Farming

Aquaponics—Integration of Hydroponics with Aquaculture
A Publication of ATTRA—National Sustainable Agriculture Information Service • 1-800-346-9140 • www.attra.ncat.org By Steve Diver NCAT Agriculture Specialist Published 2006 Updated by Lee Rinehart, NCAT Agriculture Specialist © 2010 NCAT Aquaponics is a bio-integrated system that links recirculating aquaculture with hydroponic vegetable, flower, and/or herb production. Recent advances by researchers and growers alike have turned aquaponics into a working model of sustainable food production. This publication provides an introduction to aquaponics with brief profiles of working units around the country. An extensive list of resources points the reader to print and Web-based educational materials for further technical assistance.

Introduction
Contents
Introduction ..................... 1 Aquaponics: Key Elements and Considerations ............... 2 Aquaponic Systems ...... 3 Organic Aquaculture .................. 11 Evaluating an Aquaponic Enterprise ........................ 12 References ...................... 13 Resources ....................... 13 Appendix I: Bibliography on Aquaponics ............. 20 Appendix II: Dissertations ................. 25

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quaponics, also known as the integration of hydroponics with aquaculture, is gaining increased attention as a bio-integrated food production system. Aquaponics serves as a model of sustainable food production by fol low ing certain principles: • The waste products of one biological system serve as nutrients for a second biological system. • The integration of fish and plants results in a polyculture that increases diversity and yields multiple products. • Water is re-used through biological ﬁltration and recirculation. • Local food production provides access to healthy foods and enhances the local economy. In aquaponics, nutrient-rich eﬄuent from ﬁsh tanks is used to fertigate hydroponic production beds. Th is is good for the ﬁsh because plant roots and rhizobacteria remove nutrients from the water. These nutrients – generated from ﬁsh manure, algae, and decomposing ﬁsh feed – are contaminants that would otherwise build up to toxic levels in the ﬁsh tanks, but instead serve as liquid fertilizer to hydroponically grown plants. In turn, the hydroponic beds function as a bioﬁlter – stripping oﬀ ammonia, nitrates, nitrites, and phosphorus – so the freshly cleansed water can then be recirculated back
Aquaponic vegetable bed in Australia. Photo by Joel Malcolm, Backyard Aquaponics. www.backyardaquaponics.com

into the ﬁsh tanks. The nitrifying bacteria living in the gravel and in association with the plant roots play a critical role in nutrient cycling; without these microorganisms the whole system would stop functioning. Greenhouse growers and farmers are taking note of aquaponics for several reasons: • Hydroponic growers view fishmanured irrigation water as a source of organic fertilizer that enables plants to grow well. • Fish farmers view hydroponics as a bioﬁ ltration method to facilitate intensive recirculating aquaculture. • Greenhouse growers view aquaponics as a way to introduce organic hydroponic produce into the marketplace, since the only fertility input is ﬁsh feed and all of the nutrients pass through a biological process.

ATTRA—National Sustainable Agriculture Information Service (www.attra.ncat.org) is managed by the National Center for Appropriate Technology (NCAT) and is funded under a grant from the United States Department of Agriculture’s Rural BusinessCooperative Service. Visit the NCAT website (www.ncat.org/ sarc_current.php) for more information on our sustainable agriculture projects.

Related ATTRA Publications
Aquaculture Enterprises: Considerations and Strategies Agricultural Business Planning Templates and Resources

• Food-producing greenhouses – yielding two products from one production unit – are naturally appealing for niche marketing and green labeling. • Aquaponics can enable the production of fresh vegetables and ﬁsh protein in arid regions and on waterlimited farms, since it is a water re-use system. • Aquaponics is a working model of sustainable food production wherein plant and animal agriculture are integrated and recycling of nutrients and water ﬁltration are linked. • In addition to commercial application, aquaponics has become a popular training aid on integrated bio-systems with vocational agriculture programs and high school biology classes. The technology associated with aquaponics is complex. It requires the ability to simultaneously manage the production and marketing of two diﬀerent agricultural products. Until the 1980s, most attempts at integrated hydroponics and aquaculture had limited success. However, innovations since the 1980s have transformed aquaponics technology into a viable system of food production. Modern aquaponic systems can be highly successful, but they require intensive management and they have special considerations. This publication provides an introduction to aquaponics, it proﬁ les successful aquaponic greenhouses, and it provides extensive resources. It does not attempt to describe production methods in comprehensive technical detail, but it does provide a summary of key elements and considerations.

all of the nutrients supplied to the crop are dissolved in water. Liquid hydroponic systems employ the nutrient film technique (NFT), f loating rafts, and noncirculating water culture. Aggregate hydroponic systems employ inert, organic, and mixed media contained in bag, trough, trench, pipe, or bench setups. Aggregate media used in these systems include perlite, vermiculite, gravel, sand, expanded clay, peat, and sawdust. Normally, hydroponic plants are fertigated (soluble fertilizers injected into irrigation water) on a periodical cycle to maintain moist roots and provide a constant supply of nutrients. These hydroponic nutrients are usually derived from synthetic commercial fertilizers, such as calcium nitrate, that are highly soluble in water. However, hydroorganics – based on soluble organic fertilizers such as ﬁsh hydrosylate – is an emerging practice. Hydroponic recipes are based on chemical formulations that deliver precise concentrations of mineral elements. The controlled delivery of nutrients, water, and environmental modiﬁcations under greenhouse conditions is a major reason why hydroponics is so successful. Nutrients in Aquaculture Eﬄuent: Greenhouse growers normally control the delivery of precise quantities of mineral elements to hydroponic plants. However, in aquaponics, nutrients are delivered via aquacultural eﬄuent. Fish eﬄuent contains suﬃcient levels of ammonia, nitrate, nitrite, phosphorus, potassium, and other secondary and micronutrients to produce hydroponic plants. Naturally, some plant species are better adapted to this system than others. The technical literature on aquaponics provides greater detail on hydroponic nutrient delivery; especially see papers cited in the Bibliography by James Rakocy, Ph.D. Plants Adapted to Aquaponics: The selection of plant species adapted to hydroponic culture in aquaponic greenhouses is related to stocking density of ﬁsh tanks and subsequent nutrient concentration of aquacultural eﬄuent. Lettuce, herbs, and specialty greens (spinach, chives, basil, and watercress) have low to medium nutritional requirements and are well adapted to aquaponic systems.

Aquaponics: Key Elements and Considerations
A successful aquaponics enterprise requires special training, skills, and management. The following items point to key elements and considerations to help prospective growers evaluate the integration of hydroponics with aquaculture. Hydroponics: Hydroponics is the production of plants in a soilless medium whereby
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Plants yielding fruit (tomatoes, bell peppers, and cucumbers) have a higher nutritional demand and perform better in a heavily stocked, well established aquaponic system. Greenhouse varieties of tomatoes are better adapted to low light, high humidity conditions in greenhouses than ﬁeld varieties. Fish Species: Several warm-water and coldwater ﬁsh species are adapted to recirculating aquaculture systems, including tilapia, trout, perch, Arctic char, and bass. However, most commercial aquaponic systems in North America are based on tilapia. Tilapia is a warm-water species that grows well in a recirculating tank culture. Furthermore, tilapia is tolerant of ﬂuctuating water conditions such as pH, temperature, oxygen, and dissolved solids. Tilapia produces a whiteﬂeshed meat suitable to local and wholesale markets. The literature on tilapia contains extensive technical documentation and cultural procedures. Barramundi and Murray cod ﬁsh species are raised in recirculating aquaponic systems in Australia. Water Quality Characteristics: Fish raised in recirculating tank culture require good water quality conditions. Water quality testing kits from aquacultural supply companies are fundamental. Critical water quality parameters include dissolved oxygen, carbon dioxide, ammonia, nitrate, nitrite, pH, chlorine, and other characteristics. The stocking density of ﬁsh, growth rate of ﬁsh, feeding rate and volume, and related environmental ﬂuctuations can elicit rapid changes in water quality; constant and vigilant water quality monitoring is essential. Bioﬁltration and Suspended Solids: Aquaculture eﬄuent contains nutrients, dissolved solids, and waste byproducts. Some aquaponic systems are designed with intermediate ﬁlters and cartridges to collect suspended solids in ﬁsh eﬄuent, and to facilitate conversion of ammonia and other waste products to forms more available to plants prior to delivery to hydroponic vegetable beds. Other systems deliver ﬁsh eﬄuent directly to gravel-cultured hydroponic vegetable beds. The gravel functions as a “ﬂuidized bed bioreactor,” removing dissolved solids and providing habitat for www.attra.ncat.org nitrifying bacteria involved in nutrient conversions. The design manuals and technical documentation available in the Resources section can help growers decide which system is most appropriate. Component Ratio: Matching the volume of ﬁsh tank water to volume of hydroponic media is known as component ratio. Early aquaponics systems were based on a ratio of 1:1, but 1:2 is now common and tank: bed ratios as high as 1:4 are employed. The variation in range depends on type of hydroponic system (gravel vs. raft), ﬁsh species, ﬁsh density, feeding rate, plant species, etc. For example, the Speraneo system described below is designed for one cubic foot of water to two cubic feet of grow bed media (pea gravel). Further, when shallow bed systems only three inches in depth are employed for the production of specialty greens such as lettuce and basil, the square footage of grow space will increase four times. Depending on the system design, the component ratio can favor greater outputs of either hydroponic produce or ﬁsh protein. A “node” is a conﬁguration that links one ﬁsh tank to a certain number of hydroponic beds. Thus, one greenhouse may contain a multiple number of ﬁsh tanks and associated growing beds, each arranged in a separate node.

ilapia is a warm-water species that grows well in a recirculating tank culture.

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Aquaponic Systems
Proﬁles of several aquaponic greenhouses are highlighted below as models of commercially viable systems. Most of these operations are featured in magazine articles and conference proceedings. Some operations oﬀer technical assistance through short courses, design manuals, and on-site tours. Please refer to articles in the Resources section, and the Bibliography, for in-depth descriptions and technical details.

The North Carolina State University System
Water consumption in an integrated aquavegeculture system amounts to 1 percent of that required in pond culture to produce equivalent tilapia yields. In the 1980s Mark McMurtry (former graduate student) ATTRA
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and the late Doug Sanders (professor) at North Carolina State University developed an aqua-vegeculture system based on tilapia ﬁsh tanks sunk below the greenhouse ﬂoor. Eﬄuent from the ﬁsh tanks was trickle-irrigated onto sand-cultured hydroponic vegetable beds located at ground level. The nutrients in the irrigation water fed tomato and cucumber crops, and the sand beds and plant roots functioned as a bioﬁ lter. After draining from the beds, the water recirculated back into the ﬁsh tanks. The only fertility input to the system was ﬁsh feed (32 percent protein). Some f i nd ing s a nd h ig h l ig ht s of McMurtry’s research:

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ioﬁlters (sand beds with vegetables) that are alternately ﬂooded and drained with nutrient-laden ﬁsh tank water are called reciprocating bioﬁlters.

