstract

Copyright of PARC Pesquisa em Arquitetura e Construção is the property of Universidade Estadual de Campinas - Portal de Periodicos Eletronicos Cientificos and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2023
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37. Nutrients' distribution during fertigation of a felt-based living wall.

Author

Suárez-Cáceres, Gina Patricia, Recena, Ramiro, García-López, Ana María, Delgado, Antonio, and Pérez-Urrestarazu, Luis

Subjects
VERTICAL gardening, FERTIGATION, WALLS, AREA measurement, INDOOR gardening, IRON, PLANT development
Abstract

The lack of space in cities has favoured the development of vertical gardens in indoor and outdoor environments. For an adequate development and appearance of the plants in these living walls, it is necessary to provide nutrients (usually by means of fertigation). One of the main limitations is the difficulty in obtaining a uniform distribution of nutrients, especially in felt systems. The objective of this research was to identify whether the distribution of nutrients (particularly iron and phosphorous) applied by fertigation in a felt living wall depended on the species used and the location of the plants in height. Three modules of a Fytotextile® felt-based living wall were used, each module containing three columns of different species: Soleirolia soleirolii, Philodendron hederaceum, and Nephrolepis exaltata. Fertigation was applied using a Hoagland–Arnon solution for 4 months. Measurements of leaf area, normalised difference vegetation index (NDVI), chlorophyll meter readings (CMR), fresh and dry weight, and P and Fe concentration were carried out for each of the plants. Comparing variables within the same species at different heights showed no significant differences in the variables. This means that the distribution of nutrients along the living wall (especially in height) was uniform. It is important to note that these results could vary for other types of living walls or for other configurations of the fertigation system. [ABSTRACT FROM AUTHOR]

Published
2023
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38. ENERGY AND LIFE CYCLE COST SAVING POTENTIAL OF BUILDINGS USING GREEN WALLS: A CASE STUDY FROM SRI LANKA.

Author

Madushika, U. G. D., Ramachandra T., and Zainudeen N.

Subjects
VERTICAL gardening, GLOBAL warming, CLIMATE change, CONSTRUCTION industry & the environment, SUSTAINABLE buildings
Abstract

With its numerous benefits, the concept of green walls can be used as one of the solutions to address global warming and climatic changes while improving the natural vegetation in dense urban areas. However, perception about the initial and maintenance cost of green walls along with lack of awareness about operational cost savings seems to influence the slow uptake of green wall applications. In that context, this research aimed to assess the Life Cycle Cost (LCC) of green walls in comparison to a conventional wall towards exploring the operational cost benefits which are the most convincing decision criteria for clients/investors. The study involved a case study analysis of an indirect green façade and a comparative conventional wall. The data required to perform the LCC analysis were collected through documentary reviews and on-site temperature measurements. The analysis shows that the initial cost of a green wall is 15% higher than a comparable conventional wall. However, operational and maintenance costs of green walls result in 64% and 25% savings due to potential energy cost-saving, and minimum external redecoration time interval, respectively. This results in an overall LCC saving of 45% over conventional walls with a reasonably expected lifetime of fifty years. As a departing point of previous studies, this study provides empirical evidence on the LCC of green walls in comparison to a conventional wall in a residential facility, from a tropical climate perspective. [ABSTRACT FROM AUTHOR]

Published
2022
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39. ROLE OF 3D PRINTED GREEN WALLS IN HEALING ARCHITECTURE.

Author

Chahin, Sara, Afify, Ayman, Mohsen, Hiba, and Youssef, Maged

Subjects
VERTICAL gardening, THREE-dimensional printing, COMPUTER-aided design, ARCHITECTURAL design, AUTOMATION, CONSTRUCTION materials
Abstract

