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Aquaponics-Integration of Hydroponics with Aquaculture - Backyard PDF

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Aquaponics—Integration of Hydroponics with Aquaculture ATTRA A Publication of ATTRA - National Sustainable Agriculture Information Service • 1-800-346-9140 • www.attra.ncat.org By Steve Diver Aquaponics is a bio-integrated system that links recirculating aquaculture with hydroponic vegetable, NCAT Agriculture flower, and/or herb production. Recent advances by researchers and growers alike have turned aqua- Specialist ponics into a working model of sustainable food production. This publication provides an introduction ©2006 NCAT to aquaponics with brief profiles of working units around the country. An extensive list of resources point the reader to print and Web-based educational materials for further technical assistance. Contents In aquaponics, nutrient-rich effluent from fish tanks is used to fertigate hydroponic Introduction .....................1 production beds. This is good for the Aquaponics: Key fish because plant roots and rhizobacteria Elements and Considerations ................2 remove nutrients from the water. These nutrients—generated from fish manure, Aquaponic Systems .......3 algae, and decomposing fish feed—are con- The North Carolina State University System ..........4 taminants that would otherwise build up The Speraneo System ...5 to toxic levels in the fish tanks, but instead The University of the serve as liquid fertilizer to hydroponically Virgin Islands System ....7 Aquaponic vegetable bed in Australia. grown plants. In turn, the hydroponic beds The Freshwater Institute Photo by Joel Malcolm, Backyard Aquaponics. function as a biofilter— stripping off ammo- System ................................8 www.backyardaquaponics.com nia, nitrates, nitrites, and phosphorus— The Cabbage Hill Farm (with permission) so the freshly cleansed water can then be System ................................9 recirculated back into the fish tanks. The The New Alchemy Introduction nitrifying bacteria living in the gravel and in Institute ..............................9 association with the plant roots play a criti- Miscellaneous A quaponics, also known as the integra- Systems ............................11 cal role in nutrient cycling; without these tion of hydroponics with aquaculture, Organic Aquaculture ..11 microorganisms the whole system would Evaluating an Aquaponic is gaining increased attention as a stop functioning. Enterprise ........................12 bio-integrated food production system. Greenhouse growers and farmers are taking References ......................13 Aquaponics serves as a model of sus- note of aquaponics for several reasons: Resources ........................13 tainable food production by following Appendix .........................19 • Hydroponic growers view fish- certain principles: Bibliography on manured irrigation water as a Aquaponics ..............19 • The waste products of one biological source of organic fertilizer that Dissertations ............25 enables plants to grow well. system serve as nutrients for a sec- ond biological system. • Fish farmers view hydroponics as a biofiltration method to facilitate • The integration of fish and plants intensive recirculating aquaculture. results in a polyculture that ATTRA—National Sustainable Agriculture Information Service increases diversity and yields • Greenhouse growers view aquapon- is managed by the National Cen- ics as a way to introduce organic multiple products. ter for Appropriate Technology (NCAT) and is funded under a hydroponic produce into the market- grant from the United States • Water is re-used through biological place, since the only fertility input Department of Agriculture’s filtration and recirculation. Rural Business-Cooperative Ser- is fish feed and all of the nutrients vice. Visit the NCAT Web site • Local food production pro- pass through a biological process. (www.ncat.org/agri. html) for more informa- vides access to healthy foods and • Food-producing greenhouses— tion on our sustainable agriculture projects. ���� enhances the local economy. yielding two products from one production unit—are naturally Hydroponics: Hydroponics is the produc- appealing for niche marketing and tion of plants in a soilless medium whereby green labeling. all of the nutrients supplied to the crop are dissolved in water. Liquid hydroponic