• Beneﬁts of integrating aquaculture and vegetable production are: 1. conservation of water resources and plant nutrients 2. intensive production of ﬁsh protein 3. reduced operating costs relative to either system in isolation. • Water consumption in an integrated aqua-vegeculture system amounts to 1 percent of that required in pond culture to produce equivalent tilapia yields. • Such low-water-use symbiotic systems are applicable to the needs of arid or semi-arid regions where fish and fresh vegetables are in high demand. • Organic vine-ripened, pesticide-free produce and “fresh-daily” fish can bring premium prices, particularly during winter months in urban areas. • Bioﬁlters (sand beds with vegetables) that are alternately ﬂooded and drained with nutrient-laden ﬁsh tank water are called reciprocating bioﬁlters. • Reciprocating biofilters provide uniform distribution of nutrientladen water within the filtration medium during the ﬂood cycle, and improved aeration from atmospheric exchange during each dewatering

with benefits to both nitrifying bacteria and plant roots. • Dissolved and suspended organic materials accumulate rapidly in aquaculture systems and must be removed for eﬃcient ﬁsh production. • Previous integrated fish-vegetable systems removed suspended solids from the water by sedimentation in clariﬁers prior to plant application. Removal of the solid wastes resulted in insuﬃcient residual nutrients for good plant growth; acceptable fruit yields had previously only been achieved with substantial supplementation of plant nutrients. • Aqueous nitrate concentrations in recirculating aquaculture can be adequately regulated when ﬁsh and vegetable production are linked via reciprocating bioﬁlters. • Tomatoes may have also assimilated nitrogen in organic amino acid forms. In 1950 Gosh and Burris (Utilization of Nitrogenous Compounds by Plants. Soil Science. Vol. 70: 187-203) found that tomatoes utilize alanine, glutamic acid, histidine, and leucine as eﬀectively as inorganic nitrogen sources. • Research to determine the optimum ratio of ﬁsh tank to bioﬁlter volume on ﬁsh growth rate and water quality found that stocking density of ﬁsh and plants can vary depending on desired goal. The component ratios of the system may be manipulated to favor ﬁsh or vegetable production according to local market trends or dietary needs. Fish stocking density and feeding rates are adjusted to optimize water quality as inﬂuenced by plant growth rate. See the Bibliography on Aquaponics in the appendix for a of list articles that resulted from the North Carolina research. Aqua-vegeculture research at NCSU has been discontinued because the technology had evolved to the point where it is ready

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for grower application. The Department of Horticulture and the Cooperative Extension Service at NCSU provide technical assistance to aquaponic greenhouse growers in North Carolina.

methods were designed by Tom and Paula to match their system. For years, Purina® ﬁsh chow at 40 percent protein was the primary fertility input, supplemented with tank-cultured algae. Tilapia in the Speraneo system are raised for 7 to 12 months, then harvested at one to one-and-ahalf pounds in size. Later, Tom started adding small amounts of Planters 2® rock dust on top of the gravel as a trace element supplement. S & S Aqua Farm has grown fresh basil, tomatoes, cucumbers, mixed salad greens, and an assortment of vegetable, herb, and ornamental bedding plants in the aquaponic greenhouse. In the early 1990s, Tom and Paula were raising and selling basil for $12 a pound to gourmet restaurants about four hours away in St. Louis, Missouri. Following passage of the North American Free Trade Agreement (NAFTA), however, Mexican imports of basil resulted in a market crash to $4 per pound, so they dropped the St. Louis market. S & S Aqua Farm now grows a diverse variety of vegetable and herbs, selling locally at a farmers market combined with direct sales out of their greenhouse. Tom once calculated the farm produces 45 to 70 pounds of produce for every pound of tilapia, an impressive yield. However, Paula explained this ﬁgure takes into account the cumulative yields of multiple vegetable crops raised during the 7- to 12-month time period required to raise ﬁsh to harvest. The component ratio favors vegetables over ﬁsh yields in the Speraneo system. Interest in the Speraneo system resulted in more than 10,000 visitors to the small farm in Missouri, including school children, farmers, researchers, and government oﬃcials. To handle requests for assistance, the Speraneos compiled a resource packet and design manual with technical speciﬁcations to establish an S & S Aqua Farm-style aquaponic system. The resource packet includes a 10-minute video and a list of supplies. Response from growers to a practical design manual such as this was tremendous. The Speraneo system is now in use worldwide. The resource packet is available through: ATTRA
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The Speraneo System
In the early 1990s, Tom and Paula Speraneo – owners of S & S Aqua Farm near West Plains, Missouri – modiﬁed the North Carolina State method by raising tilapia in a 500-gallon tank, with ﬁsh eﬄuent linked to gravel-cultured hydroponic vegetable beds inside an attached solar greenhouse. Later, they expanded to a full-size commercial greenhouse. The Speraneo system was practical, productive, and wildly successful. It became the model for dozens of commercial aquaponic greenhouses and high school biology programs. Sadly, Tom Speraneo died in February 2004. Tom was a true pioneer in aquaponics, and he was unfailingly generous and helpful to others. Paula Speraneo and her family continue to run the greenhouse and actively participate in aquaponics technology transfer. The following notes describe the Speraneo system and available resources. The commercial-scale solar greenhouse at S & S Aqua Farm is 50 feet by 80 feet, oriented East-West to create a south-facing slope. It contains six 1,200 gallon ﬁsh tanks. Each tank is linked to six one-foot-deep hydroponic beds ﬁlled with river gravel. Tom referred to each tank-plus-hydroponic bed setup as a “node.” This way, each node can operate independently of one another. Some aspects of the Speraneo system were modeled after the aquaponics research at North Carolina State University, while others are modified. The Speraneos employ hydroponic vegetable beds as “ﬂuidized bed reactors,” but they use pea-grade river gravel instead of sand. Tilapia are raised in ﬁsh tanks, but the tanks are more conveniently located above ground and tilapia hybrids adapted to cooler water temperatures are grown. The reciprocating water cycle, PVC piping, and return-flow water pumping www.attra.ncat.org Aquaponic greenhouse at S & S Aqua Farms, West Plains, Missouri. Photos by Steve Diver, NCAT.

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S & S A qua F arm [Contact: Paula Speraneo] 8386 County Rd. 8820 West Plains, MO 65775 417-256-5124 Especially see: Maturing Marvel (PDF/282K) by Vern Modeland, The Growing Edge, May-June 1998, www.growingedge.com/magazine/back_ issues/view_article.php3?AID=90535> The Genius of Simplicity (PDF/30K) by John Wesley Smith, The Growing Edge, Winter 1993-94, www.growingedge. com/magazine/back_issues/view_article. php3?AID=50240 Bioponics – Revolution in Food Growing: Missouri Aquafarmer Discovers Huge Beneﬁts in Trace Elements by David Yarrow Remineralize the Earth, December 1997.

Tilapia are stocked at a rate of 77 ﬁsh per cubic meter for Nile tilapia, or 154 ﬁsh per cubic meter for red tilapia and cultured for 24 weeks. The production schedule is staggered so that one tank is harvested every six weeks. After harvest, the ﬁsh tank is immediately restocked. The ﬁsh are fed three times daily with a complete, ﬂoating ﬁsh pellet at 32 percent protein. Projected annual ﬁsh production is 4.16 metric tons for Nile tilapia and 4.78 metric tons for red tilapia. In one notable experiment the UVI researchers compared the yields of a leafy herb (basil) and a fruiting vegetable (okra) grown in aquaponic vs. ﬁeld production systems. Basil and okra were raised in raft hydroponics. Yields of aquaponic basil were three times greater than ﬁeld-grown, while yields of aquaponic okra were 18 times greater than ﬁeld-grown. Based on a market price in the U.S. Virgin Islands of $22 per kg for fresh basil with stems, researchers calculated gross income potential. The aquaponic method would result in $515 per cubic meter per year or $110,210 per system per year. Th is compares to ﬁeld-produced basil at $172 per cubic meter per year or $36,808 per year for the same production area. When ﬁsh sales are included, the aquaponic system yields $134,245 (Rakocy, et al, 2004). Like McMurtry, researcher Rakocy sees integrated water reuse systems as a viable solution to sustainable food production in developing countries and arid regions – such as the Caribbean Islands – where fresh water is scarce. To provide in-depth technical support, the UVI research team oﬀers a week-long short course on aquaponics each year at the UVI agricultural experiment station. The UVI short course is the premier educational training program available to farmers in the world. In addition to aquaponics, UVI specializes in greenwater tank culture, a recirculating aquaculture system. Rakocy has published extensive research reports and several Extension Service bulletins on recirculating aquaculture and aquaponics.

the University of the Virgin Islands (UVI) developed a commercial-scale aquaponic system that has run continuously for more than ﬁve years.

J

ames Rakocy, Ph.D., and associates at

The University of the Virgin Islands System
James Rakocy, Ph.D., and associates at the University of the Virgin Islands (UVI) developed a commercial-scale aquaponic system that has run continuously for more than ﬁve years. Nile and red tilapia are raised in ﬁsh rearing tanks, and the aquacultural eﬄuent is linked to ﬂoating raft hydroponics. Basil, lettuce, okra, and other crops have been raised successfully, with outstanding quality and yields. The system components include: Four ﬁsh rearing tanks at 7,800 liters each, clariﬁers, ﬁlter and degassing tanks, air diﬀusers, sump, base addition tank, pipes and pumps, and six 400-square foot hydroponic troughs totaling 2,400 sq. ft. The pH is monitored daily and maintained at 7.0 to 7.5 by alternately adding calcium hydroxide and potassium hydroxide to the base addition tank, which buﬀers the aquatic system and supplements calcium and potassium ions at the same time. The only other supplemental nutrient required is iron, which is added in a chelated form once every three weeks.

