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Blue-Green Infrastructure Virtual Symposium – Technologies For Managing Stormwater

Learn how to plan & design efficient blue-green systems to mitigate the effects of urbanization and the economic justifications to invest in blue-green technologies. Blue-Green Infrastructure projects are gaining popularity due to their effectiveness in mitigating urban flooding while also addressing a number of other challenges including biodiversity, urban heat island, air quality and more!  Learn how to plan and design efficient blue-green systems to mitigate the effects of urbanization and the economic justifications to invest in blue-green technologies. Designers will share captivating designs and case studies that dispel current myths about blue-green roofs and how they enhance the urban landscape while improving resilience and human health.  Pending approval for 4 AIA, ASLA, and GRP CEUs  check this site out Admission: $59 USD  Admission Date: February 23, 12:00 PM – 5:00 PM EST  Date

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Projects

In harmony with nature – the first car wash with intelligent rainwater management and a solar green roof

An unusual car wash has been available in Ochtrup for some time now: The wi-wash car wash on Hauptstraße is equipped with a greened hall roof, offering many advantages. An unusual car wash has been available in Ochtrup for some time now: the wi-wash car wash on Hauptstraße is not only impressive because of its technically sophisticated and high-performance equipment, which offers everything needed for the perfect washing and care of vehicles. In harmony with nature, the entire hall roof has also been greened and equipped with a solar system. This has many advantages. The car wash, which belongs to the Wischemann Group, is probably the only car wash whose roof is completely greened. The idea came from Optigrün international AG, the market leader in green roofs and a long-standing customer service. For many years, Wischemann has been producing a large part of the drainage panels developed by Optigrün for their green roof systems. It was a logical consequence for Ingo Wischemann, builder and owner of the Wischemann Group, the most important plastics specialist for innovative thermoformed parts and thermoforming processes in Europe, to use the advantages of green roofs for the washing park and thus to build sustainably at the same time. Intelligent rainwater management The greening of the hall roof was carried out using the water-retention roof system developed by Optigrün. The system for different types of green roofs can retain large amounts of rainwater – in this case up to 75,000 litres. The WRB 80F water-retention boxes used here are 80 mm high plastic hollow bodies that are used in the drainage level. With the help of the Optigrün Smart Flow Control, an intelligently server-controlled throttle, a defined outflow of the water as well as a permanent water accumulation in the retention boxes is determined. In this way, the retention area is divided into a temporary and a permanent water reservoir. The stored water is transported via capillary bridges into the fleece that lies on top of the retention boxes. The water is distributed over the entire surface via the fleece and keeps the overlying substrate layer moist. Thus, the precipitation water is available to the vegetation for evaporation or can also be used in the washing park. The temporary storage tank in the retention area is emptied with a long delay when needed – for example, during a predicted rain event – via the throttle operated by an intelligent control system. In this way, low discharge restrictions can be adhered to and protection against flooding is provided even during rain events with large annualities.  Advantages of a green roof A green roof not only binds CO2 and particulate matter, but also acts as insulation. In winter it protects against the cold and in summer the building and the surrounding air do not get as hot as with ungreened buildings. In addition, a green roof protects the roof cladding from damage caused by the effects of heat/cold and hail. Evaporation via the drought-resistant vegetation contributes to maintaining the natural water balance and at the same time lowers the ambient temperature. In addition, the sewer system is relieved, drains can be reduced, sewer pipes can be made smaller and stormwater overflow basins can be saved. A retention green roof also has a positive effect on biodiversity and the microclimate. In addition, the green roof provides a habitat for flora and fauna. Green electricity from the roof for the charging columns In terms of sustainability, however, the construction of the car wash was not just about using rainwater. Rather, a photovoltaic system was also installed on the roof. The combination of green roof and photovoltaics does not represent a conflict of objectives but is the ideal symbiosis for a sustainable development. Thus, the roof area of the car wash not only offers space for the expansion of renewable energies. Rather, the combination of green roof and solar roof increases the economic and ecological functionality of the building. This is because the efficiency of energy generation from solar modules decreases with increasing temperatures. The green roof, however, increases the efficiency because the temperature of the modules rises more slowly due to the evaporative cooling of the vegetation. The electricity, which is generated in a resource-saving way, can be stored on site by six storage units so that it can be used as needed or fed into the electricity grid. For example, the temporarily stored electricity can be used by customers at the e-charging station while they are vacuuming. This is an innovative solution for solar green roofs. The Optigrün-Solar WRB system used on the roof of the car wash is a load-bearing solar elevation that is fixed in place by the green roof structure to prevent wind suction. Thus, no penetration of the roof is necessary, which in turn avoids damage to the roof cladding. The Optigrün-System Solar WRB consists of an aluminium base plate on which the water retention box is placed. Brackets used as module supports are inserted and screwed into the supports of the base plate. The individual elements are connected with the help of quick-assembly module rails. The solar elevation is then ballasted with substrate. The clear advantage of ballasted solar elevations is that the roof cladding does not have to be penetrated. Damage to the roof cladding and consequent repair work or leaks are thus ruled out. For care and maintenance work, the Optigrün- Optisafe ALS, a rope-guided restraint system, was used as fall protection. Up to two people with their protective equipment can be suspended here at the same time. The washing park in Ochtrup shows in an impressive way that with good planning and the right system the effects of climate change can be mitigated. More details: Owner: Wischemann Group Planning: Dorin-Immo GmbH & Co. KG Execution of Greenroof: Marcel Nadorf GmbH Supply of solar green roof and planning support: Optigrün international AG. © Optigrün international AG © Optigrün international AG © Optigrün international AG © Optigrün international AG Project details: Car Wash

