World Library  
Flag as Inappropriate
Email this Article

Integrated Agriculture

Article Id: WHEBN0027754145
Reproduction Date:

Title: Integrated Agriculture  
Author: World Heritage Encyclopedia
Language: English
Subject: Agriculture, Controlled-environment agriculture, Lufa Farms, Urban agriculture
Publisher: World Heritage Encyclopedia

Integrated Agriculture

Building-integrated agriculture (BIA) is of the practice of locating high performance hydroponic greenhouse farming systems on and in mixed use buildings to exploit synergies between the built environment and agriculture.[1]

Typical characteristics of BIA installations include: recirculating hydroponics, waste heat captured from a building's heating-ventilation-air condition system (HVAC), solar photovoltaics or other forms of renewable energy, rainwater catchment systems, and evaporative cooling.[2]

The earliest example of BIA may have been the Hanging Gardens of Babylon around 600 BC. Modern examples include Eli Zabar's rooftop greenhouse, The Sun Works Center for Environmental Studies, Gotham Greens, Sky Vegetables, Top Sprouts, Cityscape Farms, Dongtan, Masdar City, AeroFarms, Solar 2, Lufa Farms, BrightFarms, and Big Box Farms.

The term building-integrated agriculture was coined by Dr. Ted Caplow in a paper delivered at the 2007 Passive and Low Energy Cooling Conference in Crete, Greece.[3]


Applications of BIA are motivated by trends in patterns of energy use, global population, and global climate change. Specific observations include:

  • Globally, modern agriculture uses 70% of fresh water withdrawals, is the world's largest source of water pollution, and the largest consumer of land.[4]
  • According to official UN estimates, global population is expected to exceed nine billion by 2050. Food travels hundreds of thousands of miles to reach urban consumers, adding to traffic congestion, air pollution and carbon emissions.[5]
  • Increased urbanization, results in marginalization of natural world and distance from food production.[6]
  • In the United States, buildings account for 39% of energy use, 68% of electricity consumption, 12% of water consumption, and 38% of carbon dioxide emissions.[7]
  • Global warming is predicted to lead to widespread shortages of food, water, and arable land by 2050.[8]

Environmental advantages

Proponents maintain that BIA is an environmentally sustainable strategy for urban food production that reduces our environmental footprint, cuts transportation costs, enhances food security / safety, conserves water, protects rivers, improves health, reduces waste, cools buildings, and combats global warming.[9] For example, hydroponics uses ten to twenty times less land and ten times less water than conventional agriculture, while eliminating chemical pesticides, fertilizer runoff, and carbon emissions from farm machinery and long distance transport.[10] Using a building's waste heat and solar photo voltaic panels reduces fossil fuel emissions that typically result from production and distribution. Rainwater catchment systems help to manage stormwater, much like a green roof.[11]


Integrating a farm into a building offers all of the building performance benefits of a more conventional green roof, and results in a lower combined energy bill than if the components were separate. These systems are achievable with extant technology. Projects such as Gotham Greens 10,000-square-foot (930 m2) greenhouse will cost approximately $1.4 million to build. Shulman, Robin. "Raising the Root: Some City Dwellers Are Hoping Rooftop Farming Will Bear Fruit.".[12] The economics of BIA were the subject of a 2011 article in the New York Times business section.[13]


Mohamed Hage, founder of Lufa Farms talks to Silver Donald Cameron.

BIA systems may be integrated into commercial, educational, and residential buildings of varying sizes. Feasibility varies based on building size, climate, availability of light, and new build vs. retrofit. BIA farms are located on the building's envelope to make maximum use of normal light. Both horizontal (rooftop) and vertical (façade) surfaces may be used.[14]

A sprinkling of rooftop hydroponic greenhouses can be found around the world, including at academic centers in the United States (Washington University and Barnard College, among others); on a hospital (Changi) in Singapore; in the Netherlands, in India, and in parts of the developing world.[15] The Science Barge, while not on a building, is widely credited with invigorating interest in BIA in New York City, following its 2007 public debut.


Example retrofit projects include: Eli Zabar's Vinegar Factory Greenhouse, which has been growing vegetables since 1995 heats his rooftop greenhouse with waste heat from the store's bakery.[16] Gotham Greens, a company building New York City's first commercial scale, hydroponic rooftop farm.[17] The Sun Works Center for Environmental Studies, a 21st-century environmental science lab being built on the roof of The Manhattan School for Children P.S. 333.

New build

Example new build projects include: Green Sky Growers rooftop farm, a commercial scale aqua-dynamic farm in Florida. The Forest Houses greenhouse, a fully integrated rooftop farm integrated onto the rooftop of an affordable housing complex.[18] Solar Two, an environmental learning center that will feature a Vertically Integrated Greenhouse.[19]


Proposed projects include Dongtan, a proposed eco-city island in Shanghai, and Masdar City, a carbon neutral city being built in Abu Dhabi.

Related concepts

Vertical farming is a proposed agricultural concept in which entire urban high-rise buildings, not just the building envelope, are dedicated to large-scale farming.[20] According to various researchers, to be realized vertical farms would require significant technological breakthroughs with regards to energy consumption and lighting.[21] It has been estimated that a prototype five-story farm would cost between $20 million to $30 million.[22]

Methane capture greenhouses utilize recovered landfill methane to heat their facility. Rutger’s EcoComplex includes a 1-acre (4,000 m2) commercial greenhouse heated by landfill gas, allowing for year-round production of food crops. The heat for H2gro’s greenhouse is produced using special heat recovery equipment surrounding 7 electrical generators at neighboring Innovative Energy. These generators are powered by methane gas collected from Modern Landfill. By using waste heat from the landfill gas to energy plants, carbon emissions are significantly reduced (as compared to traditional fossil fuel boilers that are often used to heat greenhouses).