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See the Bibliography in the appendix for citations to articles and papers by Rakocy. Contact: James Rakocy, Ph.D. University of the Virgin Islands Agriculture Experiment Station RR 1, Box 10,000 Kingshill, St. Croix U.S. Virgin Islands 00850-9781 340-692-4031 (340) 692-4035 FAX jrakocy@uvi.edu Aquaculture Program www.uvi.edu/sites/uvi/Pages/ AES-Aquaculture-Home.aspx?s=RE rials at the Freshwater Institute’s greenhouses showed that nitrogen, phosphorus, and other nutrients in aquaculture eﬄuent can be eﬀectively removed by plants grown in NFT hydroponics or constructed wetland systems.

organization – specializes in aquaculture research and education. Fresh spring water is an abundant resource in the Appalachian region. However, protection of spring water quality as it relates to aquaculture eﬄuent is viewed as a vital component of this technology. For years, the institute has specialized in cold-water recirculating aquaculture systems raising trout and arctic char. The institute helps Appalachian farmers set up two types of aquaculture systems: (a) an indoor, hightech recirculating tank method and (b) an outdoor, low-tech recirculating tank method. Treatment of aquaculture eﬄuent prior to its return to the natural stream ﬂow led to collaborative research with USDA-ARS scientists in Kearneysville, West Virginia, on integrated hydroponic-ﬁsh culture systems. Trials at the institute’s greenhouses showed that nitrogen, phosphorus, and other nutrients in aquaculture eﬄuent can be eﬀectively removed by plants grown in NFT hydroponics or constructed wetland systems. In the mid-1990s, the institute implemented an aquaponic demonstration program based on a Speraneo-style gravel-cultured system. Tilapia is raised as a warm-water ﬁsh species. Hydroponic crops include basil, lettuce, and wetland plants. To provide technical assistance to farmers and high school biology teachers, the institute published a series of publications on recirculating aquaculture and aquaponics. The Freshwater Institute Natural Gas Powered Aquaponic System – Design Manual is a 37page manual published by the institute in 1997. Included are diagrams and photos, details on greenhouse layout and aquaponic production, parts list with suppliers and cost, estimated operating expense, and further informational resources. Please note the institute no longer provides direct technical assistance to farmers on aquaponics. Instead, it has made some of their publications on recirculating aquaculture and aquaponics available online. Contact The Freshwater Institute for information on obtaining design manuals and other publications not available as Web downloads.

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Aquaponics www.uvi.edu/sites/uvi/Pages/ AES-Aquaculture-Aquaponic_Systems. aspx?s=RE Especially see: Update on Tilapia and Vegetable Production in the UVI Aquaponic System James E. Rakocy, Donald S. Bailey, R. Charlie Shultz and Eric S. Thoman. Page 676690. In: New Dimensions on Farmed Tilapia: Proceedings of the Sixth International Symposium on Tilapia in Aquaculture, held September 12-16, 2004 in Manila, Philippines. Proceedings paper: 15 pages (PDF/254 K) http://ag.arizona.edu/azaqua/ista/ista6/ ista6web/pdf/676.pdf, PDF Presentation: 49 pages (PDF/1.47 MB) http://ag.arizona. edu/azaqua/ista/ista6/ista6web/presentation/ p676.pdf Aquaponics: Integrated Technology for Fish and Vegetable Production in Recirculating Systems, James Rakocy, University of the Virgin Islands USDA Ministerial Conference and Expo on Agricultural Science and Technology. PowerPoint Presentation; 69 slides, www.fas.usda.gov/icd/stconf/session2/ session%202d/02-rakocy_j-2D%202nd_ﬁles/ frame.htm

The Freshwater Institute System
The Freshwater Institute in Shepherdstown, West Virginia – a program of The Conservation Fund, an environmental non-proﬁt
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The Freshwater Institute 1098 Turner Road Shepherdstown, WV 25443-4228 Phone (304) 876-2815 www.freshwaterinstitute.org Selected Publications from The Freshwater Institute: • Suggested Management Guidelines for An Integrated Recycle Aquaculture – Hydroponic System • The Freshwater Institute Natural Gas Powered Aquaponic System – Design Manual • 880 Gallon Recycle Aquaculture System Installation Guide • Linking Hydroponics to a 880 Gallon Recycle Fish Rearing System • Operators Manua l for 880 – Recycle System

The New Alchemy Institute
The New Alchemy Institute in East Falmouth, Massachusetts, conducted research on integrated aquaculture systems during the 1970s and 1980s. Although the institute closed in 1991, New Alchemy publications on greenhouse production and aquaponics provide historical insight to the emerging bioshelter (ecosystem greenhouses) concept and are still a valuable resource for technical information. The Green Center, formed by a group of former New Alchemists, is again making these publications available for sale. The website has a section featuring for-sale articles on aquaculture and bioshelters (integrated systems). A selection of past articles is available online. Contact: The Green Center 28 Common Way, Hatchville, MA 02536 www.thegreencenter.net Especially see: An Integrated Fish Culture Hydroponic Vegetable Production System (PDF/6.57 MB) by Ronald D. Zweig, Aquaculture Magazine, May-June 1986. www.thegreencenter.net Listed under the heading: New Alchemy Institute Publications Online Summary of Fish Culture Techniques in Solar Aquatic Ponds (PDF/815K) by John Wolfe and Ron Zweig. Journal of The New Alchemists, 1977. www.thegreencenter.net Listed under the heading: New Alchemy Institute Publications Online n warm climates, hydroponic vegetable beds may be located outside.

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The Cabbage Hill Farm System
Cabbage Hill Farm is a non-proﬁt organization located about 30 miles north of New York City. The foundation is dedicated to the preservation of rare breeds of farm animals, sustainable agriculture and local food systems, and aquaponic greenhouse production. Cabbage Hill Farm designed and continues to operate a simple recirculating aquaponic system. Cabbage Hill Farm promotes education on aquaponics and hosts greenhouse interns. Tours are available. Tilapia ﬁsh and leaf lettuce are the main products of the Cabbage Hill Farm system, though basil and watercress are also grown in smaller quantities. In addition to hydroponics, water passes through a constructed reed bed outside the greenhouse for additional nutrient removal. Cabbage Hill Farm 115 Crow Hill Road Mount Kisco, NY 10549 914-241-2658 914-241-8264 FAX www.cabbagehillfarm.org www.attra.ncat.org Miscellaneous Systems
Instead of locating the ﬁsh and vegetable components in separate containers inside a greenhouse, ﬁsh production can be located in outdoor tanks or adjacent buildings. The eﬄuent simply needs to be delivered to hydroponic vegetable beds. In warm climates, hydroponic vegetable beds may be located outside. As an example, the Center for Regenerative Studies at California State Polytechnic University - Pomona implemented an outdoor integrated bio-system that links: (a) a pond containing treated sewage wastewater stocked with tilapia and carp; (b) water hyacinth – an aquatic plant ATTRA
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Backyard Aquaponics in Western Australia. Photos by Joel Malcolm, Backyard Aquaponics. (with permission) www.backyard aquaponics.com

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very eﬃcient at sucking up nutrients – covering 50 percent of the water surface area; the plant biomass generated by water hyacinth is used as feedstock for compost heaps; (c) nearby vegetable gardens irrigated with nutrient-laden pond water. In addition to locating the ﬁsh and vegetable components in separate containers, ﬁsh and plants can be placed in the same container to function as a polyculture. For example, plants sit on top of ﬂoating polystyrene panels with their roots hanging down into the water that fish swim around in. Models include the Rakocy system, solar-algae ponds (see literature by Zweig and Kleinholz), and the solar-aquatic ponds, or Living Machines, made popular by John Todd at Ocean Arks International. In Australia, barramundi (Lates calcarifer) and Murray cod (Maccullochella peelii peelii) ﬁsh species have been adapted to recirculating aquaculture and aquaponics systems. The stocking densities for these ﬁsh species is higher than tilapia, which in turn results in greater hydroponic surface under production. Several references are provided on these ﬁsh species and aquaponic systems in the Resources and Bibliography sections.

(for more information see The IFOAM Norms for Organic Production and Processing, Version 2005 and updated in 2009 at www. ifoam.org/about_ifoam/standards/norms/ norm_documents_library/Norms_ENG_V4_ 20090113.pdf ). However, organic aquaculture was not clearly deﬁned in the NOP and the lack of organic aquaculture guidelines has hampered the growth of a domestic organic aquaculture industry in the United States. The ATTRA publication Aquaculture Enterprises: Considerations and Strategies contains a section on organic aquaculture. It states that accredited organic certifying agencies can certify organic aquaculture operations, but the products are not allowed to carry the USDA organic label. In fact, Quality Certiﬁcation Services in Florida has certiﬁed three organic aquaculture operations in the U.S. and abroad under a private label. AquaRanch (www.aquaranch. com/index.html) an aquaponic greenhouse in Illinois, set a precedent for the aquaponics industry by obtaining organic certiﬁcation for its hydroponic produce through Indiana Certiﬁed Organic. Meanwhile, AquaRanch markets its greenhouse-raised tilapia as “naturally grown.” To address the issue of organic aquaculture, the National Organic Standards Board (NOSB) established an Aquatic Animals Task Force in June 2000. In 2003, a second group – The National Organic Aquaculture Working Group (NOAWG), comprised of 80 aquaculture professionals and related stakeholders – formed to provide further guidance and clarification to the NOSB. The interim ﬁnal report published by NOAWG in January 2006 provides proposed recommendations on organic aquaculture to NOSB, accessible at www.ams.usda. gov/AMSv1.0/getﬁle?dDocName=STELPRD C5062436&acct=nopgeninfo. To provide access to the large volume of documents, reports, and organic production standards surrounding the issue of organic aquaculture, the National Agricultural Library published an 80-page bibliography, Organic Aquaculture, through the Alternative Farming Systems Information Center. ATTRA
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rganic certifying agencies can certify organic aquaculture operations, but the products are not allowed to carry the USDA organic label.

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Organic Aquaculture
Organic production of crops and livestock in the United States is regulated by the Department of Agriculture’s National Organic Program, or NOP. The NOP is an organic certiﬁcation and marketing program that ensures foods and food products labeled as “organic” meet universal standards and guidelines for organic production. Production inputs used in organic production – such as feed and fertilizers – must be of natural origin and free of synthetic materials. A farm plan, documentation of inputs and production methods, and farm inspection are required to obtain “certiﬁed organic” status. This process allows farm products to be labeled and sold as organic. Organic trout, tilapia, salmon and other ﬁsh species are raised in Europe, Australia, and Israel using production standards developed by international organic certiﬁcation agencies www.attra.ncat.org Organic Aquaculture: AFSIC Notes #5 by Stephanie Boehmer, Mary Gold, Stephanie Hauser, Bill Thomas, and Ann Young. Alternative Farming Systems Information Center, National Agricultural Library, USDA. www.nal.usda.gov/afsic/AFSIC_pubs/ afnotes5.htm

Evaluating an Aquaponic Enterprise
Due to the highly technical nature of aquaponics and the expense associated with greenhouse production, prospective growers are advised to thoroughly investigate production methods and market potential.

with compost-based potting mixes – is a simple and productive way to get started in greenhouse vegetable production. You may quickly ﬁnd that your biggest challenge is weekly marketing of fresh produce rather than successful production of vegetables. This includes labor to harvest vegetables, grading and packing with brand name labels, post-harvest handling methods to maintain superior quality, and quick delivery of perishable produce to established markets. 3. Read technical and popular literature on recirculating aquaculture and aquaponics to become familiar with production methods, yields, and market prices for fresh ﬁsh and hydroponic vegetables. The Web Resources listed below provide quick access to reading material, diagrams and images, and related details. The Bibliography in the appendix provides access to in-depth research and technical data. 4. Visit an aquaponic greenhouse to gain ﬁrsthand observations. Take lots of pictures to document the system components and how they relate to one another. Keep in mind that aquaponic growers are busy people with a considerable investment in time and resources to establish their businesses. 5. Attend a short course. There are three prominent aquaponic short courses in North America, oﬀered by University of the Virgin Islands, (University of the Virgin Islands, No date) Aquaculture International (Aquaculture International, No date) in North Carolina, and Growing Power (Growing Power, No date) in Wisconsin. Cornell University cohosts a recirculating aquaculture short course in association with The Freshwater Institute (Cornell University, No date). In addition, Nelson and Pade, Inc. has a list of training courses on their website accessible at www.aquaponics.com/ infoCourses.htm. 6. Obtain one or two aquaponic training manuals to acquire detailed technical speciﬁcations. The book Aquaponic Food Production: raising ﬁsh and plants for food and proﬁt; the Desktop Aquaponics Booklet;

A

quaponics is one method of hydroponics, and hydroponics is one method of greenhouse production.

