Open Journal of Ecology

Open Journal of Ecology

ISSN Print: 2162-1985
ISSN Online: 2162-1993
www.scirp.org/journal/oje
E-mail: oje@scirp.org
"Greening the building envelope, facade greening and living wall systems"
written by Katia Perini, Marc Ottelé, E. M. Haas, Rossana Raiteri,
published by Open Journal of Ecology, Vol.1 No.1, 2011
has been cited by the following article(s):
  • Google Scholar
  • CrossRef
[1] Plant pixel: An optimized bio-inspired living wall system
Developments in the Built …, 2024
[2] Thermo-Environmental Performance of Modular Building Envelope Panel Technologies: A Focused Review
Osta, AA Abdou - Buildings, 2024
[3] A Nature-Inspired Green–Blue Solution: Incorporating a Fog Harvesting Technique into Urban Green Wall Design
Sustainability, 2024
[4] When Trees Are Not an Option: Perennial Vines as a Complementary Strategy for Mitigating the Summer Warming of an Urban Microclimate
Buildings, 2024
[5] Sustainable Design of Vertical Greenery Systems: A Comprehensive Framework
Sustainability, 2024
[6] Vertical greening systems serve as effective means to promote pollinators: Experimental comparison of vertical and horizontal plantings
Landscape and Urban …, 2024
[7] Optimizing energy efficiency and thermal comfort of green envelope applications in hot arid climate
Discover Applied Sciences, 2024
[8] Vertical Greenery Systems in Tropical Climate-A Review
Journal of Real Estate …, 2024
[9] When Trees Are Not an Option: Perennial Vines as a Complementary Strategy for Mitigating the Summer Warming of an Urban Microclimate. Buildings 2024, 14 …
2024
[10] Effect of water content in the composition of an extensive green roof on the temperature regime
Transportation Research Procedia, 2023
[11] Empirical study to understand marketing influence of environmental impact assessment on end users in UAE
Digital Economy and …, 2023
[12] Food Producing Facades Key to a Sustainable Future
DEPARCH Journal of Design Planning and …, 2023
[13] Performance Assessment of an Indirect Green Facade Building for Thermal Comfort: Case of Hyderabad
World Congress of Architects, 2023
[14] Zieleń wertykalna jako nowa płaszczyzna we współczesnym rozwoju miast.
Przestrzeń Urbanistyka …, 2023
[15] Growth analysis of Cineraria maritima plants in green façade systems: Northeastern Romania climate study
2023
[16] Green wall: A recuperative strategy for urban life style
2023
[17] Experimental measurement of dynamic changes in the basis weight of vegetation walls and facades due to evapotranspiration
AIP Conference …, 2023
[18] Economic and Environmental Impact Analysis of Green Building Materials in Facade Engineering
International Journal, 2023
[19] Multi-Criteria Analysis and Design Ideas of Green Façade Systems as Eco-Friendly Architectural Solutions
Civil and Environmental Engineering …, 2023
[20] Urban Greening Techniques: An Introduction
2023
[21] Vertical columns with sustainable green cover: meadow plants in urban design
Plants, 2023
[22] Green facades and renewable energy: Synergies for a sustainable future
Int. J. Innov. Sci. Res …, 2023
[23] Careful plant choice can deliver more biodiverse vertical greening (green façades)
Urban Forestry & Urban …, 2023
[24] Leaf trait plasticity means green facades are a flexible nature-based solution for vertical greening under full-sun and heavy shade conditions
Nature-Based Solutions, 2023
[25] Bioreceptivity of living walls: Interactions between building materials and substrates, and effect on plant growth
Urban Forestry & Urban …, 2023
[26] Vertical plants: Plant design of Living walls–evaluation of 34 perennials in a textile based Living wall over a three years experiment
Frontiers in Horticulture, 2023
[27] Living Wall Plants Are Affected by and Affect Temperature: How to (not) Measure Plants' Temperature in a Living Wall Experiment
Sustainability, 2023
[28] Vertical greening: The state of the art in digital modeling and simulation
International Journal of …, 2023
[29] Monitoring and performance evaluation of a green wall in a semi-arid Mediterranean climate
Journal of Building Engineering, 2023
[30] Performance of urban climate-responsive design interventions in combining climate adaptation and mitigation
Building and …, 2023
[31] Modeling the impact of overcoming the green walls implementation barriers on sustainable building projects: A novel mathematical partial least squares—SEM …
Mathematics, 2023
[32] Porous plant form-induced amplification of evapotranspiration for enhanced cooling in vertical greenery systems
Building and Environment, 2023
[33] Fire safety risks of external living walls and implications for regulatory guidance in England
Fire safety journal, 2023
[34] Thermal Performance of Indirect Green Façade in Composite Climate of India