In compost heated greenhouses, heat and carbon dioxide are generated from a manure-based compost contained in a special chamber attached to one side of the greenhouse.[23] The New Alchemy Institute designed and built an experimental composting greenhouse in 1983 to research opportunities for the production of biothermal energy.[24] Growing Power utilizes heat produced through vermicomposting to provide heat for their greenhouse.[25]

See also


  1. ^ Caplow, Ted. "Building Integrated Agriculture: Philosophy and Practice." Heinrich Böll Foundation: Urban Development and Urban Lifestyles of the Future 2009: 48–51.
  2. ^ Caroline McCarthy, for "New York barges into sustainable urban farming." New York Times 4 May 2007.
  3. ^
  4. ^ "The Global Environmental Outlook 4: Environment for Development." United Nations Environment Programme, 2007. pp. 104, 116, 420.
  5. ^ Pirog, Rich, and Andrew Benjamin. "Checking the Food Odometer: Comparing Food Miles for Local Versus Conventional Produce Sales in Iowa Institutions." 2003.
  6. ^ Caplow, Ted and Viraj Puri. "How to Grow Food in the 100% Renewable City: Building Integrated Agriculture." Droege, Peter. 100% RENEWABLE: ENERGY AUTONOMY IN ACTION. London: Earthscan, 2009. 229–242.
  7. ^ U.S. EPA, 2004, Buildings and the Environment: A Statistical Summary.
  8. ^ Lobell, David B. et al., 2008, Prioritizing Climate Change Adaptation Needs for Food Security in 2030, Science, 319, p. 607.
  9. ^ Nelkin, Jenn. "Building-integrated greenhouse systems for low energy cooling." 2nd PALENC Conference and 28th AIVC Conference on Building Low Energy Cooling and. n.d.
  10. ^ Wilson, Alex. "Growing Food Locally: Integrating Agriculture Into the Built Environment." Environmental Building News. 1 February 2009. [1]
  11. ^
  12. ^ "Raising the Root: Some City Dwellers Are Hoping Rooftop Farming Will Bear Fruit." Washington Post, 12 September 2009 [2]
  13. ^ "Cash Crops Under Glass and Up on the Roof" New York Times, 18 May 2011 [3]
  14. ^ "Vertically Integrated Greenhouse." The Buckminster Fuller Challenge. 5 May 2010. [4]
  15. ^ Wilson, Geoff. “Food from the Roof". 5 May 2010
  16. ^
  17. ^ Schwartz, Ariel."Gotham Greens Building First Hydroponic Rooftop Farm in NYC." 15 June 2009 [5]
  18. ^ Grover, Sammi. "First Ever Rooftop Farm on Affordable Housing Project." Treehugger. 10 February 2010 [6].
  19. ^ Green Career Profile: Greg Kiss. 6 May 2010
  20. ^ [7]
  21. ^ Vogel, Gretchen. "Upending the Traditional Farm." Science (February 2008): 752–753.
  22. ^ "A Farm on Every Floor, The New York Times, August 23, 2009."
  23. ^ ATTRA – National Sustainable Agriculture Information Service. 17 May 2010 [8]
  24. ^ Fulford, Bruce. "Composting Greenhouse at New Alchemy Institute: A Report on Two Years of Operation and Monitoring. Research Report No. 3." 1986.
  25. ^ "Composting And Local Food Merge At Urban Garden." November 2008. BioCycle. 17 May 2010. [9]

External links

  • The Science Barge
  • Kiss+Cathcart Integrated Agriculture
  • Financial Times article: Highly Productive
  • New York Sun Works – Building-Integrated Agriculture
  • New York Academy of Sciences: Shortening the Food Chain: Agriculture in Urban Centers
  • NY Times Blog Article: Food Advocates Envision Rooftop Gardens and Vertical Farms
  • Fast Company Article: Eat-onomics with Mike Yohay, CEO of Cityscape Farms
  • Buckminster Fuller Challenge – VIG
  • Treehugger article: First Summit on Building-Integrated Sustainable Agriculture
  • NY Times article:Visionaries Work to Get Rooftop and Vertical Farming Off the Ground
This article was sourced from Creative Commons Attribution-ShareAlike License; additional terms may apply. World Heritage Encyclopedia content is assembled from numerous content providers, Open Access Publishing, and in compliance with The Fair Access to Science and Technology Research Act (FASTR), Wikimedia Foundation, Inc., Public Library of Science, The Encyclopedia of Life, Open Book Publishers (OBP), PubMed, U.S. National Library of Medicine, National Center for Biotechnology Information, U.S. National Library of Medicine, National Institutes of Health (NIH), U.S. Department of Health & Human Services, and, which sources content from all federal, state, local, tribal, and territorial government publication portals (.gov, .mil, .edu). Funding for and content contributors is made possible from the U.S. Congress, E-Government Act of 2002.
Crowd sourced content that is contributed to World Heritage Encyclopedia is peer reviewed and edited by our editorial staff to ensure quality scholarly research articles.
By using this site, you agree to the Terms of Use and Privacy Policy. World Heritage Encyclopedia™ is a registered trademark of the World Public Library Association, a non-profit organization.

Copyright © World Library Foundation. All rights reserved. eBooks from Project Gutenberg are sponsored by the World Library Foundation,
a 501c(4) Member's Support Non-Profit Organization, and is NOT affiliated with any governmental agency or department.