For general information and supplies associated with greenhouse vegetable production, see the ATTRA resource list Greenhouse and Hydroponic Vegetable Production Resources on the Internet. Complementary ATTRA publications include Organic Greenhouse Vegetable Production and Integrated Pest Management for Greenhouse Crops. Building and equipping a commercial-sized aquaponic greenhouse can cost $10,000 to $30,000, depending on the system design and choice of components. Due to the highly technical nature of aquaponics and the expense associated with greenhouse production, prospective growers are advised to thoroughly investigate production methods and market potential. A sequence of considerations and learning opportunities geared to evaluating an aquaponic greenhouse enterprise are listed below. 1. Aquaponic greenhouses yield two food products. To evaluate greenhouse proﬁtability, obtain typical yields and market prices for hydroponic vegetables and ﬁsh, and investigate local and regional markets and related point of sales. Retail sales directly out of your greenhouse or roadside stand might be an ideal situation, but this will depend on your location. 2. Aquaponics is one method of hydroponics, and hydroponics is one method of greenhouse production. Consider lowercost and simpler alternatives. Bag culture of greenhouse vegetables – raising plants in polyethylene grow bags ﬁ lled

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and the Introduction to Aquaponics DVD from Nelson and Pade, Inc. are good starting points. When you are ready to explore a commercial system, the design manuals from S&S Aqua Farm in Missouri and Joel Malcolm’s Backyard Aquaponics in Western Australia contain in-depth technical speciﬁcations, illustrations, and parts lists (S&S Aqua Farm, Joel Malcolm, no dates). The Web Resources section lists additional training manuals and technical documentation. 7. Hire an agricultural consultant to acquire expert advice and consultation, and to shorten the time and risk involved getting started. A few consultants with expertise in aquaponics are listed in the Agriculture Consultants section below. 8. Participate on the Aquaponics E-mail Discussion Group. E-mail discussion lists

have become the modern town square. This is where practitioners, scientists, specialists, and business people all share resources, supplies, and production methods. The e-mail list is hosted by Paula Speraneo with S&S Aqua Farms. The archives are publicly accessible, and serve as a treasure trove of technical information and farmer-to-farmer exchange. 9. Lastly, avoid the “inventor’s urge” to reinvent the wheel. Successful aquaponic greenhouse operators have already ﬁgured out the system components and methods of production, based on years of research and experience. Pick one of the existing models and duplicate it insofar as possible. The old saying, “Get the engine running ﬁrst, then adjust the carburetor,” can be aptly applied to aquaponic start-up greenhouses.

References
1. Rakocy, James E., Donald S. Bailey, R. Charlie Shultz and Eric S. Thoman. 2004. Update on tilapia and vegetable production in the UVI aquaponic system. p. 676-690. In: New Dimensions on Farmed Tilapia: Proceedings of the Sixth International Symposium on Tilapia in Aquaculture, Held September 12-16, 2004 in Manila, Philippines. 2. University of the Virgin Islands – International Aquaponics and Tilapia Aquaculture www.uvi. edu/sites/uvi/Pages/AES-AquacultureInternational_Aquaponics.aspx?s=RE 3. Aquaculture International – Short Course on Aquaponics www.aquacultureinternational.org 4. Growing Power – Short Course on Aquaponics www.growingpower.org 5. Cornell University – Short Course on Recirculating Aquaculture www.bee.cornell.edu/cals/bee/ outreach/aquaculture/short-course/index.cfm 6. S&S Aqua Farm – Design Manual www.jaggartech. com/snsaqua 7. Joel Malcolm – Backyard Aquaponics Design Manual Western Australia joel@backyardaquaponics.com, www.backyardaquaponics.com

Resources
E-mail Discussion Lists for Aquaponics - Hydroponics - Aquaculture
Aquaponic E-Mail List Paula Speraneo of S & S Aqua Farm in Missouri hosts the Aquaponics E-Mail list on the Internet. Th e Aquaponics List is a prominent source of technology transfer and resource sharing on all aspects of aquaponics: hydroponics, aquaculture, ﬁ sh species, supplies, practical solutions, and resources. The e-mail archives are a key source of information. To subscribe, send an email request to: snsaquasys@townsqr.com To view Web e-mail archives, go to: Aquaponics List – Before 2002 www.i55mall.com/aquaponics

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Hydroponics and Aquaculture E-Mail List A number of e-mail lists on hydroponics and aquaculture are scattered among the Internet hosting sites like YahooGroups.com, MSN.com, and Topica.com.

Aquaculture and Aquaponic Trade Magazines, Organizations, and Journals
Aquaponics Journal Nelson and Pade, Inc. PO Box 761 Montello, WI 53949, USA phone 608-297-8708 Toll-free Fax: 866-815-9734 info@aquaponics.com www.aquaponicsjournal.com Aquaponics Journal is the quarterly journal from Nelson and Pade, Inc. It has become a prominent source for articles, reports, news, and supplies for the aquaponics industry. Back issues are a valuable resource, available in print or as e-ﬁles. The Growing Edge Magazine New Moon Publishing P.O. Box 1027 Corvallis, OR 97339-1027 800-888-6785; 541-757-8477 541-757-0028 Fax www.growingedge.com The Growing Edge is a bi-monthly trade magazine on high-tech gardening systems like hydroponics, bioponics, aquaponics, and ecologically based pest management. Past articles are an important source of technical information on aquaponics, bioponics, and organic hydroponics. Practical Hydroponics & Greenhouses P.O. Box 225 Narrabeen, NSW 2101 Australia Phone: +61 (02) 9905 9933 Fax: +61 (02) 9905 9030 info@hydroponics.com.au www.hydroponics.com.au Practical Hydroponics & Greenhouses is a bimonthly magazine dedicated to soilless culture and greenhouse production. Articles proﬁle soilless culture and greenhouse enterprises from around the world. It also reports on new products, research and development, and industry news. Back issues are a valuable resource. The awardwinning magazine is now online as an exact digital copy of the print edition, using DjVu technology. Grower Talks www.ballpublishing.com
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Ball Publishing 622 Town Road P.O. Box 1660 West Chicago, IL 60186 Tel: (630) 231-3675 Toll Free (888) 888-0013 Fax: (630) 231-5254 email: info@ballpublishing.com Greenhouse Grower www.greenhousegrower.com Greenhouse Product News www.gpnmag.com Scranton Gillette Communications, Inc. 3030 W. Salt Creek Lane, Suite 201 Arlington Heights, Illinois 60005-5025 USA 847-391-1000 847-390-0408 World Aquaculture www.was.org/main/summaryasp?page=magazine Carol Mendoza, Director WAS Home Oﬃce 143 J. M. Parker Coliseum Louisiana State University Baton Rouge, LA 70803 (USA) 1-225-578-3137 FAX: 1-225-578-3493 carolm@was.org Aquafeed.com http://aquafeed.com editor@aquafeed.com Austasia Aquaculture www.austasiaaquaculture.com.au Unit 2, Level 2, Bellerive Quay, 31 Cambridge Rd, Bellerive Tasmania, Australia 701803 6245 0064 Aquanews Archives http://pdacrsp.oregonstate.edu/aquanews/archive.html Aquaculture articles. Permaculture Activist #52 (magazine). Summer 2004. www.permacultureactivist.net Aquaculture Collaborative Research Support Program, Oregon State University. http://pdacrsp.oregonstate.edu NOAA Aquaculture Program http://aquaculture.noaa.gov
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Aquaculture Network Information Center (AquaNIC) www.aquanic.org Ecotao’s Aquaculture Links www.ecotao.com/holism/agric/aqua.htm American Fisheries Society Online Journals http://afs.allenpress.com/perlserv/?request=get-archive Scientiﬁc Journals on Aquaculture (Elsevier journal) www.sciencedirect.com/science/journal/00448486 Aquacultural Engineering (Elsevier journal) www.sciencedirect.com/science/journal/01448609 Aquaculture International (Springer journal) www.springerlink.com/content/1573-143X/?p=d6dfe772b 59245f287cad843d6809276&pi=107 Aquaculture Research (Blackwell journal) www.wiley.com/bw/journal.asp?ref=1355-557X

The Aquaponics Guidebook http://accesstoaquaponics.com/book.html

Agricultural Consultants for Integrated Hydroponics and Aquaculture
AquaRanch Industries, LLC [Contact: Myles Harston] 404 D. East Lincoln St. P.O. Box 658 Flanagan, IL 61740 815-796-2978 (815)796-4485 FAX kat@aquaranch.com www.aquaranch.com Fisheries Technology Associates, Inc. [Contact: Bill Manci] 506 Wabash Street Fort Collins, CO 80522-3245 970-225-0150 info@ftai.com www.ftai.com Global Aquatics USA, Inc. 505 Aldino Stepney Rd. Aberdeen, MD 21001 443-243-8840 410-734-7473 FAX aquatic@iximd.com www.growﬁsh.com Gordon Creaser 4886-115 Garﬁeld Street Sumas, Wa 98295 USA Phone: (407) 421-9816 www.gordoncreaser.com Mark R. McMurtry PMB 267 1627 W. Main St. Bozeman, MT 59715-4011 (406) 585-8000 mcmurtry@avicom.net Nelson and Pade, Inc. PO Box 761 Montello, Wisconsin 53949 USA 608-297-8708 866-815-9734 FAX kat@aquaponics.com www.aquaponics.com S&S Aqua Farms [Contact: Paula Speraneo] ATTRA
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Aquaponic Books and Videos
Nelson and Pade, Inc., publisher of Aquaponics Journal, oﬀers booklets, DVDs, videos, and educational curricula on aquaponics, hydroponics, and aquaculture. See their Web page for details. Contact: Nelson and Pade, Inc. PO Box 761 Montello, Wisconsin 53949 USA 608-297-8708 866-815-9734 FAX Pinfo@aquaponics.com www.aquaponics.com Rebecca L. Nelson and John S. Pade. 2008. Aquaponic Food Production: raising ﬁsh and plants for food and proﬁt. www.aquaponics.com/ShopAFPBook.htm Integrated agriculture-aquaculture: A primer. FAO/ IIRR/WorldFish Center 2001. www.fao.org/docrep/005/ y1187e/y1187e00.htm Hutchinson, Laurence. 2005. Ecological Aquaculture: A Sustainable Solution. Hampshire, England: Permanent Publications. www.amazon.com/ Ecological-Aquaculture-Sustainable-LaurenceHutchinson/dp/1856230325 Van Gorder, Steven D. 2000. Small Scale Aquaculture: A hobbyist’s guide to growing ﬁsh in greenhouses, recirculating systems, cages, and ﬂowing water. Breinigsville, PA: Alternative Aquaculture Association, Inc. www.altaqua.com www.attra.ncat.org 407 Pennsylvania Ave West Plains, MO 65775 417-256-5124 snsaquasys@townsqr.com www.jaggartech.com/snsaqua