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World Green Infrastructure Congress 2023

The World Green Infrastructure Congress (WGIC), took place 27-29 June, 2023 in Berlin & online.  After six years, the World Green Infrastructure Congress 2023 (WGIC) was held in Berlin & online from 27 to 29 June 2023! The last World Congress, also held in Berlin, was fully booked, with over 800 participants from 44 countries. To follow up on the successful event in 2017, this years congress was available in person and online to provide various opportunities to participate. This multi-day event was aimed at planners, contractors, local-, state- and federal politicians, investors and companies in the sector, concerning the greening of buildings (greening of roofs, façades and indoor areas) with the associated accompanying topics (e. g. urban climate, rainwater management, sustainability).    During day one and two, there were presentations by more than 100 speakers from 29 countries, dealing with various topics around green infrastructure on a global level. On day three, it was possible to participate in field excursions in the city of Berlin. Please see images below. The congress offered: Take a look at the trailer for WGIC 2023. View the full program here.View the event flyer here. Sponsors and congress partners: The event is presented by Bundesverband GebäudeGrün e.V. (BuGG), supported by international and national partners, as well as 23 congress and 10 media partners. For more information, please consult our website: www.bugg-congress2023.com ……………………………………………………. World Green Infrastructure Congress 2023 Date: 27. – 29. June 2023 Venue: MERCURE HOTEL MOA BERLIN, Stephanstrasse 41, 10559 Berlin Moabit, GermanyFront desk: +49 30 394043 – 0www.hotel-moa-berlin.de WGIN presented the 2023 Global Awards for best green infrastructure practice at the World Green Infrastructure Congress 2023! View the winners here. Some speakers of WGIC 2023 Rebecca Gohlke (MSc) shares a report on Urban Dialogue Building Green Municipal Funding Instruments. Dr. Marta Weber-Siwirska reflects on the challenges and possibilities of implementing green solutions in Polish cities. Paolo Russo shares highlights of his study titled “From Green obsession to vertical forests”. Professor Helga Fassbinder talks about Biotope City. The dense city as nature: the case of Wienerberg, Vienna Chintan Raveshia takes us through Singapore’s journey from a Garden City to a City in Nature. Dr. Eugenia Lin took us on a journey to Taiwan, sharing the exciting and impressive green roof projects of Taiwan.  Dominik Gooner (M.Eng) discusses modern stormwater management of urban quarters captioned Blue-Green and Smart. Prof. Nicholas Williams, University of Melbourne, shares a study of quantifying the local benefits of green roofs & provides the evidence base for planning and policy changes in Melbourne. Mathias Johr shares the technical intricacies of rainwater management on green roofs and barrier-free roof terraces. WGIN EU Chapter’s Antonin Chapelot gives an overview of EU policies on urban greening targets. Green Infrastructure Tour of Berlin:

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Projects

Greening projects in Philadelphia, highlighted at the Cities Alive Conference, 16-19 Oct 2022