SSRN Electronic Journal, 2023
[35] Food Producing Façades Key to A Sustainable Future
DEPARCH Journal of Design Planning and Aesthetics Research, 2023
[36] Vertical greening in urban built environments
2022
[37] Assessing the environmental performance of plastic-based and felt-based green wall systems in a life-cycle perspective
Science of The Total …, 2022
[38] The Application of Green Wall Systems as a Passive Design Strategy in the Buildings of Hot Aired Areas
Association of Arab Universities Journal of …, 2022
[39] Professionals' perception studies of vertical greening systems in Lagos, Nigeria
… Journal of Building Pathology and Adaptation, 2022
[40] Waste subtracts and nutrients as ingredients for vegetation growth in construction materials–A review
Gomes - Cleaner Engineering and Technology, 2022
[41] Vertical greenery system: a model for improving energy efficiency of buildings
Topalović - Građevinar, 2022
[42] The Vertical Greening Envelope and its Effect on Energy Consumption Efficiency in a Residential Building, Case Study: Twin House, 6th of October City
Zoklah, T Refaat - JES. Journal of Engineering …, 2022
[43] Vertical Gardening: An Easy and Affordable Module for Domestic Installation in the Context of Khulna City
The 8th edition of the Zero Energy Mass Custom Home (ZEMCH 2021) International Conference, 2022
[44] Systemic solutions for the holistic well-being of cities. Processes, results and reflections
AGATHÓN| International Journal …, 2022
[45] Study of Living Wall Systems'(LWSs) Support system for improving LWSs Life cycle performance and noise reduction potential
Building and Environment, 2022
[46] IMPACT OF VEGETATED INFRASTRUCTURE TO MITIGATE THE URBAN HEAT ISLAND EFFECT IN DHAKA, BANGLADESH
2022
[47] Diversity of soil microbes in a vertical forest
Journal of East China Normal …, 2022
[48] Do plant traits help to design green walls for urban air pollution control? A short review of scientific evidences and knowledge gaps
Environmental Science and Pollution …, 2022
[49] A review on typologies and the role of vertical greening in reducing the heat gain through building façades.
Jahrbuch der O?sterreichischen Gesellschaft fu?r Agraro?konomie, 2022
[50] Green Interactive Installations as Conceptual Experiments towards a New Meaning of Smart Design. Buildings 2022, 12, 62
2022
[51] Sustav vertikalnog ozelenjavanja-model za poboljšanje energetske učinkovitosti zgrada
Topalović - Građevinar, 2022
[52] Den vertikala trädgårdens utveckling: En design research studie för framtagning av ett teoretiskt väggsnitt bestående av en halvsandwich med en infäst …
2022
[53] Living wall systems for improved thermal performance of existing buildings
Building and …, 2022
[54] New developments and future challenges in reducing and controlling heat island effect in urban areas
Martínez… - Environment …, 2022
[55] Nature-based solutions applied to the built environment to alleviate climate change: Benefits, co-benefits, and trade-offs in a geographical multi-scale perspective
Handbook of Climate Change Mitigation and …, 2022
[56] Sustainability performance by ten representative intelligent Façade technologies: A systematic review
Sustainable Energy Technologies and …, 2022
[57] Green Interactive Installations as Conceptual Experiments towards a New Meaning of Smart Design
Buildings, 2022
[58] Approaches
2022
[59] A comparative study on green wall construction systems, case study: South valley campus of AASTMT
Case Studies in Construction …, 2022
[60] Evaluation of effects of a green wall as a sustainable approach on reducing energy use in temperate and humid areas
Energy and Buildings, 2022
[61] A Study on the Bioreceptivity of Cement Composites for Living Concrete Panels
Mathematical Statistician and …, 2022
[62] Clay 3D printing as a bio-design research tool: development of photosynthetic living building components
na, G Caldwell… - Architectural Science …, 2022
[63] Towards the adoption of most suitable green walls within sustainable buildings using interval type-2 fuzzy best-worst method and TOPSIS technique
Engineering …, 2022
[64] Vertical Greening Systems: A Critical Comparison of Do-It-Yourself Designs
Plants, 2022
[65] Estudo do efeito de infraestruturas verdes na resiliência da cidade de Leiria às alterações climáticas e à poluição do ar
2022
[66] Functionalizing building envelopes for greening and solar energy: Between theory and the practice in Egypt
Frontiers in Environmental …, 2022
[67] Impact of Vegetated infrastructure to mitigate the Urban Heat Island Effects in Dhaka, Bangladesh
2022
[68] Valuing Vertical Green
2022
[69] The Vertical Greening Envelope and its Effect on Energy Consumption Efficiency in a Residential Building, Case Study: Twin House, 6th of October City.