Aquaculture Associations
Aquacultural Engineering Society www.aesweb.org American Tilapia Association http://ag.arizona.edu/azaqua/ata.html The Alternative Aquaculture Association www.altaqua.com Directory of Aquaculture Associations Aquaculture Network Information Center (AquaNIC) http://aquanic.org/publicat/govagen/nal/associat.htm Texas Aquaculture Association www.texasaquaculture.org Miami Aqua-culture, Inc. www.miami-aquaculture.com

AFSIC, NAL, USDA-ARS 10301 Baltimore Ave., Room 132 Beltsville, MD 20705-2351 301-504-6559 301-504-6927 Fax afsic@nal.usda.gov http://afsic.nal.usda.gov/nal_display/index.php?tax_ level=1&info_center=2

Other Aquaculture Resources
Aquaculture Network Information Center (AquaNIC) http://aquanic.org AquaNIC is the gateway to the world’s electronic resources for aquaculture information. Especially see the extensive resource listing on recirculating aquaculture systems, and the complete listing of publications from the Regional Aquaculture Centers. Recirculating Aquaculture Systems – Index, Aquaculture Network Information Center (AquaNIC) http://aquanic.org/systems/recycle/documents/ recirculatingoklahoma.pdf Regional Aquaculture Center Publications – Index, Aquaculture Network Information Center (AquaNIC) http://aquanic.org/publicat/usda_rac/fact.htm Environmentally Friendly Aquaculture Digital Library National Sea Grant Library http://nsgd.gso.uri.edu/aquadig.html The National Sea Grant Library (NSGL) contains a complete collection of Sea Grant funded work. The NSGL maintains a bibliographical database containing over 36,000 records that can be searched by authorkeyword or browsed by topic. Selected items include proceedings from recirculating aquaculture conferences and related documents. The Environmentally Friendly Aquaculture Digital Library is a topic-oriented portal to NSGL, organized by subject category.

Aquaculture Directories and Resource Collections
National Agricultural Library – Alternative Farming Systems Information Center The Alternative Farming Systems Information Center (AFSIC) at the National Agricultural Library, a program of USDA-ARS, provides extensive aquaculture resource listings. Organic Aquaculture (AFSIC Notes No. 5), published in January 2005, is an important new publication from AFSIC that addresses the potential of organic aquacultural products; it also contains a section on recirculating aquaculture.

Aquaculture Resources http://afsic.nal.usda.gov/nal_display/index.php?info_ center=2&tax_level=2&tax_subject=295&level3_ id=0&level4_id=0&level5_id=0&topic_ id=1410&&placement_default=0

Aquaponic Resources on the Web
Selected Publications from Southern Regional Aquaculture Center (SRAC)
Recirculating Aquaculture Tank Production Systems: Integrating Fish and Plant Culture SRAC Publication No. 454 (PDF/314K) http://srac.tamu.edu/tmppdfs/504545-SRAC454.pdf?CFI D=504545&CFTOKEN=21206104&jsessionid=90308c 91b4fe7d1ee6e016a4c5e6e4a61c51
Aquaponics—Integration of Hydroponics with Aquaculture

Organic Aquaculture
• Aquaculture-Related Internet Sites and Documents • Directory of Aquaculture Related Associations and Trade Organizations • Directory of State Aquaculture Coordinators and Contacts • Automated Searches on General Aquaculture Topics
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Recirculating Aquaculture Tank Production Systems: An Overview of Critical Considerations SRAC Publication No. 451 (PDF/142K) http://srac.tamu.edu/tmppdfs/504545-451fs.pdf?CFID=5 04545&CFTOKEN=21206104&jsessionid=90308c91b 4fe7d1ee6e016a4c5e6e4a61c51 Recirculating Aquaculture Tank Production Systems: Management of Recirculating Systems SRAC Publication No. 452 (PDF/115K) http://srac.tamu.edu/tmppdfs/504545-452fs.pdf?CFID=5 04545&CFTOKEN=21206104&jsessionid=90308c91b 4fe7d1ee6e016a4c5e6e4a61c51 Recirculating Aquaculture Tank Production Systems: Component Options SRAC Publication No. 453 (PDF/378K) http://srac.tamu.edu/tmppdfs/504545-453fs.pdf?CFID=5 04545&CFTOKEN=21206104&jsessionid=90308c91b 4fe7d1ee6e016a4c5e6e4a61c51 Tank Culture of Tilapia SRAC Publication No. 282 (PDF/49K) http://srac.tamu.edu/tmppdfs/504545-282fs.pdf?CFID=5 04545&CFTOKEN=21206104&jsessionid=90308c91b 4fe7d1ee6e016a4c5e6e4a61c51

• Suggested Management Guidelines for An Integrated Recycle Aquaculture – Hydroponic System • The Freshwater Institute Natural Gas Powered Aquaponic System - Design Manual • 880 Gallon Recycle Aquaculture System Installation Guide • Linking Hydroponics to an 880 Gallon Recycle Fish Rearing System • Operators Manual for 880 - Recycle System Aquaculture on Cat Beach www.rainbowﬁsh.se/english/f89.htm www.rainbowﬁsh.se/bilder/education_short.doc A 10-page booklet with directions on establishing a small aquaponic system, including a parts list. Th e HTML version contains additional photos that illustrate system components and greenhouse production. Barrel-Ponic (aka Aquaponics in a Barrel) (PDF/3.09MB) by Travis W. Hughey www.aces.edu/dept/ﬁsheries/education/documents/ barrel-ponics.pdf

Selected Aquaponic Training Materials and Design Manuals
S&S Aqua Farm www.jaggartech.com/snsaqua Design manual with speciﬁcations Backyard Aquaponics http://www.backyardaquaponics.com Design manual with speciﬁcations A Prototype Recirculating AquacultureHydroponic System (PDF/94K) By Donald Johnson and George Wardlow University of Arkansas, Department of Agricultural and Extension Education AgriScience Project www.uark.edu/depts/aeedhp/agscience/aquart2.pdf A 10-page reprint article, originally published in Journal of Agricultural Mechanization (1997). It describes a low cost (less than $600) recirculating aquaculturehydroponic system suitable for use in laboratory settings, including a materials list with approximate cost of materials to set up a 350-gallon aquaponic unit. The Freshwater Institute Publications Index, Shepherdstown, West Virginia www.freshwaterinstitute.org/publications www.attra.ncat.org General Aquaponic Resources on the Web
The Essence of Aquaponics – Index to Aquaponics Mail Group Topics www.rainbowﬁsh.se/mailgroup/index.html The Essence of Aquaponics website of Pekka Nygard and Stefan Goës in Sweden provides an index to key topics (aquaponics, ﬁsh, ﬁsh feed, plants, plant nutrition, water, bioﬁlters, greenhouses, maintenance, economics, links, literature) posted on the Aquaponics Mail Group (see e-mail resources above). Aquaponics Library http://aquaponicslibrary.20megsfree.com/Index.htm Enhancing Student Interests in the Agricultural Sciences through Aquaponics (PDF/725K) by G.W. Wardlow and D.M. Johnson University of Arkansas, Department of Agricultural and Extension Education. www.uark.edu/depts/aeedhp/agscience/aquart.pdf Free Articles on Hydroponics, Practical Hydroponics and Greenhouses http://hydroponics.com.au/php/viewforum.php?f=3 Aquaponics Proves Proﬁtable in Australia, Aquaponics Journal, First Quarter, 2002. www.aquaponicsjournal.com/articleaustralia.htm ATTRA
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Integrated Systems of Agriculture and Aquaculture Aquaculture in the Classroom, University of Arizona http://ag.arizona.edu/azaqua/extension/Classroom/ Aquaponics.htm Aquaponics Pty Ltd www.aquaponics.com.au/index.htm Aquaponics Combine Fish, Tomatoes, and Ingenuity University of Illinois Extension http://web.extension.uiuc.edu/smallfarm/pdf/oursare/ aquaponics.pdf Hydroponics Integration with Aquaculture (powerpoint) www.texasaquaculture.org/Presentations/ Masser%20Aquaponics.pdf

download from their website. The budgets include • Channel catﬁsh pond farm • Hybrid striped bass pond farm • Rainbow trout raceway farm • Water recirculating ﬁsh farm Aquaculture Budgets, Universities of Illinois and Indiana Sea Grant www.agecon.purdue.edu/AQUABUSINESS/budgets.html

Aquaculture Publications
Southern Regional Aquaculture Center Publications. http://srac.tamu.edu The Southern Regional Aquaculture Center has an online library of very helpful publications on all aspects of aquaculture, from pond and cage construction to species and disease to marketing and promotion. Northeastern Regional Aquaculture Center (NRAC) www.nrac.umd.edu NRAC is a principal public forum for the advancement and dissemination of science and technology needed by Northeastern aquacultural producers and support industries. Publications are located here www.nrac.umd.edu/ publications/factSheets.cfm. ALabama Education in aquatic sciences, Aquaculture, Recreational ﬁsheries and Natural resource conservation (ALEARN) www.aces.edu/dept/ﬁsheries Mississippi State University Aquaculture Publications http://msucares.com/aquaculture University of Arkansas Aquaculture/Fisheries Center Publications www.uaex.edu/aqﬁ/extension/publications/factsheet National Ag Law Center – Aquaculture http://nationalaglawcenter.org/readingrooms/aquaculture

Aquaculture Resources on the Web
Greenhouse Tilapia Production in Louisiana Louisiana State University www.lsuagcenter.com/en/communications/ publications/Publications+Catalog/Environment/ Aquaculture++Fisheries/Greenhouse+Tilapia+Production +in+Louisiana.htm Recirculating Aquaculture Systems -- Teacher’s Resource Website. Auburn University www.aces.edu/dept/ﬁsheries/education/ recirculatingaquaculture.php The Urban Aquaculture Manual by Jonathan Woods www.webofcreation.org/BuildingGrounds/aqua/TOC.html NorthernAquaFarms.com www.northernaquafarms.com National Oceanic and Atmospheric Administration Aquaculture Program http://aquaculture.noaa.gov Florida Division of Aquaculture www.ﬂoridaaquaculture.com West Virginia University Extension Service Aquaculture www.wvu.edu/~agexten/aquaculture