Downtown Philadelphia: Project “the Arthouse”, a new highrise building. For the apartment owner, available are not only the typical amenities, such as a pool deck. Also available is a roof garden with various urban gardening spaces. “A new trend in urban greening” The old Silk factory: Back yard roof gardens, private roof spaces with an exiting skyline view to downtown Philadelphia. discover more Philadelphia, for more than 10 years, has been known for it’s rainwater policy. Cira Green is a public open roof park on a multi store garage. It is equiped with an extra drain layer to maximise the local water retention. It is open all day, free to the citizens to enjoy sykline and plantings. A number of Living walls and climbers highlight the new trend in urban greening. Here an example at the Museum of Independance in the museum quarter in Philadelphia. Cities Alive ForumYear: 2022City: PhiladelphiaLocation: USA

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Grey to Green Virtual Conference

Green Roofs for Healthy Cities (GRHC) is excited to announce the Grey to Green Conference, to be held virtually on June 22 from 10am – 4:30pm and June 23 from 10am – 6pm est.  Cost: $175 USD for one day, or $349 USD for both days. © Green Roofs for Healthy Cities The goal of this virtual green infrastructure conference is to help inform the current policy debate by making the case for a rapid and significant increase in green infrastructure investment in our COVID-19 recovery. Grey to Green will feature a variety of sessions including standard panel discussions and ask an expert sessions. The conference will also have virtual networking so you can catch up with other attendees and share insights on green infrastructure. It will also include a Future Proof Design Jam, where a select number of attendees will reinvent six real urban spaces in Canada through the lens of green infrastructure. Admission to the Future Proof Design Jam is FREE for all 2 Day Conference Registrants, but space is limited. Speakers include: • Peter Kindel, AIA, RIBA, ASLA, on the tenets of Biomorphic Urbanism and illustrates how these design principles can restore natural systems while enhancing the human experience. • Cecil Konijnendijk, Director, Nature Based Solutions Institute, will be presenting on the evidence-based guidelines for greener cities: the case of the 3-30-300 rule. • Henry Gordon-Smith, Founder & CEO of Agritecture, on exploring the Role of Urban Food Production in future-proofing our cities. • Jennifer Bousselot, Ph.D., GRP, Assistant Professor of Horticulture, Colorado State University, will be at the ask an expert session to discuss everything and anything related to agrivoltaics.

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Cities Alive Conference again in life: October-16-19th in Philadelphia

CitiesAlive 2022 Call for Proposals & Call for research Papers now open! Submit your Proposal by Saturday April 30, 2022 CitiesAlive 2022 have officially launched their Call for Session Proposals and Call for Research Papers! They welcome all interested parties to submit a proposal for a 30, 60, or 90 minute Session Proposal (general presentation, not research specific), or a 10-30 minute Research Presentation (must include abstract to be peer reviewed by a panel of qualified CitiesAlive Advisory Committee academics). Submissions are due by April 30th, 2022. You are invited to review the submission process and related criteria for submitting by clicking here. CitiesAlive® is back in 2022 in Philadelphia at the DoubleTree by Hilton – Philadelphia City Center. The conference will be held from Sunday October 16th to Tuesday October 18th, with an additional day of tours on Wednesday October 19th. The theme of this year’s conference is Green Infrastructure & Water in a Changing Climate. Water is critical to the health and resiliency of our communities. Over the last several years, Philadelphia has become a green infrastructure leader through creative policy solutions that work to create vibrant community spaces while managing stormwater. In 2011 the Philadelphia Water department implemented a plan to invest $1.2 Billion over the next 25 years. CitiesAlive® 2022 is a multi-disciplinary conference, bringing together the best designers, product manufacturers, researchers, and policy makers in the field of living architecture and green infrastructure. Attendees will hear from leading-edge designers, discussing their innovative approaches and newest projects. We will be highlighting progressive policies and showcasing the latest research. Join us in shaping a better, more resilient future. For more information visit www.citiesalive.org Marketing and Promotional Opportunities Brochure 