Three-dimensional (3D) printing has become a fundamental issue in modern global technology, touching practically every element of modern human life. Three-dimensional (3D) printing (also known as additive manufacturing) is an advanced manufacturing technology that can autonomously manufacture complicated shape geometries from a 3D computer-aided design model without the use of equipment or fixtures. However, there is a friction between traditional designs and the rise of 3D printed technology when it comes to architectural healing approaches, and this adaptability is hurting human healing tactics that are dependent on the relationship between space and environment. Due to its capacity to create products in a wide range of materials rapidly and at a lower cost, additive manufacturing is having a significant impact on production in a variety of areas. Even though it encompasses a wide range of techniques and applications, additive manufacturing (AM) may be described as a system for converting solid model data from a computer-based model into a physical prototype by the incremental addition of material via layer superposition. Therefore, this research aims to examine the 3d printed green walls as new proposed design elements that can upgrade the natural healing architecture. To achieve this goal, the study begins with a literature review that includes scientific methodology based on principles that assist architects dealing with advanced tools in transforming their intentions from digital to analogue means as part of a controlled system intended to innovate design and construction principles of the use of 3D printed green walls. It will also assist in the quest for a concept design that confronts the regeneration of a new spatial delineation ideology. [ABSTRACT FROM AUTHOR]

Published
2022
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40. Analysis of the Microclimatic and Biodiversity-Enhancing Functions of a Living Wall Prototype for More-than-Human Conviviality in Cities

Author

Sebastian Bornschlegl, Pia Krause, Cordula Kropp, and Philip Leistner

Subjects
green infrastructure, green wall, living wall, prototype, bioclimatic layers, microclimate, Building construction, TH1-9745
Abstract

This study analyzes the growing trend of urban green infrastructures, particularly green façade systems, in terms of their infrastructural relationships between nature and culture and their potential to act as bioclimatic layers mediating between the needs of flora, fauna and human habitation. An interdisciplinary approach is taken by combining the perspectives of social and engineering sciences to discuss the contribution of green façade systems for more-than-human conviviality in cities. Green infrastructures can support this endeavor by enabling functions that help to integrate the heterogeneity typical for semi-natural structures into urban ones, especially regarding microclimatic and biodiversity-enhancing functions. The theoretical distinction between “gray”, “green”, and “revolutionary” infrastructure is used to differentiate between conventional and posthumanist conceptualizations of urban naturecultures. The performance of the UNA TERRA living wall prototype as a green and revolutionary infrastructure is evaluated. The results show that the living wall has beneficial microclimatic effects and adds a heterogeneous habitat structure that supports biodiversity in the urban context. By adhering to “egalitarian humility” in design, the uncertainty and openness of more-than-human conviviality are acknowledged. The study finds that green infrastructures such as green façade systems can fulfill the criteria of revolutionary infrastructure if the contribution to local biodiversity and structural complexity is prioritized and the heterogeneous interrelations between human and non-human actors are taken into account.

Published
2023
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41. Evaluation of Shading of Green Facades on Visual Comfort and Thermal load of the Buildings.

Author

Sharbafian, Mohammad, Yeganeh, Mansour, and Baradaran Motie, Mohammadreza

Subjects
*COOLING loads (Mechanical engineering), *SUSTAINABLE design, *VERTICAL gardening, *THERMAL comfort, *HEATING load
Abstract

This study aimed to evaluate the impact of the building's green façade on regulating the indicators of daylight, visual comfort, heating and cooling load, and its features (such as the density of greenery and distance from the main facade). The effects of simulating 30 distinct green facade designs for various building fronts were examined. The findings reveal that altering the green facade's distance (between 0 and 50 cm) had no discernible impact on the variables. The values of DA, UDI max , and cooling load have lowered by increasing density from 20 % to 100 %. The heating burden has grown, though. Higher densities of the green facade between different distances show a greater difference in the values of the tested variables than lower densities. For instance, at 100 % density, the UDI max value rose from the highest to lowest distance (0.50 cm) by 59.6 %, but at 20 % density, this shift was only 2.9 %. [ABSTRACT FROM AUTHOR]

Published
2024
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42. GREEN WALL IMPACT ON BENEFICIAL INSECTS IN AN URBAN FRUIT ECOSYSTEM.