Water Engineering
Bocek, Alex. Water Harvesting and Aquaculture for Rural Development. Auburn University: International Center for Aquaculture and Aquatic Environments. www.ag.auburn.edu/ﬁsh/international// waterharvestingpubs.php Alberta Agriculture. 2002. Spring Development, Agdex 716 (A15). Technical Services Division. http:// www1.agric.gov.ab.ca/$Department/deptdocs.nsf/all/ agdex4595 USDA. 1984. National Engineering Handbook - Part 650, Engineering Field Handbook, Chapter 12, Springs
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Aquaculture Budgets
Aquaculture Enterprise Budget Spreadsheets. Auburn University Marine Extension & Research Center. www.aces.edu/dept/ﬁsheries/aquaculture/budgets.php The Extension specialists at Auburn have developed four Excel spreadsheets and are available as a free
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and Wells. http://directives.sc.egov.usda.gov/OpenNon WebContent.aspx?content=17550.wba

Aquaculture and Aquaponic Farms
Sweet Water Organics. http://sweetwater-organic.com/blog Sweet Water Organics will be the ﬁrst major commercial upgrading of MacArthur genius Will Allen’s aquaculture methodologies, i.e. a three-tiered, aquaponic, bio-intensive ﬁsh-vegetable garden. Sweet Water will be the anchor project in the transformation of a massive industrial building in an “ industrial slum” into a showcase of the potential of living technologies and high-value added urban agriculture. Sweet Water’s sustainable aquaculture system harvests urban waste streams, e.g. wood chips, cardboard, veggie residues, coﬀee grounds, and brewers mash, along vermiculture lines, yielding the richest possible soil. This soil in hundreds of potted plants on the simulated wetland tiers is key to the transformation of ﬁsh wastes into natural nitrate for plant growth and water ﬁltration. Eli Rogosa. Organic Aquaponics. www.growseed.org/growingpower.html Photographic tour of a Growing Power aquaponic system. Bioshelters. www.bioshelters.com Bioshelters is a recirculating aquaponics facility located in Amherst, Massachusetts. Our entire system is contained in a large solar-heated greenhouse called a Bioshelter. Solar structures create the least expensive and best natural environment for plants, animals and people. To learn more about our greenhouse system please follow the link below. Because the ﬁsh, plant and human systems are linked, no pesticides can be used on our produce. Backyard Aquafarms http://backyardaquafarms.com

DukeFish, a Durham-based community-supported ﬁshery. Duke University’s student chapter of the American Fishery Society www.walking-ﬁsh.org Carteret Catch, Project Green Leaf, Carteret County, NC http://greenleaf.uncg.edu/carteretcatch/Index3.html Information for ﬁshermen and consumers. http:// greenleaf.uncg.edu/carteretcatch/CommSuppFish1.html Catch a Piece of Maine, Lobster Community Supported Fishery www.catchapieceofmaine.com

Aquacultural and Maricultural Business Development
Aquacopia www.aquacopia.com Aquaculture Investment: Lowering the Risks, Western Regional Aquaculture Center http://aqua.ucdavis.edu/DatabaseRoot/pdf/WRAC-103.PDF

Regional Aquaculture Centers sponsored by the Extension Service
Northeastern Regional Aquaculture Center (NRAC) www.nrac.umd.edu North Central Regional Aquaculture Center (NCRAC) www.ncrac.org Southern Regional Aquaculture Center (SRAC) www.msstate.edu/dept/srac Western Regional Aquaculture Center (WRAC) www.ﬁsh.washington.edu/wrac Center for Tropical and Subtropical Aquaculture www.ctsa.org Aquaculture Network Information Center www.aquanic.org

Community Supported Fisheries
Much like community supported agriculture, community supported ﬁsheries are cooperatives of family ﬁshermen who market their catch directly to customers usually through a subscription mechanism, whereby customers receive a certain amount of product per week (a share) for a yearly share price. Four innovative projects are listed below: Port Clyde Fresh Catch CSF www.portclydefreshcatch.com www.attra.ncat.org Integrated Bio-Systems on the Web
Integrated Biosystems, Paul Harris, The University of Adelaide www.adelaide.edu.au/biogas/website/integratedbiosys.pdf World Fish Center www.worldﬁshcenter.org/wfcms/HQ/Default.aspx Ecological Engineering (Elsevier journal) www.sciencedirect.com/science/journal/09258574 Ecological engineering has been deﬁned as the design of ecosystems for the mutual beneﬁt of humans and nature. ATTRA
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Speciﬁc topics covered in the journal include: ecotechnology; synthetic ecology; bioengineering; sustainable agroecology; habitat reconstruction; restoration ecology; ecosystem conservation; ecosystem rehabilitation; stream and river restoration; wetland restoration and construction; reclamation ecology; non-renewable resource conservation. Wastewater-fed Aquaculture in Temperate Climates Nutrient recycling with Daphnia and Fish (PDF/97K), 4th International Conference on Ecological Engineering for Wastewater Treatment, June 1999, Aas, Norway www.hortikultur.ch/pub/ﬁles/15.pdf

McMurtry, Mark Richard. 1992. Integrated Aquaculture- Olericulture System as Inﬂuenced by Component Ratio. PhD. Dissertation, North Carolina State University. UMI, Ann Harbor, MI. 78 p. McMurtry, M.R., D.C. Sanders, and P.V. Nelson. 1993. Mineral nutrient concentration and uptake by tomato irrigated with recirculating aquaculture water as inﬂuenced by quantity of ﬁsh waste products supplied. Journal of Plant Nutrition. Vol. 16, No. 3. p. 407–409. McMurtry, M.R., et al. 1993. Yield of tomato irrigated with recirculating aquacultural water. Journal of Production Agriculture. Vol. 6, No. 3. (July-September). p. 428–432. McMurtry, M.R., D.C. Sanders, and R.G. Hodson. 1997. Eﬀects of bioﬁlter/culture tank volume ratios on productivity of a recirculating ﬁsh/vegetable co-culture system. Journal of Applied Aquaculture. Vol. 7, No. 4. p. 33–51. McMurtry, M.R., D.C. Sanders, J.D. Cure, R.G. Hodson, B.C. Haning, and P.C.S. Amand. 1997. Eﬃciency of water use of an integrated ﬁsh/vegetable co-culture system. Journal of the World Aquaculture Society. Vol. 28, No. 4. p. 420–428. Sanders, Doug, and Mark McMurtry. 1988. Fish increase greenhouse proﬁts. American Vegetable Grower. February. p. 32–33. Watanabe, Wade O., Thomas M. Losordo, Kevin Fitzsimmons, and Fred Hanley. 2002. Tilapia Production Systems in the Americas: Technological Advances, Trends, and Challenges. Reviews in Fisheries Science, 10(3&4): 465–498. http://aquanic.org/species/tilapia/documents/s6.pdf

Appendix I: Bibliography on Aquaponics
The following bibliography contains selected literature citations on aquaponics and integrated hydroponicsaquaculture published in trade magazines and scientiﬁc journals. Collectively, these articles provide an instant library on aquaponics. They are provided here as an important time saver to those seeking technical and popular information on this topic. University libraries carry scientiﬁc journals (e.g., Aquaculture International, Aquacultural Engineering) and trade magazines (Aquaculture, Greenhouse Management and Production), and they oﬀer on-site photocopying services to library visitors. Inter-Library Loan is a service available through most local libraries, and can provide photocopies of articles for a small fee. Please note The Growing Edge, Aquaponics Journal, and Practical Hydroponics & Greenhouses are the most relevant trade magazines for aquaponics, recirculating aquaculture, hydroponics, and related topics, including farmer proﬁles. However, they are relatively new and less widely distributed in university libraries. For a complete list of articles and back issues available through these trade magazines, see the publisher’s websites: The Growing Edge www.growingedge.com/magazine/compindex.html Aquaponics Journal www.aquaponicsjournal.com/BackIssues.htm Practical Hydroponics & Greenhouses www.hydroponics.com.au

The Speraneo System
Durham, Deni. 1992. Low-tech polycultural yields, high proﬁt. Small Farm Today. June. p. 23–25. Modeland, Vern. 1993. Aquafarming on a budget. BackHome. Summer. p. 28–31. Modeland, Vern. 1998. The Ozarks’ S&S aqua farm. The Ozarks Mountaineer. June-July. p. 42–44. Modeland, Vern. 1998. Maturing marvel: S&S Aqua Farm. The Growing Edge. Vol. 9, No. 5 (May- June). p. 35–38. Rich, Doug. 1998. Closed system opens markets. The High Plains Journal. Vol. 115, No. 34. August 24. p. 1–A.
Aquaponics—Integration of Hydroponics with Aquaculture

North Carolina State University
McMurtry, M.R., et al. 1990. Sand culture of vegetables using recirculating aquacultural eﬄuents. Applied Agricultural Research. Vol. 5, No. 4. (Fall). p. 280–284.
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Smith, John Wesley. 1993. The genius of simplicity. The Growing Edge. Vol. 5, No. 2. (Fall). p. 40–44, 70. Thompson, Nina. 1993. Fish + plants = food. Missouri Conservationist. August. p. 28. Yarrow, David. 1998. A food production revolution: Missouri aquafarmers discover huge beneﬁts in trace elements integrated with hydroponics. Remineralize the Earth. Spring-Fall, No. 12-13. p. 38–43.