Zoklah - Journal of Engineering Sciences, 2022
[70] 垂直森林绿化系统中土壤微生物多样性研究
华东师范大学学报 (自然科学版), 2022
[71] Tratamiento de aguas grises mediante un sistema de paredes verdes con las especies Aptenia Cordifolia Ynephrolepis Obliterata
2022
[72] Chapter-11 Green Wall, Its Types and Role in Environment Conservation
Advances in Floriculture and …, 2022
[73] Wall Cascade Constructed Wetland Systemfor Treatment of Greywater
NeuroQuantology, 2022
[74] KONSEP DESAIN VERTICAL GARDEN DI KAMPUNG TANGGUH KECAMATAN CURUG KOTA DEPOK
Lakar: Jurnal …, 2022
[75] Impacts of Vegetation Facades on Urban Microclimate
2021
[76] Peningkatan Ekologi Lahan di Universitas Negeri Malang melalui Rating tool Greenship Kawasan
Dampak, 2021
[77] L'enveloppe végétale
2021
[78] 리빙 콘크리트 패널용 마그네시아 복합체의 마그네시아 및 인산칼륨 비율에 따른 기초 품질 특성
한국건설순환자원학회논문집, 2021
[79] The Transition to Renewable Energy: Should the Adoption of Innovative Energy Technologies be Made Compulsory?
8th Zero Energy Mass Custom …, 2021
[80] The Quality Properties According to the Ratio of Magnesia and Potassium Phosphate of Magnesia Composites for Living Concrete Panel
Journal of the Korean …, 2021
[81] of the book: Contemporary Approaches in Urbanism and Heritage Studies
Studies, 2021
[82] Total value wall: Full scale demonstration of a green wall for grey water treatment and recycling
Journal of …, 2021
[83] In situ experimental evaluation of a novel modular living wall system for industrial symbiosis
Energy and Buildings, 2021
[84] The Perception of Green Facades and its Effects on Public Spaces' Users
Estudos em Design, 2021
[85] Deterrents to the adoption of green walls: a hybrid fuzzy-based approach
Engineering …, 2021
[86] Razvoj zelene stene za čiščenje sive vode in prenos toplote
2021
[87] A review of the impact of the green landscape interventions on the urban microclimate of tropical areas
Building and Environment, 2021
[88] Green walls to treat kitchen greywater in urban areas: Performance from a pilot-scale experiment
2021
[89] Green walls: A form of constructed wetland in green buildings
2021
[90] “Greening” and comfort conditions in transport infrastructure systems: Understanding users' preferences
2021
[91] Thermal Environment Control of Buildings using Installation of Plants and Metal Panels on Brick Walls
2021
[92] Role of Urban Greening Strategies for Environmental Sustainability—A Review and Assessment in the Context of Saudi Arabian Megacities
2021
[93] Bioreceptividade de substrato de concreto para colonização biológica em Florianópolis
2021
[94] Jardins Verticais como uma proposta de ambiente agradável e de baixo custo em Escolas Públicas Living walls as a proposal for a pleasant and low-cost …
Brazilian Journal of …, 2021
[95] Innover dans la conception des murs végétaux afin de maximiser leurs effets sur la qualité de l'air
2021
[96] ЗЕЛЕНЫЕ ФАСАДЫ В УСТОЙЧИВОМ ПРОЕКТИРОВАНИИ
… ПРОБЛЕМЫ СОВРЕМЕННОЙ НАУКИ, 2021
[97] Les façades végétalisées: Analyse comparative et mise au point d'un outil d'aide à la décision
2021
[98] Sistema de paredes verdes para la reducción de contaminantes del aire: Revisión sistemática
2021
[99] Entwicklung, Vorteile und Kostenvergleich zwischen Bauwerksbegrünungen in Wien und Belgrad
2021
[100] Study of Vertical Greening System Implementation at Flyover Structure in DKI Jakarta
2021
[101] Global technological advancement and challenges of glazed window, facade system and vertical greenery-based energy savings in buildings: A …
Energy and Built …, 2021
[102] Vertical Farming Projects and Reducing Urban Heat Islands Phenomenon in Cities
of the book: Contemporary …, 2021
[103] Development, advantages and cost comparison between building greening in Vienna and Belgrade
2021
[104] Urban agriculture in landscape architectural view in Ho Chi Minh City
AIP Conference Proceedings, 2021
[105] Assessment and optimization of felt living walls in terms of water retention performance and artificial lighting
2021
[106] The Vegetated Building Facades and their Contribution to Environmental Sustainability
Cities People Places: An …, 2021
[107] Green roof and green wall benefits and costs: A review of the quantitative evidence
2021
[108] Nature-based solutions in the urban context: terminology, classification and scoring for urban challenges and ecosystem services