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Key Definition: Living Wall

Living wall: A living wall is a vertical vegetated wall system with irrigation. A living wall system is variable depending on the climatic conditions and there is no proven formula for plant specification, even the most successful walls have evolved from the time of initial installation with the plant palette changing. Interior living walls require supplementary ‘grow’ lights and irrigation with drip trays and drainage outlets. The most lightweight system is hydroponic with two layers of felt matting stapled to poly-board and fixed to a structural wall aka Vertical Gardens / P.Blanc. Slits allow plants to grow in pockets initially until the root system spreads between the two felt layers. The felt is kept constantly damp with nutrient levels specifically maintained. This system was originally developed by Patrick Blanc in 1986 in Paris. In their more elaborate form, living walls and may incorporate water elements including ponds and ?sh, which provide essential nutrients. Living walls may also be incorporated into the cooling strategy of a house, as a kind of evaporative air conditioner, and they may even be designed as part of a water treatment system. TYPES OF LIVING WALLS Living walls, i.e. vegetation growing on or against vertical surfaces, can be found outdoors or indoors on any type of vertical surface, from building façades to boundary demarcation or even free-standing support. They can be incorporated into new construction or easily retrofitted to existing buildings. Living walls can vary considerably in construction; they can be rooted in or off the ground (i.e. soilless), in several kind of growing media (mineral or organic), or in an inert medium acting only as a rooting element. According to the type of structure, the system can be either ‘completely natural’ or hydroponic. Irrigation can be manual or automatic. Living walls have been divided into three main categories: green façades and green walls; however the concept of the green wall can be extended to a wider range of systems: urban hedges, stone walls, green screens, live curtains and modular planter walls. Green façades Green façades are made of climbing plants growing on a wall either with no additional infrastructure, or with the use of stainless steel or wooden trellis, meshwork, or cabling, as plant support. They are historically set outdoors, rooted in the ground and don’t require additional irrigation. They can also be off the ground and erected indoors, usually free-standing with irrigation. The great diversity of climbing plants, in terms of flower and foliage colours, flowering season, profile, etc. make them attractive for humans. They can be evergreen or deciduous and are usually woody and perennial, although some can be herbaceous or/and annual. As they use different ways of adhering to a surface, they need different kinds of support either vertical and/or horizontal, or no support at all in the case of self-adhering climbers such as Hedera helix(common ivy), Parthenocissus sp. (Boston ivy) or Wisteria sp. (Virginia creeper).Plants that can be trained against the wall or in espalier (e.g. Camellia sp., Ceanothus sp., Chaenomeles sp. (“flowering quince”), Coronilla valentine (scorpion vetch), Garrya sp., Fuchsia sp., Magnolia grandiflora, Pyracantha sp.) referred to as ‘wall shrubs’ can be included in the term ‘green façade’. Green Walls Green walls are recently developed, completely artificial systems, using continuous or modular, planted-up, units. Continuous living wall systems can be made of felt-layers or be a block of concrete. Modular panels are using modules of sphagnum, substrate filled metallic cage, gabions, preformed plastic modules or rockwool units. Plants are rooted directly in the structure (in the case of felt layers or sphagnum units) or in growth medium, beforehand added to the structure (for concrete block, rockwool, plastic preformed module or gabion panel). The growing media can be organic materials such as coconut coir (Cocos nucifera L.), peat, tree bark, or inorganic materials such as expended clay pebbles, gravel, perlite, mineral soil, mineral wool, sand, vermiculite; although different components are often used in mixes. The system is usually hydroponic (i.e. the mineral nutrients are brought to the plant as inorganic ions in water). Any plant species can be grown on a living wall system. Typically, the only constraint is the weight of the mature plant; some felt layers systems have been shown to support tree species. Indoor walls are usually planted with tropical species due to the constant mild temperature and the lack of light; while outdoor walls are more restricted to rustic plants. Living walls are sometimes referred to as “vertical gardens” when they are used to grow herbs and/or plants producing vegetables or fruits. When growing herbs, the green wall is usually called a “herb wall”.Depending on the system and the manufacturer, units are either pre-grown in greenhouse (vertically or not) prior to installation or planted on site once installed. Intermediate living walls Green Façades and Green Walls are the opposites, in terms of complexity of structure and man-made features, of the large panel of the green wall concept. Between these two can be found features like Green screens, made of a climbing plant (typically Hedera sp.), pre-grown on a freestanding, galvanized steel framework, and established as an instant hedge. They are usually included in the concept of green façades. However, the facts that they are commercially pre-grown in nursery, completely free-standing when historically green façades are against walls, and usually installed with automatic irrigation, may set them apart from green façades. Live curtains combine the features of green façades and living walls. Like green façades, this system is made of plants climbing on a structure, but rooted off the ground, in small planter boxes, as hydroponic systems like living walls.Urban hedges can be considered as part of the green wall concept as they are interchangeable with green façades or living walls for some of their features and ecosystem services.Stone walls are horizontal structures of overlapping stones build upwards, with successive rows of stones overlapping each other. The space between two rows is filled with smaller stones and sometimes with capping stones bridging the top. A distinction is made between dry stone walls and mortared walls that are usually more shaped with