Author

IVAN, Elena Ştefania, CICEOI, Roxana, BUTCARU, Ana Cornelia, STANCIU, Ana Maria, NIŢU, Oana Alina, and STĂNICĂ, Florin

Subjects
VERTICAL gardening, URBAN ecology, INSECTS, INSECT pollinators, GROUND beetles, SHRUBS, URBAN plants, ORGANIC farming, ORCHARDS
Abstract

Green walls are a component of urban green infrastructure and contribute to a range of ecosystem services including habitat provision for urban biodiversity, screening out aerial particulate matter, improving air quality, attenuating noise, and enhancing aesthetics of the cityscape. Insects can be the organic grower’s best friend. Whether pollinators or predators, they will help manage pests and keep urban gardens healthy. The organic growers encourage flowers, along with trees, shrubs and water, to provide a valuable and diverse ecosystem. The green wall was set in the experimental fruit field of the Faculty of Horticulture within USAMV Bucharest, at the border between the vineyard and the organic apple and cherry growing sector. Observations were made on the green wall impact on beneficial insects, as pollinators, hoverflies (Diptera), ladybirds (Coleoptera), parasitic wasps (Hymenoptera), butterflies and moths (Lepidoptera), lacewings (Neuroptera), ground beetles (Coleoptera, Carabidae). The preliminary results indicate that Lonicera japonica, Hedera helix, Mentha, Parthenocissus quinquefolia, Akebia Quinata,Campsis radicans they attract beneficial insects such as pollinators or aphid eaters. [ABSTRACT FROM AUTHOR]

Published
2022

43. Public Perceptions of Green Roofs and Green Walls in Tokyo, Japan: A Call to Heighten Awareness.

Author

Jim, C. Y., Hui, Ling Chui, and Rupprecht, Christoph D. D.

Subjects
GREEN roofs, VERTICAL gardening, CITIES & towns, AIR quality, PLANT litter
Abstract

Many cities advocate retrofitting green roofs and green walls (GRGW) to create additional green areas, especially in cramped urban areas. Yet, worldwide, only a handful of studies have evaluated the public views towards the benefits and negative issues and promotion policies of this innovative greening option. To address this gap in the literature, we conducted a survey (N = 500) of residents' opinions towards GRGW in Tokyo, a city with mandatory installation of GRGW for almost two decades. Respondents mostly agreed with the contribution of GRGW to thermal comfort, air quality, and cityscape but weakly endorsed other potential benefits. High costs as well as mosquitoes and plant litter nuisances were the most recognized negative issues. Mandatory installation was the least preferred promotion policy. Instead, respondents expected installation on public buildings and provision of installation guidance. Respondents predominantly held a "moderate" view towards both the benefits and negative issues, showing indifferent attitudes towards GRGW. Income level and housing type shaped the overall perceptions, whereas age, sex, and current living environment influenced perceptions of individual aspects. Our findings signified a need for a bottom-up strategy to heighten public awareness for the advanced development of GRGW to complement and prime the top-down mandatory installation policy. [ABSTRACT FROM AUTHOR]

Published
2022
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44. Integration of architecture and vegetation -a review of tendencies and perspectives.

Author

STANGEL, MICHAŁ

Subjects
VEGETATION & climate, SUSTAINABLE architecture, GREEN roofs, CLIMATE change, BIOPHILIA hypothesis
Abstract

Copyright of Builder (1896-0642) is the property of PWB MEDIA Zdzieblowski sp.j. and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2022
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45. Vertical Greenery as Natural Tool for Improving Energy Efficiency of Buildings.

Author

Campiotti, Carlo Alberto, Gatti, Lorenzo, Campiotti, Alessandro, Consorti, Luciano, De Rossi, Patrizia, Bibbiani, Carlo, Muleo, Rosario, and Latini, Arianna

Subjects
BUILDING-integrated photovoltaic systems, URBAN heat islands, ENERGY consumption, SUSTAINABLE buildings, VERTICAL gardening, HEAT flux, WINTER
Abstract

The European Construction Sector Observatory outlined that green building envelopes as green roofs and walls contribute to the reduction of energy demand and CO2 emissions due to the air conditioning in summer periods, and the mitigation of heat islands in urban areas. For this reason, the understanding about the contribution of urban greening infrastructures on buildings to sustainable energy use for air conditioning is urgent. This paper focuses on the analysis of a vertical surface provided with a Parthenocissus quinquefolia (L.) Planch., a winter deciduous species, as green cover of a building, assessing the reduction of the solar radiation energy absorbed by the façade and, consequently, the heat flux (HF) transmitted into the internal ambient. This research shows that, in July, surface temperatures (STs) on the vegetated façade were up to 13 °C lower than on the unvegetated (bare) façade. Under the climate and environmental conditions of the green wall located at ENEA Casaccia Research Center, a saving of 2.22 and 1.94 kWhe/m2, respectively in 2019 and 2020, for the summer cooling electricity load, was achieved. These energy reductions also allowed the saving of 985 and 862 g CO2/m2 emissions, respectively, in 2019 and 2020. Ultimately, a green factor named K v * was also elaborated to evaluate the influence of vegetation on the STs as well as on HFs transmitted into the indoor ambient and adapted to the case of a detached vertical green cover. Measurements of K v * factor lasting three years showed the suitability of this index for defining the shading capacity of the vegetation on the building façade surfaces, which can be used to predict thermal gains and effects in a building endowed of a vertical green system. [ABSTRACT FROM AUTHOR]