sys- • Aquaponics can enable the produc- tems employ the nutrient film technique tion of fresh vegetables and fish pro- (NFT), floating rafts, and noncirculating tein in arid regions and on water- water culture. Aggregate hydroponic sys- limited farms, since it is a water tems employ inert, organic, and mixed re-use system. media contained in bag, trough, trench, • Aquaponics is a working model of pipe, or bench setups. Aggregate media sustainable food production wherein used in these systems include perlite, ver- plant and animal agriculture are miculite, gravel, sand, expanded clay, peat, integrated and recycling of nutrients and sawdust. Normally, hydroponic plants and water filtration are linked. are fertigated (soluble fertilizers injected into irrigation water) on a periodical cycle • In addition to commercial appli- to maintain moist roots and provide a con- cation, aquaponics has become a stant supply of nutrients. These hydroponic popular training aid on integrated nutrients are usually derived from synthetic Related ATTRA bio-systems with vocational agri- Publications commercial fertilizers, such as calcium culture programs and high school nitrate, that are highly soluble in water. Evaluating an biology classes. However, hydro-organics—based on solu- Aquaculture The technology associated with aquapon- ble organic fertilizers such as fish hydrosyl- Enterprise ics is complex. It requires the ability to ate—is an emerging practice. Hydroponic Agricultural Business simultaneously manage the production recipes are based on chemical formula- Planning Templates and marketing of two different agricultural tions that deliver precise concentrations of and Resources products. Until the 1980s, most attempts mineral elements. The controlled deliv- at integrated hydroponics and aquacul- ery of nutrients, water, and environmen- ture had limited success. However, inno- tal modifications under greenhouse condi- vations since the 1980s have transformed tions is a major reason why hydroponics is aquaponics technology into a viable sys- so successful. tem of food production. Modern aquaponic Nutrients in Aquaculture Effluent: systems can be highly successful, but they Greenhouse growers normally control the require intensive management and they have delivery of precise quantities of mineral special considerations. elements to hydroponic plants. However, in aquaponics, nutrients are delivered via This publication provides an introduction to aquacultural effluent. Fish effluent contains aquaponics, it profiles successful aquaponic sufficient levels of ammonia, nitrate, nitrite, greenhouses, and it provides extensive phosphorus, potassium, and other second- resources. It does not attempt to describe ary and micronutrients to produce hydro- production methods in comprehensive tech- ponic plants. Naturally, some plant species nical detail, but it does provide a summary are better adapted to this system than oth- of key elements and considerations. ers. The technical literature on aquaponics provides greater detail on hydroponic nutri- Aquaponics: Key Elements ent delivery; especially see papers cited in and Considerations the Bibliography by James Rakocy, PhD. A successful aquaponics enterprise requires Plants Adapted to Aquaponics: The special training, skills, and management. selection of plant species adapted to hydro- The following items point to key elements ponic culture in aquaponic greenhouses and considerations to help prospective grow- is related to stocking density of fish tanks ers evaluate the integration of hydroponics and subsequent nutrient concentration of with aquaculture. aquacultural effluent. Lettuce, herbs, and Page 2 ATTRA AAqquuaappoonniiccss——IInntteeggrraattiioonn ooff HHyyddrrooppoonniiccss wwiitthh AAqquuaaccuullttuurree specialty greens (spinach, chives, basil, and products to forms more available to plants watercress) have low to medium nutritional prior to delivery to hydroponic vegetable requirements and are well adapted to aqua- beds. Other systems deliver fish effluent ponic systems. Plants yielding fruit (toma- directly to gravel-cultured hydroponic veg- toes, bell peppers, and cucumbers) have etable beds. The gravel functions as a “flu- a higher nutritional demand and perform idized bed bioreactor,” removing dissolved better in a heavily stocked, well established solids and providing habitat for nitrifying aquaponic system. Greenhouse varieties bacteria involved in nutrient