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Key Definition: Green Roof

Green roof: (Also referred to as living roofs; eco roofs; ecotecture; roofscapes.) Their usage dates back to 10thC BC throughout Persia with particular reference to Babylon, as green roofs were used as a storm-water management system irrigating a stepped series of planters throughout the city creating a lush cool urban environment aka the Hanging Gardens of Babylon. Scandinavian ‘sod’ roof housing has been built since 1000AD to insulate dwellings during summer and winter. Throughout the 20thC there were progressive architects using vegetated roof-tops, however it was not until a green roof renaissance started in Germany during the 1980’s with R&D by FLL producing a definitive guideline for specification of green roofs. In 1986, Patrick Blanc pioneered his irrigated felt Verticle Garden (aka living wall) in Paris, which completed a technology capable of vegetating every building facade. The technology is now referred to as ‘Building Integrated Vegetation (BIV) systems. Definition: A green roof is a vegetated roofing system which is functionally integrated onto a roof area. Designs are site specific depending on climatic conditions; slope; access; structural capacity and intended usage. Standard components are a tested waterproofing membrane; root barrier; drainage outlets; drainage layer; geofabric; grow media; vegetation; irrigation; maintenance regime. Green roofs are sometimes referred to as the fifth façade. There are three kinds of green roof: extensive; semi intensive & intensive, each type requiring particular engineering. A simple way to differentiate the types is :- EXtensive is less / INtensive is more. Types: Extensive Green Roofs: Shallow growing medium – 90 to 300mm.Roof engineering similar to conventional standards.Vegetation limited to shallow rooting plants.Relatively economical.Relatively easy to retrofitAverage saturated weight @ 150kg/sqm Semi Intensive Green Roofs: Grow medium depth – 300 – 500mmPlant range; ground cover to small treesIrrigation suggestedRoot barrier suggested Intensive Green Roofs: Deep growing medium – 500mm or greater.Greater saturated load..Wide range of plantings possible.Relatively expensive.Greater benefits, insulation, water retention etcRoot barrier & Irrigation suggestedLeak detection system suggestedHigher biodiversity Green roofs may appear as manicured lawns or natural plant communities. Extensive green roofs that use a thin layer of growing medium to support ground cover plants with short roots are generally designed with building performance in mind rather than aesthetic concerns. Sloping and curved extensive green roofs may be seen from ground level. Intensive roofs can support quite substantial, highly visible vegetation, cascading over the sides of the building or as shrubs and trees rising above the roo?ine. These are commonly referred to as roof gardens. By creating a landscaped surface green roofs can radically change a building’s ‘roof line’. Green roofs and external green walls (which can be small and incidental or large and dramatic) extend the scope for creating pleasant urban environments by introducing plants and greenery that are visually restful or refreshing. Proven therapeutic effects include increased productivity with improved concentration levels; improved psychological health and happiness. BENEFITS: Green roofs provide a multitude of benefits to the people who interact with them and the cities and regions in which they exist. Benefits are delivered across three spheres, environmental, economic and social, making green roofs a truly sustainable feature. In fact, it would be hard to argue that any other architectural element of a building can have such wide and profound benefits as a green roof does. The benefits of a green roof range from a single user observing a roof to reducing the planet’s CO2 emissions through sequestration. The benefits described below have been dived up into Environmental, Economic and Social sections. However, as with true sustainability, many of these overlap. A further distinction is made if the benefit is private, that is mostly delivered to a signal person or organization, or public, those benefits derived by all. Many green roofs deliver both public and private benefits, making green roofs an equitable and egalitarian solution for our cities and homes. Social Benefits Physiological/mental health Green roofs can improve a person’s mental and physiological function by allowing them to view ‘natural’ scenes and elements. Such experiences have been shown to relieve stress, improve productivity and reduce blood pressure. Improved Biophilia “A human’s innate need to connect with Nature” Exposure to nature or natural scenes, even for periods of as little as 3-4 minutes, has been shown to reduce symptoms of stress and restore cognitive function. Most city cores have a lack of either accessible or viewable green space, thus denying city-dwellers a means to escape from the demands of their daily lives or the opportunity for mental rejuvenation.  The inability to experience nature’s involuntary stress reliving power can place people at risk of poor productivity, anti-social behaviour or symptoms of mental illness. Green roofs supply an important resource of ‘natural environments’ in a landscape dominated by built structures. Due to the built form of many modern cites, green roofs might be the only option for introducing green space. Green roofs can deliver many public and private physiological benefits. In the case of an office roof garden for example, it may provide a venue for relaxation, socialising or ‘time out’ for the employees of the building, improving staff wellbeing and productivity. The same roof however can also be viewed by an office worker in an adjacent building and they too can enjoy the mental respite by simply viewing the natural elements of a green roof. The ability of green space to relive stress and improve physiological function has seen an increase in installation of green roofs in European and North American hospitals. In the redesign and redevelopment of the Royal Children’s hospital, Melbourne, the use of evidence-based design led to the installation of 360m2 green roof for use by patients, staff and visitors alike. Increased Amenity and recreation opportunities Many cities lack adequate open space. Green roofs provide an opportunity to increase the amount of useable space available for the pursuit of both passive and active recreational activities. Since they are composed of natural elements and replace underutilised space, green roofs can also improve the quality and attractiveness of building and its surrounding location. The high population