Published
2022
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46. The Impacts of Greenery Systems on Indoor Thermal Environments in Transition Seasons: An Experimental Investigation.

Author

Hao, Xiaoli, Liu, Liping, Tan, Hang, Lin, Yaolin, Hu, Jinhua, and Yin, Wei

Subjects
THERMAL comfort, WEATHER, SEASONS, BUILDING performance, SURFACE temperature, HUMIDITY
Abstract

The impacts of greenery systems (GSs) on microclimate conditions and building energy performance have been frequently investigated using experiments and simulations during the past decades, especially in summer and winter. However, few studies have focused on the performance of GSs in transition seasons. The ambient weather conditions vary with great fluctuations during transition seasons, which may result in severe oscillations in indoor environments. To investigate the impacts of GSs on indoor environments, an experiment was conducted using a contrastive test platform, which consisted of two experimental rooms, one equipped with a GS and the other without, from 1 April 2019 to 31 May 2019 in Hunan, China. Both rooms were free-running. The experimental results showed that the GS had the ability to reduce the oscillations in the indoor environment. The oscillations in indoor dry-bulb temperature (DBT) and relative humidity (RH) were reduced by 39.3% and 28.8%, respectively. The maximum daily DBT and RH ranges were, respectively, cut down by 3.5 °C and 12.4%. The maximum reductions in external and internal surface temperatures were 29.5 °C and 9.4 °C, respectively, for the GS, while the average reductions were 1.6~4.1 °C and 0.2~1.3 °C, respectively, depending on the orientation of the surfaces. The operative temperature (OT) during the daytime on sunny days was also lowered by the GS. The differences in OT between the two rooms ranged from −1.8 °C to 8.2 °C, with an average of 1.0 °C. The GS can improve the indoor thermal comfort during transition seasons. The thermal dissatisfaction was decreased by 7.9%. This lengthened the thermal comfort time by 15% across the whole day and by 28% during the daytime. This indicates reductions in air-conditioning system operating times, leading to energy savings. [ABSTRACT FROM AUTHOR]

Published
2022
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47. Skyscapers and greenery. An unprecedented symbiosis

Author

Simona Talenti and Annarita Teodosio

Subjects
Italian skyscrapers, sustainability, vegetation, green wall, roof garden, Architecture, NA1-9428
Abstract

An appropriate use of natural resources, combined with the choice of innovative materials and the reduction of the consumption of non-renewable sources, increasingly contribute to the sustainability of skyscrapers. Italy has also witnessed the growing custom of including green elements in tall buildings, in the envelopes, at the bases, sides or interiors. The use of vegetation not only concerns new constructions, but also the redevelopment of existing towers, sometimes offering a chance even to buildings that originally lack significant value. Greenery applied to Italian skyscrapers, however, should raise questions about the actual environmental, economic and social sustainability of these design solutions, which sometimes seem to respond to mere aesthetic and ornamental requirements or marketing demands. Through the analysis of certain Italian skyscrapers characterized by the presence of greenery, this study aims to underline the potential and the importance of the use of vegetation in the tall building, an architectural type historically in contrast with natural elements, triggering a reflection on intervention criteria susceptible of application also at wider and more differentiated scales.

Published
2022
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48. Reduction of carbon dioxide by bio-façades for sustainable development of the environment.