conversions. of tomatoes are better adapted to low light, The design manuals and technical docu- high humidity conditions in greenhouses mentation available in the Resources sec- than field varieties. tion can help growers decide which system is most appropriate. Fish Species: Several warm-water and cold-water fish species are adapted to recir- Component Ratio: Matching the volume culating aquaculture systems, including of fish tank water to volume of hydroponic tilapia, trout, perch, Arctic char, and bass. media is known as component ratio. Early However, most commercial aquaponic sys- aquaponics systems were based on a ratio tems in North America are based on tila- of 1:1, but 1:2 is now common and tank: T ilapia is a pia. Tilapia is a warm-water species that bed ratios as high as 1:4 are employed. warm-water grows well in a recirculating tank culture. The variation in range depends on type of species that Furthermore, tilapia is tolerant of fluctuat- hydroponic system (gravel vs. raft), fish spe- ing water conditions such as pH, tempera- cies, fish density, feeding rate, plant spe- grows well in a recir- ture, oxygen, and dissolved solids. Tilapia cies, etc. For example, the Speraneo system culating tank cul- produces a white-fleshed meat suitable to described below is designed for one cubic ture. local and wholesale markets. The literature foot of water to two cubic feet of grow bed on tilapia contains extensive technical doc- media (pea gravel). Further, when shallow umentation and cultural procedures. Bar- bed systems only three inches in depth are ramundi and Murray cod fish species are employed for the production of specialty raised in recirculating aquaponic systems greens such as lettuce and basil, the square in Australia. footage of grow space will increase four times. Depending on the system design, the Water Quality Characteristics: Fish component ratio can favor greater outputs of raised in recirculating tank culture require either hydroponic produce or fish protein. good water quality conditions. Water qual- A “node” is a configuration that links one ity testing kits from aquacultural sup- fish tank to a certain number of hydroponic ply companies are fundamental. Critical beds. Thus, one greenhouse may contain water quality parameters include dissolved a multiple number of fish tanks and asso- oxygen, carbon dioxide, ammonia, nitrate, ciated growing beds, each arranged in a nitrite, pH, chlorine, and other character- separate node. istics. The stocking density of fish, growth rate of fish, feeding rate and volume, and related environmental fluctuations can elicit Male tilapia fish. AARM rapid changes in water quality; constant - Aquaculture & Aquatic and vigilant water quality monitoring Resources Management Asian Institute of is essential. Technology, Thailand. Biofiltration and Suspended Solids: www.aqua.ait.ac.th/ modules/xcgal/ Aquaculture effluent contains nutrients, dis- solved solids, and waste byproducts. Some Aquaponic Systems aquaponic systems are designed with inter- mediate filters and cartridges to collect sus- Profiles of several aquaponic greenhouses pended solids in fish effluent, and to facili- are highlighted below as models of com- tate conversion of ammonia and other waste mercially viable systems. Most of these www.attra.ncat.org ATTRA Page 3 operations are featured in magazine articles fish can bring premium prices, and conference proceedings. Some oper- particularly during winter months ations offer technical assistance through in urban areas. short courses, design manuals, and on-site • Biofilters (sand beds with vegeta- tours. Please refer to articles in the Sug- bles) that are alternately flooded gested Reading list, the Resources sec- and drained with nutrient-laden fish tion, and the Bibliography for in-depth tank water are called reciprocating descriptions and technical details. biofilters. • Reciprocating biofilters provide The North Carolina State uniform distribution of nutrient- University System laden water within the filtration In the 1980’s Mark McMurtry (former medium during the flood cycle, and improved aeration from atmospheric graduate student) and the late Doug Sand- exchange during each dewatering ers (professor) at North Carolina State Uni- with benefits to both nitrifying bac- versity developed an aqua-vegeculture sys- teria and plant roots. tem based on tilapia fish tanks sunk below Water con- the greenhouse floor. Effluent from the fish • Dissolved and suspended organic tanks was trickle-irrigated onto sand-cul- materials accumulate rapidly sump- tured hydroponic vegetable beds located at in aquaculture systems and must tion in ground level. The nutrients in the irrigation be removed for efficient fish an integrated aqua- water fed tomato and cucumber crops, and production. vegeculture system the sand beds and plant roots functioned as • Previous integrated fish-vegetable amounts to 1 per- a biofilter. After draining from the beds, systems removed suspended solids cent of that required the water recirculated back into the fish from the water by sedimentation in tanks. The only fertility input to the system in pond culture to clarifiers prior to plant application. was fish feed (32 percent protein). Removal of the solid wastes resulted produce equivalent in insufficient residual nutrients for tilapia yields. Some findings and highlights of good plant growth; acceptable fruit McMurtry’s research: yields had previously only been • Benefits of integrating aquaculture achieved with substantial supple- and vegetable production are: mentation of plant nutrients. 1. conservation of water resources • Aquaeous nitrate concentrations in and plant nutrients recirculating aquaculture can be 2. intensive production of fish adequately regulated when fish and protein vegetable production are linked via reciprocating biofilters. 3. reduced operating costs relative to either system in isolation. • Tomatoes may have also assimi- lated nitrogen in organic amino • Water consumption in an integrated acid forms. In 1950 Gosh and Bur- aqua-vegeculture system amounts to ris (Utilization of nitrogenous com- 1 percent of that required in pond pounds by plants. Soil Science. culture to produce equivalent tilapia Vol. 70: 187-203) found that toma- yields. toes utilize alanine, glutamic acid, • Such low-water-use symbiotic sys- histidine, and leucine as effectively tems are applicable to the needs as inorganic nitrogen sources. of arid or semi-arid regions where • Research to determine the optimum fish and fresh vegetables are in high ratio of fish tank to biofilter volume demand. on fish growth rate and water qual- • Organic vine-ripened, pesticide- ity found that stocking density of free produce and “fresh-daily” fish and plants can vary depending Page 4 ATTRA AAqquuaappoonniiccss——IInntteeggrraattiioonn ooff HHyyddrrooppoonniiccss wwiitthh AAqquuaaccuullttuurree on desired goal. The component tank-plus-hydroponic bed setup as a “node.” ratios of the system may be manipu- This way, each node can operate indepen- lated to favour fish or vegetable pro- dently of one another. duction according to local market Some aspects of the Speraneo system were trends or dietary needs. Fish stock- modeled after the aquaponics research at ing density and feeding rates are North Carolina State University, while oth- adjusted to optimize water quality ers are modified. The Speraneos employ as influenced by plant growth rate. hydroponic vegetable beds as “fluidized See the Bibliography on Aquaponics bed reactors,” but they use pea-grade river in the appendix for a of list articles that gravel instead of sand. Tilapia are raised resulted from the North Carolina research. in fish tanks, but the tanks are more con- veniently located above ground and tilapia Aqua-vegeculture research at NCSU has hybrids adapted to cooler water tempera- been discontinued because the technology tures are grown. The reciprocating water had evolved to the point where it is ready cycle, PVC piping, and return-flow water for grower application. The Department of pumping methods were designed by Tom Horticulture and the Cooperative Extension Service at NCSU provide technical assis- and Paula to match their system. T he Spera- tance to aquaponic greenhouse growers in For years, Purina® fish chow at 40 percent neo system North Carolina. protein was the primary fertility input, sup- was practi- plemented with tank-cultured algae. Tila- cal, productive, and The Speraneo System pia in the Speraneo system are raised for wildly successful. In the early 1990s, Tom and Paula Spe- 7 to 12 months, then harvested at one to raneo—owners of S & S Aqua Farm near one-and-a-half pounds in size. Later, Tom West Plains, Missouri—modified the North started adding small amounts of Planters Carolina State method by raising tilapia in 2® rock dust on top of the gravel as a trace a 500-gallon tank, with fish effluent linked element