Rakocy, James. 1999. The status of aquaponics, Part II. Aquaculture Magazine. September-October. p. 64-70. Rakocy, J.E., D.S. Bailey, K.A. Shultz and W.M. Cole. 1997. Evaluation of a commercial-scale aquaponic unit for the production of tilapia and lettuce. p. 357-372. In: Tilapia Aquaculture: Proceedings from the Fourth International Symposium on Tilapia in Aquaculture. Orlando, FL. Rakocy, J.E. 1997. Integrating tilapia culture with vegetable hydroponics in recirculating systems. p. 163-184. In B.A. Costa Pierce and J.E. Rakocy (eds.) Tilapia Aquaculture in the Americas. Vol. 1. World Aquaculture Society, Baton Rouge, LA. 258 p. Rakocy, J.E. and J.A. Hargreaves. 1993. Integration of vegetable hydroponics with ﬁsh culture: A review, p. 112-136. In: J.K. Wang (ed.) Techniques for Modern Aquaculture, Proceedings Aquacultural Engineering Conference. American Society for Agricultural Engineers, St. Joseph, MI. Rakocy, J.E., J.A. Hargreaves, and D.S. Bailey. 1993. Nutrient accumulation in a recirculating aquaculture system integrated with hydroponic vegetable gardening, p. 148-158. In: J.K. Wang (ed.) Techniques for Modern Aquaculture, Proceedings Aquacultural Engineering Conference. American Society for Agricultural Engineers, St. Joseph, MI. Rakocy, James E., Thomas M. Losordo, and Michael P. Masser. 1992. Recirculating Aquaculture Tank Production Systems: Integrating Fish and Plant Culture. SRAC Publication No. 454. Southern Region Aquaculture Center, Mississippi State University. 6p. Rakocy, J.E., and A. Nair. 1987. Integrating ﬁsh culture and vegetable hydroponics: Problems and prospects. Virgin Islands Perspectives, University of the Virgin Islands Agricultural Experiment Station, St. Croix, U.S. Virgin Islands. Vol. 1, No. 1. (Winter/ Spring 1987). p. 19-23. Rakocy, James E. 1984. A recirculating system for tilapia culture and vegetable hydroponics in the Caribbean. Presented at the Auburn Fisheries and Aquaculture Symposium, September 20-22, Auburn University, Alabama. 30 p. Rakocy, James E. 1989. Vegetable hydroponics and ﬁsh culture: A productive interface. World Aquaculture. September. p. 42-47. Bailey, D.S., J.E. Rakocy, W.M. Cole and K.A. Shultz. 1997. Economic analysis of a commercial-scale aquaponic ATTRA
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The Rakocy System and Related Papers
Rakocy, J., R.C. Shultz, D.S. Bailey, E.S. and Thoman. 2004. Aquaponic production of tilapia and basil: comparing a batch and staggered cropping system. Acta Horticulturae. Vol. 648. p. 63–69. www.actahort.org/books/648/648_8.htm Rakocy, James E., Donald S. Bailey, R. Charlie Shultz and Eric S. Thoman. 2004. Update on tilapia and vegetable production in the UVI aquaponic system. (PDF/ 251K). p. 676–690. In: New Dimensions on Farmed Tilapia: Proceedings of the Sixth International Symposium on Tilapia in Aquaculture, Manila, Philippines. http://ag.arizona.edu/azaqua/ista/ista6/ista6web/pdf/676.pdf Rakocy, James E., Donald S. Bailey, Eric. S. Thoman and R. Charlie Shultz. 2004. Intensive tank culture of tilapia with a suspended, bacterial-based, treatment process. (PDF/368K). p. 584–596. In: New Dimensions on Farmed Tilapia: Proceedings of the Sixth International Symposium on Tilapia in Aquaculture. http://ag.arizona.edu/azaqua/ista/ista6/ista6web/pdf/584.pdf Rakocy, J.E., D.S. Bailey, J.M. Martin and R.C. Shultz. 2003. Tilapia production systems for the Lesser Antilles and other resource-limited, tropical areas. In: Report of the Subregional Workshop to Promote Sustainable Aquaculture Development in the Small Island Developing States of the Lesser Antilles. FAO Fisheries Report No. 704 www.fao.org/docrep/006/Y4921E/y4921e07.htm#bm7.3 Rakocy, James E. 1998. Integrating hydroponic plant production with recirculating system aquaculture: Some factors to consider. p. 392-394. In: Proceedings of Second International Conference on Recirculating Aquaculture, Held July 16-19, Roanoke, VA. http://nsgd.gso.uri.edu/vsgcp/vsgcpc98001/ vsgcpc98001index.html Rakocy, James. 1999. The status of aquaponics, Part I. Aquaculture Magazine. July-August. p. 83-88. www.attra.ncat.org system for the production of tilapia and lettuce. p. 603-612. In: Tilapia Aquaculture: Proceedings from the Fourth International Symposium on Tilapia in Aquaculture, Orlando, FL. Cole, W.M., J.E. Rakocy, K.A. Shultz and D.S. Bailey. 1997. Eﬀects of solids removal on tilapia production and water quality in continuously aerated, outdoor tanks. p. 373-384. In: Tilapia Aquaculture: Proceedings from the Fourth International Symposium on Tilapia in Aquaculture, Orlando, FL. Nair, Ayyappan, James E. Rakocy, and John A. Hargreaves. 1985. Water quality characteristics of a closed recirculating system for tilapia culture and tomato hydroponics. p. 223-254. In: Randy Day and Thomas L. Richards (ed). Proceedings of the Second International Conference on Warm Water Aquaculture – Fin-ﬁsh. Brigham Young University Hawaii Campus, February 5-8, 1985. Bioshelters, Inc. Dinda, Kara. 1997. Hydroponics & aquaculture working together: A case study. The Growing Edge. September-October. p. 56-59. Spencer, Robert. 1990. Investing in an ecosystem. In Business. July-August. p. 40-42.

production strategy on lettuce and basil productivity and phosphorus removal from aquaculture wastewater. Environmental Research Forum. Vols. 5–6. p. 131–136. Brown, Robert H. 1993. Scientists seek better ways of utilizing eﬄuent from ﬁsh. Feedstuﬀs. May 31. Vol. 65, No. 22. p. 10. Jenkins, M.R., Jr. and S.T. Summerfelt. 2000. A natural gas-powered small-scale: aquaponic demonstration project. Small Farm Today. Vol. 17, No. 4. (July-Aug). p. 45–46. Jenkins, M. R., and S.T. Summerfelt. 1999. Demonstrating aquaponics. Practical Hydroponics & Greenhouses. Vol. 44. January-February. p. 48–51. Stanley, Doris. 1993. Aquaculture springs up in West Virginia. Agricultural Research. March. p. 4–8. Takeda, F., P. Adler, and D.M. Glenn. 1993. Growing greenhouse strawberries with aquaculture eﬄuent. Acta Horticulturae. Vol. 348. p. 264–267. Takeda, F., P.R. Adler, and D.M. Glenn. 1997. Strawberry production linked to aquaculture wastewater treatment. Acta Horticulturae. Vol. 439. p. 673–678. www.actahort.org/books/439/439_113.htm Williams, Greg, and Pat Williams (ed.) 1992. Fishpond eﬄuent + iron=good crop nutrition. HortIdeas. Vol. 9, No. 11. p. 130.

The Freshwater Institute/USDA-ARS
Adler, Paul R., Steven T. Summerfelt, D. Michael Glenn and Fumiomi Takeda. 2003. Mechanistic approach to phytoremediation of water. Ecological Engineering. Vol. 20, No. 3. p. 251–264. Adler, P.R. 2001. Overview of economic evaluation of phosphorus removal by plants. Aquaponics Journal. Vol. 5, No. 4. p. 15–18. Adler, P.R., J.K. Harper, E.W. Wade, F. Takeda, and S.T. Summerfelt. 2000. Economic analysis of an aquaponic system for the integrated production of rainbow trout and plants. International Journal of Recirculating Aquaculture. Vol. 1, No. 1. p. 15–34. Adler, P.R., J.K. Harper, F. Takeda, E.M. Wade, and S.T. Summerfelt. 2000. Economic evaluation of hydroponics and other treatment options for phosphorus removal in aquaculture eﬄuent. HortScience. Vol. 35, No. 6. p. 993–999. Adler, P.R. 1998. Phytoremediation of aquaculture eﬄuents. Aquaponics Journal. Vol. 4, No. 4. p. 10–15. Adler, P. R., S.T. Summerfelt, D.M. Glenn, and F. Takeda. 1996. Evaluation of the eﬀect of a conveyor
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Inslee’s Fish Farm
Nelson, R.L. 1999. Inslee’s aquaponics. AgVentures. Vol. 3, No. 5. (October-November). p. 57–61. Watkins, Gordon. 1999. Inslee ﬁsh farm: A family run aquaponic operation produces chives and ﬁsh. The Growing Edge. Vol. 10, No. 5. (May-June). p. 35–40.

Gordon Watkins’ System
Watkins, Gordon. 1993. Aqua-vegeculture: more food from our water. Farmer to Farmer: Better Farming in the Ozarks. Vol. 3, No. 4. (Winter 1992–1993). p. 1–3, 12. Watkins, Gordon. 1998. Integrating aquaculture and hydroponics on the small farm. The Growing Edge. Vol. 9, No. 5. (May-June) p. 17–21, 23.

New Alchemy
Anon. 1982. Hydroponics in the Ark. Journal of the New Alchemists. No. 8. (Spring). p. 10.
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Baum, Carl. 1981. Gardening in fertile waters. New Alchemy Quarterly. Summer. p. 2–8. Burgoon, P.S., and C. Baum. 1984. Year round ﬁsh and vegetable production in a passive solar greenhouse. International Society for Soilless Culture (ISOSC) Proceedings. p. 151–171. McLarney, Bill. 1983. Integration of aquaculture and agriculture, in the Northern United States. New Alchemy Quarterly. No. 11. (Spring). p. 7–14. Sardinsky, Robert. 1985. Water farms: Integrated hydroponics in Maine. New Alchemy Quarterly. Spring. p. 13–4. Zweig, Ronald D. 1986. An integrated ﬁsh culture hydroponic vegetable production system. Aquaculture Magazine. Vol. 12, No. 3. (May- June). p. 34, 36–40.

Aquaculture Economics & Management. Vol. 3, No. 1 (March). p. 83–91. Clarkson, R. and S.D. Lane. 1991. Use of small-scale nutrient ﬁlm hydroponic technique to reduce mineral accumulation in aquarium water. Aquaculture and Fisheries Management. Vol. 22. p. 37–45. Costa-Pierce, B.A. 1998. Preliminary investigation of an integrated aquaculture-wetland ecosystem using tertiary-treated municipal wastewater in Los Angeles County, California. Ecological Engineering. Vol. 10, No. 4. p. 341–354. www.sciencedirect.com Dontje, J.H. and C.J. Clanton. 1999. Nutrient fate in aquacultural systems for waste treatment. Transactions of the ASAE. Vol. 42, No. 4. p. 1073–1085. Creaser, Gordon. 1997. Aquaponics – combining aquaculture with hydroponics. The Growing Edge. Vol. 1, No. 9. Ghaly, A.E., M. Kamal, and N. S. Mahmoud. 2005. Phytoremediation of aquaculture wastewater for water recycling and production of ﬁsh feed. Environment International. Vol. 31, No. 1 (January). p. 1–13. www.sciencedirect.com Guterstam, B. 1996. Demonstrating ecological engineering for wastewater treatment in a Nordic climate using aquaculture principles in a greenhouse mesocosm. Ecological Engineering. Vol. 6. p. 73–97. Head, William, and Jon Splane. 1980. Fish Farming in Your Solar Greenhouse. Amity Foundation, Eugene, OR. 43 p. Kleinholz, Conrad, Glen Gebhart, and Ken Williams. 1987. Hydroponic/Aquaculture and Aquaculture/ Irrigation Systems: Fish Waste as a Plant Fertilizer. U.S. Department of Interior, Bureau of Reclamation Research Report. Langston University, Langston, OK. 65 p. Kubiak, Jan. 1998. Cape Cod Aquafarm: Combining Ingenuity and Enterprise. The Growing Edge. JulyAugust. p. 36–37, 39-41. Langford, Norma Jane. 1998. Cell ﬁsh and plant pipes and young moms. Maine Organic Farmer and Gardener. Vol. 24, No. 4. (December). p. 24–26. Letterman, Gordon R., and Ellen F. Letterman. 1985. Propagation of prawns and plants in the same environment. Combined Proceedings International Plant Propagator’s Society. Vol. 34. p. 185–188. Lewis, W.M., J.H. Yopp, H. L. Schramm Jr., and A. M. Brandenburg. 1978. Use of hydroponics to maintain ATTRA
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Barramundi and Murray Cod Systems
Lennard, Wilson A. and Brian V. Leonard. 2005. A comparison of reciprocating ﬂow versus constant ﬂow in an integrated, gravel bed, aquaponic test system. Aquaculture International. Volume 12, Number 6. p. 539–553. Wilson, Geoﬀ. 2005. Australian barramundi farm goes aquaponic. Aquaponics Journal. Issue No. 37, 2nd Quarter. p. 12–16.