2021
[109] Architectural Laboratory Practice for the Development of Clay and Ceramic-Based Photosynthetic Biocomposites
2020
[110] SINCE ANCIENT PERSIAN GARDENS TO MODERN VERTICAL GARDENS AND ROOF GARDENS
2020
[111] Hindrances to the adoption of green walls: a hybrid fuzzy-based approach
2020
[112] A Deep Dive into Natural Swimming Pool Filtration: Living Walls as Technical Wetland Filters
2020
[113] Vertical gardens as a restorative tool in urban spaces of New Cairo
2020
[114] Heat island effects in urban life cycle assessment: Novel insights to include the effects of the urban heat island and UHI‐mitigation measures in LCA for effective policy …
2020
[115] The impact of green facades and vegetative cover on the temperature and relative humidity within model buildings
2020
[116] تأثیر شاخص های داخلی و خارجی دیوار سبز بر عملکردهای زیست محیطی و صرفه جویی انرژی‎
2020
[117] Urban horticulture for food secure cities through and beyond COVID-19
2020
[118] Green infrastructure and public policies: An international review of green roofs and green walls incentives
2020
[119] Management of nature-based goods and services provisioning from the urban common: a pan-European perspective
2020
[120] Green Walls, a Critical Review: Knowledge Gaps, Design Parameters, Thermal Performances and Multi-Criteria Design Approaches
2020
[121] The Impact of Living Wall on Building Passive Cooling: A Systematic Review and Initial Test
2020
[122] Monitorization and statistical analysis of south and west green walls in a retrofitted building in Madrid
2020
[123] Assessment of the effect of living wall systems on the improvement of the urban heat island phenomenon
2020
[124] Benefits of implementing vertical greening in tropical climates
2020
[125] Thermal Mitigation of the Indoor and Outdoor Climate by Green Curtains in Japanese Condominiums
2020
[126] An environmental Life Cycle Assessment of Living Wall Systems
2020
[127] The impact internal and external indicators green wall On Environmental and Energy Savings Performance
2020
[128] Aproximación sobre el hormigón biológico
2020
[129] Problem przegrzewania miast XXI wieku (MWC) a zieleń miejska
2020
[130] Ekofickan
2020
[131] Tipologija sustava vertikalnog ozelenjavanja
2020
[132] Zielone ściany-odpowiedź na Miejską Wyspę Ciepła
2020
[133] Typology of vertical greenery system
2020
[134] Principles of implementation of the vertical greenery system (VGS) in architecture
2020
[135] WETWALL: an innovative design concept for the treatment of urban wastewaters
2020
[136] 绿化表皮对过渡空间的热环境影响实测研究
西部人居环境学刊, 2020
[137] Vegetační prvky budov jako nástroj adaptace na klimatické změny na území města Plzně
2020
[138] Evaluasi komposisi ruang terbuka hijau di lingkungan kampus dalam menunjang konsep eco campus
EMARA: Indonesian Journal of …, 2020
[139] İç mimarlık ve çevre tasarımında dikey bahçe uygulamalarının değerlendirilmesi
Anadolu Bil Meslek Yüksekokulu Dergisi, 2020
[140] Thermal Performance Evaluation of Green Living Walls in Composite Climate
International Journal of …, 2020
[141] Relația lumii vegetale cu spații destinate birourilor
2020
[142] Implementation of Vertical Greening as a Double Skin Envelop: A Sustainable Approach in Tropical Climates
Proceedings of the …, 2019
[143] Die Indexierung der Familienbeihilfe im Lichte des europäischen Rechts und der Judikatur des EuGH/eingereicht von Sylvia Kirchmayr
2019
[144] Yapı cephelerinde dikey bahçe kullanımının kent ekolojisine etkilerinin incelenmesi, Florya trafo binası örneği
2019
[145] División de Ciencias Biológicas y Ambientales
2019
[146] Heat Island Effects in Urban Life Cycle Assessment
2019
[147] Evaluación del potencial de tratamiento de aguas grises domésticas con sustratos orgánicos y plantas utilizadas comercialmente en paredes verdes
2019
[148] Effects of the Green Façade on Thermal Comfort in the Transitional Spaces: Field Measurements in Munich, Germany
Conference Proceedings of 5th International Conference on Countermeasures to Urban Heat Islands (IC2UHI), 2019
[149] Study of Vertical Greenery System as Passive Approach for Sustainable Design
2019
[150] QUANTIFYING ECOSYSTEM SERVICES OF GREEN INFRASTRUCTURE IN AUSTIN, TEXAS