supplement. to gravel-cultured hydroponic vegetable S & S Aqua Farm has grown fresh basil, beds inside an attached solar greenhouse. tomatoes, cucumbers, mixed salad greens, Later, they expanded to a full-size commer- and an assortment of vegetable, herb, and cial greenhouse. The Speraneo system was ornamental bedding plants in the aqua- practical, productive, and wildly successful. ponic greenhouse. In the early 1990’s, It became the model for dozens of commer- Tom and Paula were raising and selling cial aquaponic greenhouses and high school basil for $12 a pound to gourmet restau- biology programs. rants about four hours away in St. Louis, Sadly, Tom Speraneo died in February Missouri. Following passage of the North 2004. Tom was a true pioneer in aqua- American Free Trade Agreement (NAFTA), ponics, and he was unfailingly generous however, Mexican imports of basil resulted and helpful to others. Paula Speraneo in a market crash to $4 per pound, so they and her family continue to run the green- dropped the St. Louis market. S & S Aqua house and actively participate in aqua- Farm now grows a diverse variety of vege- ponics technology transfer. The following table and herbs, selling locally at a farmers notes describe the Speraneo system and market combined with direct sales out of available resources. their greenhouse. The commercial-scale solar green- Tom once calculated the farm produces 45 house at S & S Aqua Farm is 50 feet by to 70 pounds of produce for every pound of 80 feet, oriented East-West to create a tilapia, an impressive yield. However, Paula south-facing slope. It contains six 1,200 explained this figure takes into account the gallon fish tanks. Each tank is linked to cummulative yields of multiple vegetable six one-foot-deep hydroponic beds filled crops raised during the 7 to 12 month time with river gravel. Tom referred to each period required to raise fish to harvest. www.attra.ncat.org ATTRA Page 5 Aquaponic greenhouse at S&S Aqua Farms, West Plains, Missouri. Photos by Steve Diver, NCAT. Page 6 ATTRA AAqquuaappoonniiccss——IInntteeggrraattiioonn ooff HHyyddrrooppoonniiccss wwiitthh AAqquuaaccuullttuurree The component ratio favors vegetables over rearing tanks, and the aquacultural efflu- fish yields in the Speraneo system. ent is linked to floating raft hydroponics. Basil, lettuce, okra, and other crops have Interest in the Speraneo system resulted been raised successfully, with outstanding in more than 10,000 visitors to the small quality and yields. farm in Missouri, including school children, farmers, researchers, and government offi- The system components include: Four fish cials. To handle requests for assistance, the rearing tanks at 7,800 liters each, clarifi- Speraneos compiled a resource packet and ers, filter and degassing tanks, air diffus- design manual with technical specifications ers, sump, base addition tank, pipes and to establish an S & S Aqua Farm-style aqua- pumps, and six 400-square foot hydroponic ponic system. The resource packet includes troughs totaling 2,400 sq. ft. The pH is a 10-minute video and a list of supplies. monitored daily and maintained at 7.0 to Response from growers to a practical design 7.5 by alternately adding calcium hydroxide manual such as this was tremendous. The and potassium hydroxide to the base addi- Speraneo system is now in use worldwide. tion tank, which buffers the aquatic system The resource packet, which sells for $250, and supplements calcium and potassium is available through: ions at the same time. The only other sup- J ames Rakocy, plemental nutrient required is iron, which S & S Aqua Farm PhD, and asso- is added in a chelated form once every [Contact: Paula Speraneo] ciates at the three weeks. 8386 County Rd. 8820 University of the West Plains, MO 65775 Tilapia are stocked at a rate of 77 fish per Virgin Islands (UVI) 417-256-5124 cubic meter for Nile tilapia, or 154 fish per developed a com- [email protected] cubic meter for red tilapia and cultured for www.townsqr.com/snsaqua/index.html 24 weeks. The production schedule is stag- mercial-scale aqua- gered so that one tank is harvested every ponic system that Especially see: six weeks. After harvest, the fish tank is has run continu- Maturing Marvel immediately restocked. The fish are fed ously for more than by Vern Modeland three times daily with a complete, floating five years. The Growing Edge, May-June 1998 fish pellet at 32 percent protein. Projected