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Key Definition: Green Infrastructure

Green Infrastructure: There is an international movement towards the regeneration of urban landscapes due to an increased awareness about human impact on the environment. As urban development and populations increase there is a greater demand to improve upon the planning mistakes of the past. There is a movement towards mitigating the impact of impermeable urban infrastructure materials such as concrete by including permeable pedestrian paths, bio-swales, street planting, green roofs, green walls, rejuvenated wetlands, urban forests, parklands and other vegetative systems into the urban fabric. Green Infrastructure refers to any vegetative infrastructure system which enhances the natural environment through direct or indirect means. It describes the network of green spaces and water systems that deliver multiple environmental, economical and social values and benefits for sustainable urban development. Green Infrastructure includes green roofs, living walls, parks and reserves, backyards and gardens, waterways and wetlands, streets and transport corridors, pathways and green corridors, squares and plazas, sports fields and cemeteries. Green Infrastructure provides and connects vital ecosystem services which contribute or enhance urban sustainability and the natural environment. GI: a strategically planned network of natural and semi-natural areas with other environmental features designed and managed to deliver a wide range of ecosystem services. It incorporates green spaces (or blue if aquatic ecosystems are concerned) and other physical features in terrestrial (including coastal) and marine areas. On land, GI is present in rural and urban settings ie green roofs, living walls, rain gardens, parks, community gardens, canopy cover, parklands, urban forests. Green Infrastructure Benefits include storm-water management, climate adaptation, mitigation of Urban Heat Island Effects, enhanced biodiversity, carbon sequestration, enhanced air quality, sustainable energy production, enhanced storm water quality returning to the natural environment and to deep soil profiles, improved anthropocentric functions such as increased quality of life and improving biophilia. Green Infrastructure (GI) / Enhancing Natural Capital Overview: Human society depends on the benefits provided by nature such as food, materials, clean water, clean air, climate regulation, flood prevention, pollination and recreation[1]. However, many of these benefits, frequently referred to as ecosystem services, are used as if their supply is almost unlimited and treated as free commodities whose true value is not fully appreciated. This can result in public authorities turning to built infrastructure — grey infrastructure — as a substitute for natural solutions to problems such as flood prevention. In Australasia we consequently continue to degrade our natural capital, jeopardising our long-term sustainability and undermining our resilience to environmental shocks. As stated in the Resource Efficiency Roadmap[2], the failure to protect our natural capital and to give a proper value to ecosystem services will need to be addressed as part of the drive towards smart, sustainable and inclusive growth.. The EU roadmap identifies investing in GI as an important step towards protecting natural capital. All AUS government tiers need to collaborate and establish a GI Commission to develop a GI strategy[5]. The EU Resource Efficiency Roadmap states that their Commission will draft a Communication on GI. This document is the Commission’s response to these commitments[6]. It sets out how EU-wide action can add value to the local initiatives currently underway. What is Green Infrastructure (GI)? GI is a successfully tested tool for providing ecological, economic and social benefits through natural solutions. It helps us to understand the value of the benefits that nature provides to human society and to mobilise investments to sustain and enhance them. It also helps avoid relying on infrastructure that is expensive to build when nature can often provide cheaper, more durable solutions. Many of these create local job opportunities. Green Infrastructure is based on the principle that protecting and enhancing nature and natural processes, and the many benefits human society gets from nature, are consciously integrated into spatial planning and territorial development. Compared to single-purpose, grey infrastructure, GI has many benefits. It is not a constraint on territorial development but promotes natural solutions if they are the best option. It can sometimes offer an alternative, or be complementary, to standard grey solutions.

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