2019
[151] LIVING WALLS AND GREEN FACADES: A STUDY IN NICOSIA
2019
[152] Thermal Performance of Edible Vertical Greenery System In High-rise Residential Balcony
2019
[153] Održivo ozelenjavanje fasada
2019
[154] YAPI CEPHELERİNDE DİKEY BAHÇE KULLANIMININ KENT EKOLOJİSİNE ETKİLERİ'NİN İNCELENMESİ FLORYA TRAFO BİNASI ÖRNEĞİ
2019
[155] Physical and Non-Physical Benefits of Vertical Greenery Systems: A Review
2019
[156] Overcoming the barriers to green walls in urban areas of the UK
2019
[157] A Study on the Quality and Biological Characteristics of Moss Panel Utilizing Alumina Cement
2019
[158] Cooling and Energy-Saving Performance of Different Green Wall Design: A Simulation Study of a Block
2019
[159] Green Facades and Living Walls—A Review Establishing the Classification of Construction Types and Mapping the Benefits
2019
[160] Växter uppåt väggarna
2019
[161] Zieleń na elewacjach–problem czy korzyść dla budynku?
2019
[162] Experimental comparison of green facades with outdoor test cells during a hot humid season
2019
[163] The true cost of “greening” a building: Life cycle cost analysis of vertical greenery systems (VGS) in tropical climate
2019
[164] Vegetation integrated building design and its implications on the interior temperature in warm and humid climate
2019
[165] Living concrete: Democratizing living walls
2019
[166] Assessment of perlite, expanded clay and pumice as substrates for living walls
2019
[167] Implementation of the Systems for Greening the Building's Structure
2019
[168] Możliwości i ograniczenia wykorzystania roślin w obniżaniu temperatury powierzchni elewacji budynku
2019
[169] 알루미나 시멘트 활용 이끼 판넬의 품질 및 생물학적 특성에 관한 연구
2019
[170] Pemetaan teknologi fasad bangunan di iklim tropis
2019
[171] BARRIERS OF IMPLEMENTING GREEN WALLS IN THE URBAN ENVIRONMENT IN DEVELOPING COUNTRIES
2019
[172] Green facades: Evaluation, impact, advantages, disadvantages and potential in a humid subtropical climate zone–Burgas, Bulgaria
2019
[173] Engagement in practice: partnering with a local community in an effort to promote revitalization
2018
[174] A study on the fundamental quality of magnesia-phosphate-formed mortar composites using superabsorbent polymer for development of concrete for …
2018
[175] Investigating the Cooling Effect of Living Walls in Egypt Based on Design Builder Software
2018
[176] “WETWALL”—an innovative design concept for the treatment of wastewater at an urban scale
2018
[177] Applications of Image Processing
2018
[178] Multi-layer planting as a strategy of greening the transitional space in high-rise buildings: A review
2018
[179] The Socio-Economic Feasibility of Greening Rail Stations: A Case Study in Lisbon
The Engineering Economist, 2018
[180] Review on village/backyard/poultry production system in Ethiopia
2018
[181] OPTIMISING BALCONY FOR GREEN SPACES: APPLICATION OF EDIBLE BIOFAÇADE ON URBAN HIGH-RISE SETTING
2018
[182] Murs verts: Une approche" Habitats analogues". Test pour la mise en oeuvre de murs végétalisés analogues aux habitats de falaises et de vieux murs
2018
[183] Participating in Vertical Gardens
2018
[184] A Study on the Fundamental Quality of Magnesia-Phosphate-Formed Mortar Composites Using Superabsorbent Polymer for Development of Concrete for Biological …
Advances in Materials Science and Engineering, 2018
[185] " WETWALL”: an innovative design concept for the treatment of wastewater at an urban scale
2018
[186] Designing Green Walls: An Early-Design Framework to Estimate the Cooling Impact of Indirect Green Walls on Buildings in Six Different Climates
2018
[187] Field evaluation of precipitation interception potential of green façades
Ecological Engineering, 2018
[188] Murs verts : Une approche "Habitats analogues". Test pour la mise en oeuvre de murs végétalisés analogues aux habitats de falaises et de vieux murs
2018
[189] WETWALL-an innovative design concept for the treatment of wastewater at an urban scale
2018
[190] The Biofaçade as a Vertical Edible Landscape in High-Rise Buildings: A Review
2018
[191] Experimental Investigation of Living Architecture Design Tools to Attenuate Rooftop Noise
2018
[192] 후기포 방식을 적용한 생물학적 판넬용 기포 시멘트 복합재료의 품질특성에 관한 실험적 연구
Journal of the Korea Concrete Institute, 2018