www.townsqr.com/snsaqua/0905ssaf.pdf annual fish production is 4.16 metric tons for Nile tilapia and 4.78 metric tons for The Genius of Simplicity red tilapia. by John Wesely Smith The Growing Edge, Winter 1993-94 In one notable experiment the UVI www.townsqr.com/snsaqua/0502ssaf.pdf researchers compared the yields of a leafy herb (basil) and a fruiting vegetable (okra) Bioponics—Revolution in Food Grow- grown in aquaponic vs field production sys- ing: Missouri Aquafarmer Discovers tems. Basil and okra were raised in raft Huge Benefits in Trace Elements hydroponics. Yields of aquaponic basil by David Yarrow were three times greater than field-grown, Remineralize the Earth, December 1997 while yields of aquaponic okra were 18 www.championtrees.org/topsoil/ times greater than field-grown. Based on bioponics.htm a market price in the U.S. Virgin Islands of $22 per kg for fresh basil with stems, The University of the Virgin researchers calculated gross income poten- Islands System tial. The aquaponic method would result in James Rakocy, PhD, and associates at the $515 per cubic meter per year or $110,210 University of the Virgin Islands (UVI) devel- per system per year. This compares to field- oped a commercial-scale aquaponic system produced basil at $172 per cubic meter that has run continuously for more than five per year or $36,808 per year for the same years. Nile and red tilapia are raised in fish production area. When fish sales www.attra.ncat.org ATTRA Page 7 are included, the aquaponic system ista6web/pdf/676.pdf yields $134,245. (1) PowerPoint presentation; 49 pages http://ag.arizona.edu/azaqua/ista/ista6/ Like McMurtry, researcher Rakocy sees ista6web/presentation/p676.pdf integrated water reuse systems as a viable solution to sustainable food production in Aquaponics: Integrated Technology developing countries and arid regions— for Fish and Vegetable Production in such as the Caribbean Islands—where fresh Recirculating Systems water is scarce. James Rakocy, University of the Virgin Islands To provide in-depth technical support, the USDA Ministerial Conference and Expo on UVI research team offers a week-long short Agricultural Science and Technology course on aquaponics each year at the UVI PowerPoint presentation; 69 slides agricultural experiment station. The UVI http://ffas.usda.gov/icd/stconf/session2/ short course is the premier educational session%202d/02-rakocy_j-2D%202nd_ training program available to farmers in the files/frame.htm world. In addition to aquaponics, UVI spe- cializes in greenwater tank culture, a recir- Like culating aquaculture system. The Freshwater Institute System McMurtry, The Freshwater Institute in Shepherdstown, Rakocy has published extensive research researcher West Virginia—a program of The Conser- reports and several Extension Service bul- Rakocy sees inte- letins on recirculating aquaculture and vation Fund, an environmental non-profit organization—specializes in aquaculture grated water reuse aquaponics. See the Bibliography in the research and education. Fresh spring water systems as a viable appendix for citations to articles and papers is an abundant resource in the Appala- by Rackocy. solution to sustain- chian region. However, protection of spring able food produc- Contact: water quality as it relates to aquaculture tion in develop- effluent is viewed as a vital component of James Rakocy, PhD ing countries and University of the Virgin Islands this technology. arid regions—such Agriculture Experiment Station For years, the institute has specialized in as the Caribbean RR 1, Box 10,000 cold-water recirculating aquaculture systems Kingshill, St. Croix Islands—where raising trout and arctic char. The institute U.S. Virgin Islands 00850-9781 fresh water is scarce. helps Appalachian farmers set up two types 340-692-4020 of aquaculture systems: (a) an indoor, high- [email protected] tech recirculating tank method and (b) an http://rps.uvi.edu/AES/Aquaculture/ outdoor, low-tech recirculating tank method. aqua.html Treatment of aquaculture effluent prior to http://rps.uvi.edu/AES/Aquaculture/ its return to the natural stream flow led aquaponics.html to collaborative research with USDA-ARS Especially see: scientists in Kearneysville, West Virginia, on integrated hydroponic-fish culture Update on Tilapia and Vegetable Pro- systems. Trials at the institute’s green- duction in the UVI Aquaponic System houses showed that nitrogen, phosphorus, James E. Rakocy, Donald S. Bailey, R. and