Miscellaneous
Bender, Judith. 1984. An integrated system of aquaculture, vegetable production and solar heating in an urban environment. Aquacultural Engineering. Vol. 3, No. 2. p. 141–152. www.sciencedirect.com Belusz, Larry. 1993. Recirculating aquaculture: Is it for you? Small Farm Today. June. p. 23–24. Bird, Kimon T. 1993. Aquatic plants for treatment of aquaculture wastewater. Aquaculture Magazine. January-February. p. 39–42. Burgoon, P.S. and C. Baum. 1984. Year round ﬁsh and vegetable production in a passive solar greenhouse. p. 151–171. In. Proceedings of the 6th International Congress on Soilless Culture. Held April 28–May 5, Luntern, The Netherlands. ISOSC, Wageningen, The Netherlands. Chaves, P.A., R.M. Sutherland, and L.M. Laird. 1999. An economic and technical evaluation of integrating hydroponics in a recirculation ﬁsh production system. www.attra.ncat.org quality of recirculated water in a ﬁsh culture system. Transactions of the American Fisheries Society. Vol. 107, No. 1. p. 92–99. http://afsjournals.org/doi/ abs/10.1577/1548-8659(1978)107%3C92%3AUOHTM Q%3E2.0.CO%3B2 Lewis, W.M., J.H. Yopp, A.M. Brandenburg, and K.D. Schnoor. 1981. On the maintenance of water quality for closed ﬁsh production systems by means of hydroponically grown vegetable crops. p. 121–130. In: K. Tiews and H. Heenemann (ed.) Aquaculture in Heated Eﬄuents and Recirculation Systems. Volume 1. Berlin, Germany. Mathieu, Jennifer J., and Jaw-Kai Wang. 1995. The eﬀect of water velocity and nutrient concentration on plant nutrient uptake; A literature review. p. 187–211. In: Aquacultural Engineering and Waste Management. Proceedings from Aquaculture Expo VIII and Aquaculture in the Mid-Atlantic Conference. McClintic, Dennis. 1994. Double-duty greenhouse. The Furrow. March-April. p. 41–42. Naegel, L.C.A. 1977. Combined production of ﬁsh and plants in recirculating water. Aquaculture. Vol. 10, No. 1. p. 17–24. Newton, Scott and Jimmy Mullins. 1990. Hydroponic Tomato Production Using Fish Pond Water. Virginia Cooperative Extension Service. Fact Sheet No. 31. 3 p. Pierce, Barry A. 1980. Water reuse aquaculture systems in two solar greenhouses in Northern Vermont. Proceedings of the Annual Meeting of the World Mariculture Society. Vol. 11. p. 118–127. Przybylowicz, Paul. 1991. Surﬂess and turﬂess: A new wave in integrated food production. The Growing Edge. Vol. 2, No. 3. (Spring). p. 28–34, 60–61. Quillere, I., D. Marie, L. Roux, F. Gosse, J.F. MorotGaudry. 1993. An artiﬁcial productive ecosystem based on a ﬁsh/bacteria/plant association. 1. Design and management. Agriculture, Ecosystems and Environment. Vol. 47, No. 1. (October). p. 13–30. Quillere, I., D. Marie, L. Roux, F. Gosse, J.F. MorotGaudry. 1995. An artiﬁcial productive ecosystem based on a ﬁsh/bacteria/plant association. 2. Performance. Agriculture, Ecosystems and Environment. Vol. 53, No. 1. (March). p. 19–30. Raﬁee, Gholamreza and Che Roos Saad. 2005. Nutrient cycle and sludge production during diﬀerent stages of red tilapia (Oreochromis sp.) growth in a recirculating

aquaculture system. Aquaculture. Vol. 244, No. 1-4. p. 109–118. www.sciencedirect.com Rennert, B. and M. Drews. 1989. The possibility of combined ﬁsh and vegetable production in greenhouses. Advanced Fish Science. Vol. 8. p. 19–27. Rivera, Gregg, and Bruce Isaacs. 1990. Final Report: A Demonstration of an Integrated Hydroponics and Fish Culture System. Submitted to: New York State Department of Agriculture & Markets, Agricultural Research and Development Grants Program. 15 p. Seawright, D.E., R.R. Stickney, and R.B. Walker. 1998. Nutrient dynamics in integrated aquaculturehydroponics systems. Aquaculture. Vol. 160, No. 34 (January). p. 215–237. www.sciencedirect.com Seawright, D.E. 1993. A method for investigating nutrient dynamics in integrated aquaculture-hydroponics systems, p. 137–47. In: J.K. Wang (ed.) Techniques for Modern Aquaculture. American Society for Agricultural Engineers, St. Joseph, MI. Sneed, K. 1975. Fish farming and hydroponics. Aquaculture and the Fish Farmer. Vol. 2, No. 1. p. 11, 18–20. Spencer, Robert. 1990. Wastewater recycling for ﬁsh farmers. BioCycle. April. p. 73–74, 76. Sutton, R.J. and W.M. Lewis. 1982. Further observations on a ﬁsh production system that incorporates hydroponically grown plants. Progressive Fish Culturist. Vol. 44, No. 1. p. 55–59. Thomas, Luther. 1992. Going for gold. The Growing Edge. Vol. 3, No. 4. (Summer). p. 23–29, 40. University of California-Los Angeles. 1975. Waste nutrient recycling using hydroponic and aquacultural methods. Institute of Evolutionary and Environmental Biology, Environmental Science and Engineering, University of California- Los Angeles. 177 p. Watten, Barnaby J., and Robert L. Busch. 1984. Tropical production of tilapia (Sarotherodon aurea) and tomatoes (Lycopersicon esculentum) in a small-scale recirculating water system. Aquaculture. Vol. 41, No. 3. (October). p. 271–283. www.sciencedirect.com Youth, Howard. 1992. Farming in a ﬁsh tank. World Watch. May-June. p. 5–7.

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Appendix II: Dissertations
Dissertations (PhD) and theses (Masters degree) on integrated aquaculture-hydroponic systems can provide critical access to research data and literature reviews. For example, the Speraneos in Missouri and Gordon Watkins in Arkansas used Mark McMurtry’s dissertation from North Carolina State University as a guide in the design of their systems. The UMI ProQuest Digital Dissertations database (see below) provides public Web access to titles and abstracts, via keyword and author search. Print copies are available for sale. Land-grant university libraries – through fee-based subscription– provide full-text access to recent documents via the ProQuest Dissertations and Theses database. Selected titles on aquaponic systems are listed below. The thesis by Carla MacQuarrie contains a detailed description of an aquaponics facility, including parts and pumping equipment, for example. There are numerous other titles in hydroponics, aquaculture, recirculating aquaculture, tilapia, tank culture, and wastewater eﬄuent for those who wish to explore further. Contact: UMI ProQuest Digital Dissertations 789 E. Eisenhower Parkway P.O. Box 1346 Ann Arbor, MI 48106-1346 734-761-4700 800-521-0600 http://proquest.com/en-US/default.shtml Faucette, Raymond Frank, Jr. 1997. Evaluation of a Recirculating Aquaculture-Hydroponics System. PhD Dissertation, Oklahoma State University. UMI, Ann Harbor, MI. 69 p. Head, William. 1986. An Assessment of a Closed Greenhouse Aquaculture and Hydroponic System (Tilapia Diets). PhD. Dissertation, Oregon State University. UMI, Ann Harbor, MI. 127 p. Khan, Masud A. 1996. Utilization of Aquaculture Eﬄuent to Supplement Water and Nutrient Use of Turfgrasses and Native Plants (Ephedra viridis, Artemesia tridentata, Atriplex canescens, Ceratoides lanata, Chrysothamnus nauseosus, and Cercocarpus montanus). PhD Dissertation, New Mexico State University. UMI, Ann Harbor, MI. 218 p. King, Chad Eric. 2005. Integrated Agriculture and Aquaculture for Sustainable Food Production. PhD Dissertation, The University of Arizona. UMI, Ann Harbor, MI. 87 p. MacQuarrie, Carla Dawn. 2002. Computational Model of an Integrated Aquaculture- Hydroponic System. MS Thesis, Daltech-Dalhousie University. UMI, Ann Harbor, MI. 127 p. McMurtry, Mark Richard. 1992. Integrated AquacultureOlericulture System as Inﬂuenced by Component Ratio. PhD Dissertation, North Carolina State University. UMI, Ann Harbor, MI. 78 p. Rakocy, James Edward. 1980. Evaluation of a Closed Recirculating System for Tilapia Culture. PhD Dissertation, Auburn University. UMI, Ann Harbor, MI. 129 p. Seawright, Damon Eurgene. 1995. Integrated Aquaculture-Hydroponic Systems: Nutrient Dynamics and Designer Diet Development. PhD Dissertation, University of Mexico. UMI, Ann Harbor, MI. 274 p. Singh, Sahdev. 1996. A Computer Simulation Model for Wastewater Management in an Integrated (Fish Production-Hydroponics) System. PhD Dissertation, Virginia Polytechnic Institute and State University. UMI, Ann Harbor, MI. 150 p.

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Aquaponics—Integration of Hydroponics with Aquaculture By Steve Diver, NCAT Agriculture Specialist Published 2006 Updated by Lee Rinehart, NCAT Agriculture Specialist © 2010 NCAT Holly Michels, Editor Amy Smith, Production This publication is available on the Web at: www.attra.ncat.org/attra-pub/aquaponic.html or www.attra.ncat.org/attra-pub/PDF/aquaponic.pdf IP163 Slot 54 Version 033010

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