[193] Alterations in use of space, air quality, temperature and humidity by the presence of vertical greenery system in a building corridor
Urban Forestry & Urban Greening, 2018
[194] Shading Effect and Heat Reflection Performance of Green Façade in Hot Humid Climate Area: Measurements of a Residential Project in Guangzhou, China
IOP Conference Series: Earth and Environmental Science, 2018
[195] Morphological Changes of Mexican Native Succulent Plants in a Vertical Greenery System Compared with Pot Conditions
2018
[196] A Comparative Approach to Artificial and Natural Green Walls According to Ecological Sustainability
2018
[197] Promoting Vertical Greening in High-rise Residential Buildings within Urban Areas
2018
[198] Vertical Greening Systems for Pollutants Reduction
Nature Based Strategies for Urban and Building Sustainability, 2018
[199] Well-being, health and urban coherence-advancing vertical greening approach toward resilience: A design practice consideration
Journal of Cleaner Production, 2018
[200] The impact of urban green infrastructure as a sustainable approach towards tropical micro-climatic changes and human thermal comfort
Urban Forestry & Urban Greening, 2018
[201] A Breathing System for Cities: Vertical Green Systems
Science, Ecology and Engineering Research in the …, 2018
[202] A Study on the Compressive Strength Properties and Quality Control of Lightweight Foamed Magnesia Composite Using Super Absorbent Polymers as Base Material …
2018
[203] THE USE OF LIVING WALLS IN EGYPTIAN RESIDENTIAL BUILDINGS: IDENTIFYING THE PERCEPTIONS AND CHALLENGES
HEALTH: THE DESIGN, PLANNING AND POLITICS OF HOW AND WHERE WE LIVE, 2018
[204] GROWTH AND HAEMATOLOGICAL PARAMETERS OF JAPANESE QUAILS (Corturnix cortunix japonica) FED DRIED CORN SILK POLYALTHIA LONGIFOLIA LEAF …
2018
[205] Factorially Derived Cultural Factors of Gaborone Senior Secondary School Students and Mathematics Performance
2018
[206] Effect of different levels of feed added coriander (coriandrum sativum) leaves meal on the performance, carcass quality, immune response and blood profile of quails …
2018
[207] Field evaluation of precipitation
2018
[208] APPLYING BIOMIMETIC APPROACH FOR ENERGETICAL RETROFIT OF THE RAI SKYSCRAPER IN TURIN
2018
[209] DUAL SYSTEM AND HYBRID PUMP
2017
[210] Maximising the Potential of Transitional Space in Building for Improving Thermal Comfort through Vertical Greeneries
2017
[211] An analysis on the potentials of Vertical Greenery System (VGS) in context to the application viewpoint
2017
[212] The Effect of Living Wall Systems on the Heat Resistance Value of the Façade
2017
[213] Evaluación del potencial de uso de building information modeling (BIM) para apoyar la mantención de envolventes verdes
2017
[214] Advantages and Risks of Vertical Gardens
Journal of Bartin Faculty of Forestry, 2017
[215] Dikey Bahçelerin Avantajlari ve Riskleri
Journal of Bartin Faculty of Forestry, 2017
[216] The effect of living wall systems on the thermal resistance of the façade
Energy and Buildings, 2017
[217] Green walls for greywater reuse: Understanding the role of media on pollutant removal
Ecological Engineering, 2017
[218] Cooling effect of direct green façades during hot summer days: An observational study in Nanjing, China using TIR and 3DPC data
Building and Environment, 2017
[219] Determination of Some American Grapevine Rootstocks' Suitability for Vertical Gardens as a New Edible Landscape Component
2017
[220] Determination of the Suitability of Some American Grapevine Rootstocks as a New Edible Landscape Component of Vertical Gardens
Sustainability, 2017
[221] Residents' Perceptions towards the Application of Vertical Landscape in Cairo, Egypt
International Journal of Architectural and Environmental Engineering, 2017
[222] Vertical greening systems–A review on recent technologies and research advancement
Building and Environment, 2017
[223] ПРОБЛЕМИ ТЕПЛОВОГО ЗАБРУДНЕННЯ СЕЛІТЕБНИХ ТЕРИТОРІЙ: ДОСЛІДЖЕННЯ ТА МОНІТОРИНГ
2017
[224] Uso de Vegetação na Envlovente Vertical dos Edifícios
Dissertation, Open Repository of the University of Porto, 2017
[225] Improving Thermal Comfort through Vertical Greeneries in Transitional Spaces for the Tropical Climate: A Review.