Author

Rezazadeh, Hamidreza, Salahshoor, Zahra, Ahmadi, Ferial, and Nasrollahi, Farshad

Subjects
CARBON dioxide reduction, SCIENTIFIC literature, SUSTAINABLE development, ANALYTIC hierarchy process, CLIMATE change & health, BIOMASS liquefaction, AIR pollution
Abstract

Nowadays, air pollution and consequently global warming are the major problems that the earth is faced with. These issues can influence climate change and human health. Building façades can play a significant role in the air quality of the urban environment. Therefore, this study draws upon the ability of nature in controlling carbon dioxide to compare three types of bio-façades (i.e. Water façade, Green façade, and Microalgae façade) and to identify an appropriate one. For this purpose, we analyzed documents and scientific literature qualitatively. Then, we identified the aforementioned types of biological façades and selected the most optimal one through the comparison. Additionally, for this comparison, the analytical hierarchy process (AHP) method was employed that resulted in achieving the higher scores by the microalgae façade among other bio-façades mentioned above. The major criteria considered for the AHP analysis included climatic, economic, architectural, environmental, and structural aspects of using the noted bio-façades in buildings. It should be emphasized that the environmental aspect was obtained as the most influential criterion among others. Finally, some technical tips and design requirements for bioreactors are depicted and discussed along with their upcoming challenges and future research direction. [ABSTRACT FROM AUTHOR]

Published
2022
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49. Special issue in honour of Prof. Reto J. Strasser - Can we predict winter survival in plants using chlorophyll a fluorescence?

Author

T. SWOCZYNA, J. MOJSKI, A.H. BACZEWSKA-DĄBROWSKA, H.M. KALAJI, and N.I. ELSHEERY

Subjects
green wall, jip-test, perennials, plant winter hardiness, vertical garden, Botany, QK1-989
Abstract

In the last years, JIP-test became to be a tool widely applied to assess the performance of photosynthetic apparatus of plants growing under environmental stresses. The objective of our work was to check whether JIP-test can help to predict winter survival in plants. An experiment with outdoor vertical garden was conducted in June 2015 on a south-oriented wall in Lublin city, Poland. Plants were cultivated in pockets made of polyester felt and irrigated by automatic controlled system. After winter period (2015/2016) only 16 species and cultivars from 23 initially planted taxa substantiated successful survival. Chlorophyll fluorescence measurements were performed twice in 2015 and six times in 2016. Survival rate of examined species did not show any significant correlation with performance indices of PSII (PIABS and PItotal) and parameters related to quantum yields. On the other hand, changes of some parameters related to specific energy fluxes per active reaction centres were found to be connected, to some extent, to plants winter survival. These changes could play a key role in plants ability to survive winter conditions.

Published
2020
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50. Exploring the Integration Between Colour Theory and Biodiversity Values in the Design of Living Walls

Author

Petra Thorpert, John Rayner, Christine Haaland, Jan-Eric Englund, and Ann-Mari Fransson

Subjects
green infrastructure, landscape aesthetics, living wall, green wall, ecosystem services pollinators, environmental appraisal, Evolution, QH359-425, Ecology, QH540-549.5
Abstract

Designing green infrastructure in cities requires vegetation that has multiple outcomes and functions, particularly using plants that have both attractive visual or aesthetic features and high biodiversity values. Plantings that have high visual appeal are more highly valued by people and increase their feeling of wellbeing. Increasing biodiversity in cities is one of the major challenges facing urban planning and design. However, balancing biodiversity and aesthetic outcomes in urban planting design is complex, and to date there are few methods that can be used to guide plant selection. To address this knowledge gap, we investigated the use of a colour theory framework for planting arrangements to see if we could design vegetation that is highly aesthetic and has high biodiversity. We did this by configuring planting combinations for living walls in Malmö, Sweden, using principles based on Johannes Itten’s colour theories. The plant combinations on each wall were graphically arranged using (1) colour analysis of each plant and (2) design of the plant species into two colour schemes: light-dark colour concept and a complementary colour concept. For each species used in the compositions we created a biodiversity classification, based on its pollination value, “nativeness” and conservation value as a cultivar; and a plant visual quality classification, based on the performance from living walls studies. The graphical colour composition and interlinked biodiversity value were then compared to designs created with randomly selected plant species. The results showed that it is possible to design a living wall based on colour theory without compromising with biodiversity outcomes, namely species richness, pollination and the nativeness of the species. The results also indicate the potential application of this design approach to deliver greater aesthetic appreciation and enjoyment from plantings. While more work is needed, this study has shown that a theoretical colour framework can be a useful tool in designing green infrastructure to improve delivery of both cultural and regulatory ecosystem services.

Published
2022
Full Text
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