other nutrients in aquaculture efflu- Charlie Shultz and Eric S. Thoman page ent can be effectively removed by plants 676-690. In: New Dimensions on Farmed grown in NFT hydroponics or constructed Tilapia: Proceedings of the Sixth Inter- wetland systems. national Symposium on Tilapia in Aqua- culture, Held September 12-16, 2004 in In the mid-1990s, the institute implemented Manila, Philippines. an aquaponic demonstration program based Proceedings paper: 15 pages on a Sperraneo-style gravel-cultured sys- http://ag.arizona.edu/azaqua/ista/ista6/ tem. Tilapia is raised as a warm-water fish Page 8 ATTRA AAqquuaappoonniiccss——IInntteeggrraattiioonn ooff HHyyddrrooppoonniiccss wwiitthh AAqquuaaccuullttuurree species. Hydroponic crops include basil, Cabbage Hill Farm designed and continues lettuce, and wetland plants. to operate a simple recirculating aquaponic system. Cabbage Hill Farm promotes edu- To provide technical assistance to farmers cation on aquaponics and hosts greenhouse and high school biology teachers, the insti- interns. Tours are available. tute published a series of publications on recirculating aquaculture and aquaponics. Tilapia fish and leaf lettuce are the main The Freshwater Institute Natural Gas Pow- products of the Cabbage Hill Farm system, ered Aquaponic System—Design Manual is a though basil and watercress are also grown 37-page manual published by the institute in smaller quantities. In addition to hydro- in 1997. Included are diagrams and pho- ponics, water passes through a constructed tos, details on greenhouse layout and aqua- reed bed outside the greenhouse for addi- ponic production, parts list with suppliers tional nutrient removal. and cost, estimated operating expense, and further informational resources. Aquaponics—Preserving the Future is a video film documenting the research and dem- Please note the institute no longer pro- onstration of aquaponics at Cabbage Hill vides direct technical assistance to farm- C Farms. The cost is $18. abbage Hill ers on aquaponics. Instead, it has made the aquaponics design manual and related Farm pro- Cabbage Hill Farm publications on recirculating aquaculture motes edu- 205 Crow Hill Road and aquaponics available as free cation on aqua- Mount Kisco, NY 10549 Web downloads. 914-241-2658 ponics and hosts The Freshwater Institute 914-241-8264 FAX greenhouse interns. Shepherdstown, WV www.cabbagehillfarm.org www.freshwaterinstitute.org The New Alchemy Institute Selected Web Publications from The Freshwater Institute The New Alchemy Institute in East Fal- mouth, Massachusetts, conducted research • Suggested Management Guidelines on integrated aquaculture systems during for An Integrated Recycle Aquacul- the 1970s and 1980s. Although the insti- ture – Hydroponic System tute closed in 1991, New Alchemy pub- • The Freshwater Institute Natural lications on greenhouse production and Gas Powered Aquaponic System - aquaponics provide historical insight to Design Manual the emerging bioshelter (ecosystem green- • 880 Gallon Recycle Aquaculture houses) concept and are still a valuable System Installation Guide resource for technical information. The • Linking Hydroponics to a 880 Gal- Green Center, formed by a group of for- lon Recycle Fish Rearing System mer New Alchemists, is again making these • Operators Manual for 880 - Recycle publications available for sale. The Web System site has a section featuring for-sale articles on aquaculture and bioshelters (integrated The Cabbage Hill Farm System systems). A selection of past articles is available online. Cabbage Hill Farm is a non-profit organi- zation located about 30 miles north of New Contact: York City. The foundation is dedicated to the preservation of rare breeds of farm The Green Center animals, sustainable agriculture and 237 Hatchville Rd. local food systems, and aquaponic East Falmouth, MA 02536 greenhouse production. www.vsb.cape.com/~nature/greencenter/ www.attra.ncat.org ATTRA Page 9 Backyard Aquaponics in Western Australia. Photos by Joel Malcolm, Backyard Aquaponics. (with permission) www.backyard aquaponics.com Page 10 ATTRA AAqquuaappoonniiccss——IInntteeggrraattiioonn ooff HHyyddrrooppoonniiccss wwiitthh AAqquuaaccuullttuurree

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Aquaponic vegetable bed in Australia. Photo by Joel Malcolm, Backyard Aquaponics. www.backyardaquaponics.com. (with permission). Introduction.
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