GSTF Journal of Engineering Technology, 2017
[226] Estimating the Untapped Cooling Power of Green Walls as Evaporative Coolers for Buildings
2017
[227] Green walls: a sustainable approach to climate change, a case study of London
Synthetic Communications, 2017
[228] Assessment of environmental performance of vertical greening systems
2017
[229] Sistemi innovativi di living wall system: prestazioni ambientali e tecnologiche
2017
[230] Improving Thermal Comfort through Vertical Greeneries in Transitional Spaces for the Tropical Climate: A Review
2017
[231] Estimating the cooling power through transpiration of vining green walls in various climates
2017
[232] An Analytical Approach to Vertical Green Systems in High Rise Buildings
2017
[233] Comportamento térmico do sistema modular GEOGREEN, com incorporação de PCMs
2016
[234] FOTOBİYOREAKTÖRLER VE SÜRDÜRÜLEBİLİR BİNA UYGULAMALARI
Dokuz Eylül üniversitesi Mühendislik Fakültesi Fen ve Mühendislik Dergisi, 2016
[235] Aos professores do mestrado, que de formas tão diferentes contribuíram para meu conhecimento, ampliaram meus horizontes e somaram competências. À …
2016
[236] The use of edible vertical greenery system to improve thermal performance in tropical climate
2016
[237] Façade integrated photobioreactors for building energy efficiency
2016
[238] 綠牆系統溫度及熱傳遞影響因素分析之研究-以台灣建築為例; Analysis of Factors Related to Green Wall Temperature Performance and Heat Transfer: Case Study of …
2016
[239] Energy Efficient Plant Design Approaches: Case Study of the Sample Building of the Energy Efficiency Training Facilities
International Journal of Energy and Power Engineering, 2016
[240] Developing a green maintainability framework for green walls in Singapore
Structural Survey, 2016
[241] The state of the art of living walls: Lessons learned
Building and Environment, 2016
[242] Concept development for a bionically-mathematically inspired greened cooling cladding.
2016
[243] Jardins verticais: modelos e técnicas
2016
[244] Fachadas verdes e comportamento térmico urbano
2016
[245] The application of air layers in building envelopes: A review
Applied Energy, 2016
[246] Exploring the use of edible and evergreen perennials in living wall systems in the Scandinavian climate
Urban Forestry & Urban Greening, 2016
[247] Vertical Greening Systems and Sustainable Cities
Journal of Urban Technology, 2016
[248] Transfunctional living walls-designing living walls for environmental and social benefits
2016
[249] A Review on Green Wall, Classification and Function
2016
[250] The Effect of Green Facades in Landscape Ecology
Procedia Environmental Sciences, 2016
[251] FEN VE MÜHENDİSLİK DERGİSİ
2016
[252] The impact of ecological architecture trough systems of flat roofs and'vertical gardens' to improve the quality of environment
2016
[253] Controlling ivy attachment to wall surfaces by applying paints, metal meshes and sheets
2016
[254] Analysis of environmental performance of indoor living walls using embodied energy and carbon
2016
[255] Yaşayan kabuk sisteminin yağmur suyu kontrolüne etkisi: İTÜ Taşkışla Yerleşkesi
2016
[256] Form, function and cognition: A review of the role of building Integrated vegetation in green building and ecological city
SCIENTIA SINICA …, 2015
[257] Sistemas constructivos de fachadas que incorporan vegetación. Una revisión del estado del arte
2015
[258] 臺北市間接型養成式綠牆植物種類篩選與應用
臺灣大學園藝學研究所學位論文, 2015
[259] Living walls in urban landscape
Науковий вісник Національного університету біоресурсів і природокористування України. Серія: Лісівництво та декоративне садівництво, 2015
[260] An Experimental Study on Bioclimatic Design of Vertical Greenery Systems in the Tropical Climate
The Malaysia-Japan Model on Technology Partnership. Springer Japan, 2015
[261] Green wall systems: A review of their characteristics
Renewable and Sustainable Energy Reviews, 2015
[262] Green Infrastructure: Incorporating Plants and Enhancing Biodiversity in Buildings and Urban Environments
2015
[263] Study of embodied energy and carbon for indoor living walls
2015
[264] 形式, 功能与认知: 建筑绿化在绿色建筑与生态城市中的角色
2015
[265] Designing Green Façades and Living Wall Systems for Sustainable Constructions Designing Green Façades and Living Wall Systems for Sustainable Constructions
International Journal of Design & Nature and Ecodynamics, 2014
[266] 基于数值模拟分析的生态绿墙环境效应
沈阳建筑大学学报(自然科学版), 2014
[267] The next green hectare will be vertical
2014
[268] COMPARATIVO DE ENERGIA EMBUTIDA EM DIFERENTES COMPOSIÇÕES DE FACHADAS VIVAS–ENTAC 2014–MACEIÓ–AL
2014
[269] A BUILDING AS A GARDEN-A GARDEN AS A HOUSE
European Scientific Journal, 2014
[270] PLANT SURVIVAL FOR LIVING WALLS IN A SUBTROPICAL CLIMATE
2014
[271] Bioreceptivity evaluation of cementitious materials designed to stimulate biological growth
Science of The Total Environment,, 2014
[272] Emergy based evaluation of environmental performances of Living Wall and Grass Wall systems
Energy and Buildings, 2014
[273] Plant performance in living wall systems in the Scandinavian climate
Ecological Engineering.Elsevier, 2014
[274] Designing Green FaÇades And Living Wall Systems For Sustainable Constructions
International Journal of Design & Nature and Ecodynamics, 2014
[275] A review of energy characteristic of vertical greenery systems
Renewable and Sustainable Energy Reviews, 2014
[276] 行人對於捷運施工圍籬設計形式之感受分析
臺灣大學學位論文, 2014
[277] Kentsel tasarımda dikey bahçeler
2014
[278] Simulazione del comportamento energetico di un fabbricato-tipo in assenza/presenza di tetto/parete verde per ottimizzare l'efficienza energetica degli edifici …
Report RdS/PAR2013, 2014
[279] The etg ee he ta e ill ee ti al
2014
[280] Analysıs of contrıbutıon of vertıcal gardens to urban sustaınabılıty: the case study of Antalya cıty, Turkey
2013
[281] Vertical Greening Systems and Their Importance to Sustainability in the Urban Environment
2013
[282] Energy performance of living walls in commercial buildings
2013
[283] Cost ebenefit analysis for green façades and living wall systems
Building and Environment, 2013
[284] Lifecycle based energy assessment of green roofs and walls
2013
[285] Planning Review: Application of Vertical Greening for Landscape Beautification in Taipei
International Review for Spatial Planning and Sustainable Development, 2013
[286] Analysis of Contribution of Vertical Gardens to Urban Sustainability: The Case Study of Antalya City, Turkey
?n?nü üniversitesi Sanat ve Tasar?m Dergisi,, 2013
[287] Valoracion de alternativas en paneles vegetales prefabricados
E Prieto Fernandez, 2013
[288] 學校圍牆綠美化感受效益之評估
臺灣大學建築與城鄉研究所學位論文, 2012
[289] The integration of vegetation in architecture, vertical and horizontal greened surfaces
International Journal of Biology, 2012
[290] Urban food growth: Designing for vertical building surfaces
2012
[291] Feasibility study of green noise barriers in Hong Kong
2012
[292] ECOLOGICAL BENEFITS OF GREENING BUILDING ENVELOPES
2012
[293] Vertical greening systems: contribution to thermal behaviour on the building envelope and environmental sustainability
2012
[294] A sustainability evaluation of vertical greenery systems based on emergy
2012
[295] Jardins Verticais: um contributo para os espaços verdes urbanos e oportunidade na reabilitação do edificado
2012
[296] Design and analysis of energy saving buildings using the software energy plus
2012
[297] PUA
[298] Vertikální zahrady jako způsob ochlazování prostředí městské zástavby
[299] ENERJİ ETKİN PEYZAJ TASARIM YAKLAŞIMLARI
[300] An Urban Landscape
[301] GREEN ENVELOPE: AN ARCHITECTURAL STRATEGY FOR ENERGY EFFICIENCY IN BUILDING
[302] Cleaner Engineering and Technology
[303] Framework conditions and implementation scenarios for green infrastructure in schools
[304] URBAN HORTICULTURE AND VERTICAL FARMING
[305] THERMAL BALANCE OF VENTILATED FAÇADES IN WINTER AND SUMMER: GREEN VS. CLADDING
[306] ΠΡΟΓΡΑΜΜΑ ΣΠΟΥΔΩΝ: ΠΕΡΙΒΑΛΛΟΝΤΙΚΟΣ ΣΧΕΔΙΑΣΜΟΣ ΠΟΛΕΩΝ ΚΑΙ ΚΤΙΡΙΩΝ
Free SCIRP Newsletters
Copyright © 2006-2024 Scientific Research Publishing Inc. All Rights Reserved.
Top